Publikationen

1. S. Fasoulas et al., “Motivation, structure and goals of the Collaborative Research Centre 1667: Advancing Technologies of very Low-Altitude Satellites—ATLAS,” CEAS Space Journal, May 2026, doi: 10.1007/s12567-025-00687-8.

2. T. Jestin et al., “Interstellar dust predictions for the Destiny+ mission,” Copernicus Meetings, 2026.

3. N. Khawaja et al., “Deciphering mixtures of complex organic compounds in cosmic dust particles using JAXA’s Destiny+ Dust Analyzer,” Copernicus Meetings, 2026.

4. F. Leese and C. Olthoff, “Combining Life Support Systems with Digital Twins: A New Potential?,” in The 15th EASN International Conference on “Innovation in Aviation & Space Towards Sustainability Today & Tomorrow”, S. Pantelakis, A. Strohmayer, and G. Alonso, Eds., MDPI Engineering Proceedings, 2026, pp. 2–7. [Online]. Available: https://www.mdpi.com/2673-4591/133/1

5. Y. Li et al., “Small Linear Accelerators for Charged Microparticles,” Copernicus Meetings, 2026.

6. R. Mikula et al., “Measuring the processing of organic and mineral cosmic dust grains with the Interstellar Dust Experiment (IDEX) instrument,” Copernicus Meetings, 2026.

7. K. Schindler, J. Wolf, and A. Krabbe, “The Astronomical Telescope of the University of Stuttgart (ATUS): Development, Optimization, and Lessons Learned,” Publications of the Astronomical Society of the Pacific, vol. 138, Art. no. 3, Mar. 2026, doi: 10.1088/1538-3873/ae477d.

8. M. Schütte, I. Hörner, S. Löhle, S. Fasoulas, and M. Pfeiffer, “Numerical Simulation of the Flow Field Around a Sounding Rocket for the PMWE Project,” in Rarefied Gas Dynamics, M. Grabe, G. Oblapenko, and M. Torrilhon, Eds., Springer Nature Switzerland, 2026, pp. 193–201.

9. R. Srama et al., “The Dust Analyser for DESTINY+: Development Status and Performance,” Copernicus Meetings, 2026.

10. D. Starzmann, T. Loeffler, K. Waizenegger, M. Lengowski, and S. Klinkner, “Using Commercial Off-the-Shelf Camera Systems for Remote Sensing and Public Engagement on the Small Satellite ROMEO,” Aerospace, vol. 13, Art. no. 5, Apr. 2026, doi: 10.3390/aerospace13050411.

11. F. Turco, C. Traub, M. Schütte, M. Pfeiffer, and S. Fasoulas, “Assessment of the practicality of optimal aerodynamic orbit control in VLEO,” Acta Astronautica, Aug. 2026, doi: 10.1016/j.actaastro.2026.02.039.

12. F. Turco, C. Traub, and S. Fasoulas, “Decay-optimal lift-based adjustments of the orbital plane in Very Low Earth Orbits,” Acta Astronautica, Sep. 2026, doi: 10.1016/j.actaastro.2026.04.025.

13. F. Tuttas and M. Pfeiffer, “Comparison of Stochastic BGK and FP Methods for the Simulation of Non-Equilibrium Multi-species Molecular Gas Flows,” in Rarefied Gas Dynamics, M. Grabe, G. Oblapenko, and M. Torrilhon, Eds., Cham: Springer Nature Switzerland, 2026, pp. 421–429. doi: 10.1007/978-3-032-00094-1_40.

14. D. Wanke et al., “Thruster and testing facility design developments of low power AF-MPD thrusters in SUPREME and BANTER,” in 35th International Symposium on Space Technology and Science (ISTS), University of Stuttgart, Mar. 2026. doi: 10.5281/ZENODO.19002724.

15. C. Althaus et al., “Lunar Levitation Dust Instrument for a Lander: Investigating Electrostatic Dust Transport on the Moon,” 2025.

16. N. Altobelli et al., “Exogenic dust inventory in the Saturn system: the Cassini Cosmic Dust Analyzer perspective,” Monthly Notices of the Royal Astronomical Society, vol. 539, Art. no. 4, 2025.

17. T. Arai et al., “Updated Status of DESTINY+ Asteroid Flyby Mission,” LPI Contributions, vol. 3090, p. 1875, 2025.

18. N. Barth et al., “Solar activity dependency of a specular intake for an ABEP system,” Journal of electric propulsion, vol. 4, p. 57, 2025, doi: 10.1007/s44205-025-00157-7.

19. M. Bauer et al., “A Small Linear Accelerator for Charged Microparticles,” Applied Sciences, vol. 15, Art. no. 21, 2025.

20. A. Behnke, G. Becatti, A. Sperber, D. Wanke, and G. H. Herdrich, “Current density and Lorentz force measurements in the downstream plume of the 100 kW AF-MPD thruster SX3,” Journal of applied physics, vol. 137, Art. no. 22, 2025, doi: 10.1063/5.0254076.

21. A. Behnke et al., “Recent Investigations of the Operational Behavior Accompanied by Life Time Assessments for the AF-MPD Thruster SX3,” 39th International Electric Propulsion Conference, Sep. 2025.

22. K.-S. Ellenberger, A. Schlitzer, M. Pfeiffer, and S. Fasoulas, “Numerical Study on the Setup of an Atomic Oxygen Ground Testing Facility,” in 3rd International Conference on Flight Vehicles, Aerothermodynamics and Re-entry (FAR), May 2025. [Online]. Available: https://www.researchgate.net/publication/393786584_NUMERICAL_STUDY_ON_THE_SETUP_OF_AN_ATOMIC_OXYGEN_GROUND_TESTING_FACILITY

23. S. Fasoulas et al., “Motivation, structure and goals of the Collaborative Research Centre 1667 : Advancing Technologies of very Low-Altitude Satellites-ATLAS,” CEAS space journal, 2025, doi: 10.1007/s12567-025-00687-8.

24. T. Friedrich, J. Grill, and G. Herdrich, “Analysis of the Electric Propulsion System for the Nuclear Space Tug in ESA’s RocketRoll Project,” 39th International Electric Propulsion Conference, 2025. [Online]. Available: https://www.researchgate.net/publication/395833587_Analysis_of_the_Electric_Propulsion_System_for_the_Nuclear_Space_Tug_in_ESA's_RocketRoll_Project

25. R. Fritzsche et al., “Thrust Measurement Setup for the Modular Pulsed Propulsion System,” in Proceedings of the 39th International Electric Propulsion Conference, 2025.

26. S. Förste, L. E. Yousfi, J.-S. Fischer, F. Turco, C. Traub, and S. Fasoulas, “A comprehensive assessment of rocket body related space debris and discussion of suitable means of risk reduction,” Acta Astronautica, May 2025, doi: 10.1016/j.actaastro.2025.01.068.

27. E. Gaglio, C. Traub, F. Turco, J. O. Murcia Piñeros, R. Bevilacqua, and S. Fasoulas, “Optimal drag-based collision avoidance: Balancing miss distance and orbital decay,” Acta Astronautica, vol. 228, pp. 295–305, Mar. 2025, doi: 10.1016/j.actaastro.2024.11.052.

28. E. Gaglio et al., “Quasi-Optimal Guidance and Control in Very Low Earth Orbit via Deep Learning for Drag-Based Collision Avoidance,” Acta astronautica, vol. 235, pp. 362–374, 2025, doi: 10.1016/j.actaastro.2025.05.029.

29. J. Grill, M. Ehresmann, and G. Herdrich, “Extending the Evolutionary System Design Converger (ESDC) for High-Power Electric Propulsion,” 39th International Electric Propulsion Conference, 2025. [Online]. Available: https://www.researchgate.net/publication/395831372_Extending_the_Evolutionary_System_Design_Converger_ESDC_for_High-Power_Electric_Propulsion

30. J. Grill, G. Herdrich, G. Becatti, E. Puccinelli, and A. Pasini, “Integrating Mission and System Analyses in the BANTER Project for Nuclear Bimodal Propulsion,” 2025. [Online]. Available: https://www.researchgate.net/publication/397096767_Integrating_Mission_and_System_Analyses_in_the_BANTER_Project_for_Nuclear_Bimodal_Propulsion

31. P. Haufe et al., “Minimum-Time Spacecraft Collision Avoidance Using Aerodynamic Lift and Drag Via Reachable Sets,” in 23rd IAA Symposium on Space Debris, Oct. 2025. doi: 10.52202/083079-0150.

32. G. Herdrich et al., “Advancements in the AF-MPD Development Within the EU Project SUPREME,” in 76th International Astronautical Congress (IAC 2025), International Astronautical Federation (IAF), 2025. doi: 10.52202/083090-0043.

33. M. Horányi et al., “Interstellar Dust Experiment (IDEX) onboard NASA’s Interstellar Mapping and Acceleration Probe (IMAP),” Space Science Reviews, vol. 221, Art. no. 8, 2025.

34. L. Ingrillini et al., “Operationalizing differential drag control : a planning routine for the S-NET satellite formation,” CEAS space journal, 2025, doi: 10.1007/s12567-025-00630-x.

35. S. Kempf et al., “SUDA: A SUrface Dust Analyser for compositional mapping of the Galilean moon Europa,” Space Science Reviews, vol. 221, Art. no. 1, 2025.

36. N. Khawaja et al., “A New Look at Enceladus’s Organic Inventory,” in EPSC-DPS Joint Meeting 2025 (EPSC-DPS2025, 2025, pp. EPSC––DPS2025.

37. N. Khawaja et al., “Detection of organic compounds in freshly ejected ice grains from Enceladus’s ocean,” Nature Astronomy, vol. 9, Art. no. 11, 2025.

38. S. Lauterbach, S. Fasoulas, and M. Pfeiffer, “Modeling of heterogeneous catalytic reactions with the simulation tool PICLas,” Computer Physics Communications, vol. 311, p. 109560, Jun. 2025, doi: 10.1016/j.cpc.2025.109560.

39. F. Leese and C. Olthoff, “Analysis of Historical Life Support Systems to Define a Design Envelope for Future Missions,” in 54th International Conference On Environmental Systems, in International Conference on Environmental Systems. International Conference on Environmental Systems, 2025. [Online]. Available: https://hdl.handle.net/2346/102663

40. F. Leese, E. Kamps, V. Stratmann, and C. Olthoff, “Outlook on Research on Life Support Systems together with Digital Twin modeling,” in 76th International Astronautical Congress (IAC), 2025, pp. 1–8. [Online]. Available: https://www.researchgate.net/publication/396229498_Outlook_on_research_on_Life_Support_Systems_together_with_Digital_Twin_modeling

41. S. Linti et al., “A Dust Halo from Saturn’s Main Rings Extending Several Saturnian Radii above the Ring Plane,” The Planetary Science Journal, vol. 6, Art. no. 11, 2025.

42. N. Maraqten, O. Nimer, J. Grill, M. Ehresmann, G. Herdrich, and U. Soergel, “Dimensionality Reduction and Machine Learning for Generative Surrogate Modeling of ABEP Intake DSMC Simulations,” 39th International Electric Propulsion Conference, 2025. [Online]. Available: https://www.researchgate.net/publication/395835470_Dimensionality_Reduction_and_Machine_Learning_for_Generative_Surrogate_Modeling_of_ABEP_Intake_DSMC_Simulations

43. N. Maraqten, O. Nimer, J. Grill, M. Ehresmann, G. Herdrich, and U. Soergel, “PINN–PONN: A Novel Physics-Informed Deep Learning Method for Plasma Flow Reconstruction,” 39th International Electric Propulsion Conference, 2025. [Online]. Available: https://www.researchgate.net/publication/395835483_PINN-PONN_A_Novel_Physics-Informed_Deep_Learning_Method_for_Plasma_Flow_Reconstruction

44. C. Mayer, C. Olthoff, and J. Holl, Enhancing Spaceflight Autonomy with Machine Learning: Fault Detection in Life Support Systems. 2025. [Online]. Available: https://iafastro.directory/iac/paper/id/94538/summary/

45. C. Mayer and C. Olthoff, “Life support systems: A comparative study of machine learning applications, challenges, and future developments in space exploration,” in 54th International Conference on Environmental Systems, International Conference on Environmental Systems, Jul. 2025. doi: 10.32865/2346/102642.

46. K. Papavramidis, C. Vogt, E. Gutierrez Rojas, J. Skalden, J. Grill, and G. H. Herdrich, “Design, development and simulation activities of an RF helicon-based plasma thruster for VLEO satellites,” Journal of electric propulsion, vol. 4, Art. no. 1, 2025, doi: 10.1007/s44205-025-00161-x.

47. A. Pasini et al., “Bimodal Ammonia Nuclear Thermal and Electric Rocket (BANTER): Project Overview,” 76th International Astronautical Congress, 2025. doi: 10.52202/083090-0080.

48. F. Postberg et al., “Salt diversity observed in Enceladus’ ice grains suggest a complex plume formation process from the subsurface ocean,” in EPSC-DPS Joint Meeting 2025 (EPSC-DPS2025, 2025, pp. EPSC––DPS2025.

49. E. Puccinelli, V. Giusti, J. Grill, G. Becatti, G. Herdrich, and A. Pasini, “Definition of Requirements and System Engineering of the Innovative Bimodal Ammonia Nuclear Thermal and Electric Rocket (BANTER),” 76th International Astronautical Congress, 2025. doi: 10.52202/083090-0089.

50. D. Rossa et al., “Investigating Electrodynamic Tethers for Sustainable Space Debris Mitigation,” 76th International Astronautical Congress, 2025. doi: 10.52202/083079-0180.

51. M. Rothmeier et al., “Doomed Worlds. II. Reassessing Suggestions of Orbital Decay for TrES-5 b,” The Planetary Science Journal, Dec. 2025, doi: 10.3847/PSJ/ae1b9c.

52. B. Schulz et al., “Helping Bridge the FIR-Data-Drought with the SOFIA Data Center (SDC),” American Astronomical Society Meeting Abstracts. Jan. 2025.

53. M. Schütte, S. Hocker, H. Lipp, J. Roth, S. Fasoulas, and M. Pfeiffer, “A machine learning framework for scattering kernel derivation using molecular dynamics data in very low Earth orbit,” Physics of Fluids, Sep. 2025, doi: 10.1063/5.0287359.

54. M. Schütte, S. Fasoulas, and M. Pfeiffer, “Enhanced gas-surface scattering modeling for VLEO satellites in DSMC simulations,” CEAS Space Journal, Jun. 2025, doi: 10.1007/s12567-025-00629-4.

55. A. Sperber, A. Behnke, D. Wanke, and G. Herdrich, “Performance Characterization and Laboratory Model Development of AF-MPD Thrusters at IRS,” in 11th European Conference for Aeronautics and Aerospace Sciences, 2025.

56. A. Sperber et al., “Thermal Design of the 5 kW AF-MPD Thruster SUPREME and its Testing Environment,” 39th International Electric Propulsion Conference, Sep. 2025.

57. R. Srama et al., “The DESTINY+ Dust Analyser (DDA) for in-situ Cosmic Dust Measurements,” in EGU General Assembly Conference Abstracts, 2025, pp. EGU25––19660.

58. R. Tietz, R. Stierle, K. S. Ellenberger, S. Fasoulas, and M. Pfeiffer, “A Multi-Species Enskog-Vlasov Solver to Determine Evaporation Coefficients of Fluids in High Pressure Environments.” arXiv, 2025. doi: 10.48550/ARXIV.2506.22162.

59. C. Traub et al., “Revealing the impact of operational constraints on aerodynamic collision avoidance maneuvers : In-flight results from the BEESAT-4 CubeSat,” Acta astronautica, vol. 234, Art. no. September, 2025, doi: 10.1016/j.actaastro.2025.04.038.

60. F. Turco, C. Traub, M. Schütte, M. Pfeiffer, and S. Fasoulas, “Assessment of the Practicality of Optimal Aerodynamic Orbit Control in VLEO,” in IAF Astrodynamics Symposium, Sep. 2025. doi: 10.52202/083087-0029.

61. F. E. G. Turco, C. Traub, and S. Fasoulas, “Optimal Satellite Orbit Control via Aerodynamic Forces in Very Low Earth Orbits,” in AAS/AIAA Astrodynamics Specialist Conference, Aug. 2025. [Online]. Available: https://www.researchgate.net/publication/394530650_Optimal_Satellite_Orbit_Control_via_Aerodynamic_Forces_in_Very_Low_Earth_Orbits

62. F. Tuttas and M. Pfeiffer, “Modeling of Particle-Based BGK Methods for the Simulation of Chemically Reactive Gas Mixtures in Multi-Scale Flows,” in 3rd International Conference on Flight Vehicles, Aerothermodynamics and Re-entry (FAR), Arcachon, France, May 2025. [Online]. Available: https://www.researchgate.net/publication/391316219_Modeling_of_Particle-Based_BGK_Methods_for_the_Simulation_of_Chemically_Reactive_Gas_Mixtures_in_Multi-Scale_Flows

63. F. Tuttas and M. Pfeiffer, “Multi-Scale Gas Kinetic Simulations for Chemically Reactive Flows,” 22nd International Planetary Probe Workshop, 2025. doi: 10.13140/RG.2.2.16441.28000.

64. A. Vorburger et al., “Pallas Interstellar: A Dual-Purpose Mission to a Primordial Asteroid and the Local Interstellar Medium,” Copernicus Meetings, 2025.

65. M. Winter et al., “Downscaling the 100 kW SX-3 AF-MPD to the 5 kW SUPREME thruster,” Journal of electric propulsion, vol. 4, p. 28, 2025, doi: 10.1007/s44205-025-00128-y.

66. T. Arai et al., “Flyby of asteroid Phaethon: the Sun’s son and cosmic dust’s mother!(1)--Overview and science of DESTINY+,” YU, SEI, JIN, vol. 33, pp. 34–50, 2024.

67. A. Behnke, G. Becatti, A. Sperber, D. Wanke, and G. Herdrich, “Investigation of the current densities and the acceleration mechanisms in the plume of the AF-MPD thruster SX3,” in 38th International Electric Propulsion Conference, Toulouse, France: Electric Rocket Propulsion Society, 2024.

68. A. Behnke et al., “Reference Missions, Mission Level Needs and Evaluation of Candidate Technologiesfor High Power Electric Propulsion,” 9th Space Propulsion Conference, 2024. [Online]. Available: https://www.researchgate.net/publication/381229294_Reference_Missions_Mission_Level_Needs_and_Evaluation_of_Candidate_Technologiesfor_High_Power_Electric_Propulsion

69. A. Bryant, A. Krabbe, B. Schulz, P. Maier, and H. Zinnecker, “The legacy of SOFIA and perspectives on the far-infrared,” in Space Telescopes and Instrumentation 2024: Optical, Infrared, and Millimeter Wave, L. E. Coyle, M. D. Perrin, and S. Matsuura, Eds., SPIE, Aug. 2024, p. 12. doi: 10.1117/12.3019708.

70. P. Dewey, J. K. Hillier, F. Postberg, L. M. Eckart, R. Srama, and M. Trieloff, “Synthesis and Characterisation of Cosmic Dust Analogue Ensembles from Meteorite Samples,” in European Planetary Science Congress, 2024, pp. EPSC2024––1056.

71. A. Ershova et al., “Modeling the Enceladus dust plume based on in situ measurements performed with the Cassini Cosmic Dust Analyzer,” Astronomy & Astrophysics, vol. 689, p. A114, 2024.

72. R. Fritzsche, C. F. Kaiser, and G. Herdrich, “Design approach for an advanced multi-channel pyrometer for bulk oven processes,” Journal of the European Optical Society-Rapid Publications, 2024, doi: 10.1051/jeos/2024035.

73. E. Gaglio, C. Traub, F. E. G. Turco, J. O. Murcia-Piñeros, R. Bevilacqua, and S. Fasoulas, “Optimal spacecraft collision avoidance using aerodynamic drag,” in 4th IAA Conference on Space Situational Awareness (ICSSA), May 2024.

74. J. Grill et al., “Analysis and Benchmarking of Suitable High-Power Electric Thrusters for RocketRoll’s Nuclear Electric Propulsion Project,” 38th International Electric Propulsion Conference, 2024. [Online]. Available: https://www.researchgate.net/publication/382117250_Analysis_and_Benchmarking_of_Suitable_High-Power_Electric_Thrusters_for_RocketRoll's_Nuclear_Electric_Propulsion_Project

75. J. Grill et al., “Enabling High-Power Propulsion Systems for Large Scale Transportation, from Earth Orbits and the Cis-Lunar Region to Mars and Beyond,” 9th Space Propulsion Conference, 2024. [Online]. Available: https://www.researchgate.net/publication/381198883_ENABLING_HIGH-POWER_PROPULSION_SYSTEMS_FOR_LARGE_SCALE_TRANSPORTATION_FROM_EARTH_ORBITS_AND_THE_CIS-LUNAR_REGION_TO_MARS_AND_BEYOND

76. G. Herdrich et al., “System design study of a VLEO satellite platform using the IRS RF helicon-based plasma thruster,” Acta Astronautica, Feb. 2024, doi: 10.1016/j.actaastro.2023.11.009.

77. F. Hild and M. Pfeiffer, “Multi-species modeling in the particle-based ellipsoidal statistical Bhatnagar-Gross-Krook method including internal degrees of freedom,” Journal of Computational Physics, vol. 514, p. 113226, 2024, doi: 10.1016/j.jcp.2024.113226.

78. F. Hild and M. Pfeiffer, “Simulation of Multi-species Non-equilibrium Gas Flows with the Particle-based Ellipsoidal Statistical Bhatnagar-Gross-Krook Method,” in 32nd International Symposium on Rarefied Gas Dynamics, R. S. Myong, K. Xu, and J.-S. Wu, Eds., in AIP Conference Proceedings, vol. 2996. American Institute of Physics, 2024, p. 60001. doi: 10.1063/5.0187423.

79. B. Karahan et al., “In-orbit validation of a ferrofluidic Thermal Switch in ISS microgravity,” CEAS space journal, 2024, doi: 10.1007/s12567-024-00579-3.

80. B. Karahan et al., “Recent results of Ferrofluid ISS Experiments to enable Sustainable Space Activities,” Journal of evolving space activities, vol. 2, p. 157, 2024, doi: 10.57350/jesa.157.

81. S. Kempf, N. Altobelli, J. Schmidt, J. Cuzzi, P. Estrada, and R. Srama, “How old are Saturn’s rings?,” in 55th Lunar and Planetary Science Conference, 2024, p. 2196.

82. N. Khawaja et al., “Calibration of Destiny Dust Analyzer (DDA) with Polypyrrole Coated Perylene Microparticles,” in European Planetary Science Congress, 2024, pp. EPSC2024––1119.

83. N. Khawaja et al., “Cassini’s new look at organic material in Enceladus’ plume ice grains with CDA: implication for the habitability of Ocean Worlds,” Copernicus Meetings, 2024.

84. N. Khawaja et al., “Mass Spectral Properties of Hydrothermally Processed Triglycine (GGG) in Ice Grains Emitted by Enceladus and Europa,” Copernicus Meetings, 2024.

85. B. Knieling, K. Schindler, A. A. Sickafoose, M. J. Person, S. E. Levine, and A. Krabbe, “Stellar Occultations in the Era of Data Mining and Modern Regression Models: Using Gaussian Processes to Analyze Light Curves and Improve Predictions,” The Planetary Science Journal, Apr. 2024, doi: 10.3847/PSJ/ad3819.

86. M. Kobayashi, O. Okudaira, T. Hirai, S. Sasaki, H. Krueger, and R. Srama, “Advancements in in-situ dust observation: design and capabilities of the Circum-Martian Dust Monitor (CMDM) for JAXA’s Martian Moons eXploration (MMX).,” 45th COSPAR Scientific Assembly. Held 13-21 July, vol. 45, p. 824, 2024.

87. H. Krüger et al., “Modeling the interstellar dust detections by DESTINY+ I: Instrumental constraints and detectability of organic compounds,” Planetary and Space Science, vol. 254, p. 106010, 2024.

88. H. Krüger et al., “The interstellar dust detection conditions with the DESTINY+ Dust Analyzer,” in European Planetary Science Congress, 2024, pp. EPSC2024––897.

89. S. Linti et al., “Cassini’s CDA observes a variety of dust populations just outside Saturn’s main rings,” Monthly Notices of the Royal Astronomical Society, vol. 529, Art. no. 4, 2024.

90. S. Linti et al., “Iron depletion in mineral dust grains from Saturn’s main rings,” Monthly Notices of the Royal Astronomical Society, vol. 529, Art. no. 2, 2024.

91. R. Mikula et al., “Analyzing impact ionization mass spectra of polycyclic aromatic dust particles-preparation for the in-situ collection of organic interplanetary dust particles,” in AGU Fall Meeting Abstracts, 2024, pp. P13A––3051.

92. R. Mikula et al., “Impact ionization mass spectra of polypyrrole-coated anthracene microparticles: a useful mimic for cosmic polycyclic aromatic hydrocarbon dust,” ACS Earth and Space Chemistry, vol. 8, Art. no. 3, 2024.

93. L. Nölle et al., “Radial compositional profile of Saturn’s E ring indicates substantial space weathering effects,” Monthly Notices of the Royal Astronomical Society, vol. 527, Art. no. 3, 2024.

94. J. Owald, A. Pagan, A. Behnke, and G. H. Herdrich, “Investigation of Re-Entry Break-Up Radiation Markers with a Splitter Probe,” Journal of evolving space activities, vol. 2, p. 130, 2024, doi: 10.57350/jesa.130.

95. S. I. Schlachter et al., “Design, fabrication and test of high temperature superconducting magnet for heat flux and radio blackout mitigation experiments in plasma wind tunnels,” in Advances in Cryogenic Engineering - Materials : Proceedings of the International Cryogenic Materials Conference (ICMC) 2023 09/07/2023 - 13/07/2023 Honolulu, United States of America, in IOP Conference Series. Materials Science and Engineering. Institute of Physics, 2024, p. 12021. doi: 10.1088/1757-899x/1302/1/012021.

96. J. Schmidt et al., “The Enceladus dust plume from the Cassini cosmic dust analyzer,” in European Planetary Science Congress, 2024, pp. EPSC2024––510.

97. J. Sevecek et al., “Preliminary European Reckon on Nuclear Electric Propulsion for Space Applications (RocketRoll),” 9th Space Propulsion Conference, 2024. [Online]. Available: https://www.researchgate.net/publication/392727549_Preliminary_European_Reckon_on_Nuclear_Electric_Propulsion_for_Space_Applications_RocketRoll

98. J. Simolka et al., “The DESTINY+ Dust Analyser (DDA)-characterising the dust environment from Earth to (3200) Phaethon,” 45th COSPAR Scientific Assembly. Held 13-21 July, vol. 45, p. 174, 2024.

99. J. Simolka et al., “The DESTINY+ Dust Analyser—a dust telescope for analysing cosmic dust dynamics and composition,” Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, vol. 382, Art. no. 2273, 2024.

100. A. Sperber et al., “Thrust Balance Design for the Advanced 5 kW AF-MPD Thruster SUPREME,” in 38th International Electric Propulsion Conference, Toulouse, France: Electric Rocket Propulsion Society, 2024.

101. Z. Sternovsky et al., “Detecting Organics with Dust Impact Analyzer Instruments,” European Geosciences Union General Assembly 2024 (EGU24), p. 12633, 2024.

102. S. Sütterlin et al., “Fargo : validation of space-relevant ferrofluid applications on the ISS,” CEAS space journal, vol. 16, Art. no. 6, 2024, doi: 10.1007/s12567-024-00539-x.

103. F. Turco, C. Traub, S. Gaißer, J. C. Burgdorf, S. Klinkner, and S. Fasoulas, “Analysis of Collision Avoidance Manoeuvres Using Aerodynamic Drag for the Flying Laptop Satellite,” Aerotecnica missili & spazio, vol. 103, pp. 61–71, 2024, doi: 10.1007/s42496-023-00183-4.

104. C. Vogt, J. Grill, K. Papavramidis, J. Skalden, and G. Herdrich, “Investigation on Thermal Behaviour of a RF Helicon Plasma Thruster with Coupled Electromagnetic and Thermal Models,” 75th International Astronautical Congress, 2024. doi: 10.52202/078379-0059.

105. D. Wanke et al., “Facility Advancement and Mapping for the Advanced 5 kW AF-MPD Thruster SUPREME,” in 38th International Electric Propulsion Conference, Electric Rocket Propulsion Society, 2024. [Online]. Available: https://www.researchgate.net/publication/381861126_Facility_Advancement_and_Mapping_for_the_Advanced_5_kW_AF-MPD_Thruster_SUPREME

106. S. Zajonz et al., “Development of a Ferrofluid-Based Attitude Control Actuator for Verification on the ISS,” Aerotecnica Missili & Spazio, vol. 103, Art. no. 3, Sep. 2024, doi: 10.1007/s42496-024-00208-6.

107. T. Arai et al., “DESTINY+ and Ground-Based Observations of Its Target Asteroid (3200) Phaethon,” in Asteroids, Comets, Meteors Conference, 2023, p. 2578.

108. A. Behnke and G. Herdrich, “Current Balance and Current Densities in the Plume of the AF-MPD thruster SX3,” in 34th ISTS, 2023.

109. A. Bryant, “Far-Infrared Imaging Spectroscopy of the Galactic Centre’s Circumnuclear Disk,” in Physics and Chemistry of Star Formation: The Dynamical ISM Across Time and Spatial Scales, 2023.

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240. H. Krüger et al., “Dust simulations for the Destiny+ mission to (3200) Phaethon,” in European Planetary Science Congress 2018, 2018.

241. H. Krüger et al., “Interstellar and Interplanetary Dust Modelling for Destiny+,” in Dusty Visions Workshop, 2018.

242. Y. Li et al., “Determination of impact position on an impact ionization detector by electrostatic induction,” Advances in Space Research, vol. 62, Art. no. 4, 2018.

243. Y. Li, A. Mocker, and R. Srama, “The measurement of micron sized impact fragment using delay line detector,” in European Planetary Science Congress, 2018, pp. EPSC2018––1187.

244. M. Masanori, R. Srama, H. Krüger, T. Arai, and H. Kimura, “DESTINY+ Dust Analyzer,” in 49th Annual Lunar and Planetary Science Conference, 2018, p. 2050.

245. G. Mitri et al., “Explorer of Enceladus and Titan (E2T): Investigating ocean worlds’ evolution and habitability in the solar system,” Planetary and space science, vol. 155, pp. 73–90, 2018.

246. E. Pfüller, J. Wolf, K. Schindler, and M. J. Person, “Adding a second spectral channel to the SOFIA FPI+ science instrument,” Proc. SPIE, vol. 10702, p. 107022V, 2018, doi: 10.1117/12.2313663.

247. F. Postberg et al., “Enceladus’ complex organics, Saturn’s main ring composition and Oort Cloud dust: the latest and best from Cassini’s CDA,” in AGU Fall Meeting Abstracts, 2018, pp. U21A––06.

248. F. Postberg et al., “Macromolecular organic compounds from Enceladus,” 42nd COSPAR Scientific Assembly, vol. 42, pp. B5––3, 2018.

249. F. Postberg et al., “Macromolecular organic compounds from the depths of Enceladus,” Nature, vol. 558, Art. no. 7711, 2018.

250. W. Reschke and S. Fasoulas, “Gas-Kinetic Simulation of Microdroplet-Gas Interaction,” in DIPSI Workshop 2018-Droplet Impact Phenomena & Spray Investigations, Università degli studi di Bergamo, 2018, pp. 48–51.

251. R. Srama, M. Kobayashi, and H. Krüger, “Dust astronomy with the DESTINY+ dust analyser,” in European Planetary Science Congress, 2018, pp. EPSC2018––1223.

252. R. Srama, H. Krueger, M. Kobayashi, T. Arai, and H. Kimura, “Dust Astronomy with the mission Destiny+,” 42nd COSPAR Scientific Assembly, vol. 42, pp. C5––2, 2018.

253. R. Srama et al., “The dust environment of Saturn within Saturn’s D ring: CDA results of the Grand Finale of Cassini,” 42nd COSPAR Scientific Assembly, vol. 42, pp. B5––2, 2018.

254. F. Tuttas, “Auslegung des Lageregelungssystems für den Nanosatelliten Student-Operated University Research Cubesat for Education (SOURCE),” Bachelor’s Thesis, Stuttgart, 2018. doi: 10.13140/RG.2.2.24504.01280.

255. S.-Y. Ye et al., “Cassini RPWS dust observation near the Janus/Epimetheus orbit,” Journal of Geophysical Research: Space Physics, vol. 123, Art. no. 6, 2018.

256. S.-Y. Ye et al., “Dust observations by the radio and plasma wave science instrument during Cassini’s grand finale,” Geophysical Research Letters, vol. 45, Art. no. 19, 2018.

257. S. Ye et al., “Dust Detection in Space by Wave Instruments,” in AGU Fall Meeting Abstracts, 2018, pp. P43B––08.

258. T. Albin, D. Koschny, S. Molau, R. Srama, and B. Poppe, “Analysis of the technical biases of meteor video cameras used in the CILBO system,” Geoscientific Instrumentation, Methods and Data Systems, vol. 6, Art. no. 1, 2017.

259. N. Altobelli, S. Kempf, and R. Srama, “Dust in the Outer Solar System as measured by Cassini-CDA: KBOs, Centaurs and TNOs as parent bodies?,” in European Planetary Science Congress, 2017, pp. EPSC2017––794.

260. M. Bhatt et al., “Composition of Jupiter irregular satellites sheds light on their origin,” Astronomy and Astrophysics, Dec. 2017, doi: 10.1051/0004-6361/201630361.

261. S. Hsu et al., “A dusty road connecting Saturn and its rings-preliminary results from Cassini Cosmic Dust Analyser during the Grand Finale Mission,” in AGU Fall Meeting Abstracts, 2017, pp. U22A––04.

262. S. Kempf, B. Southworth, J. Schmidt, F. Postberg, and R. Srama, “Resolving the Mass Production and Surface Structure of the Enceladus Dust Plume,” in European Planetary Science Congress, 2017, pp. EPSC2017––818.

263. S. Kempf, N. Altobelli, R. Srama, J. N. Cuzzi, and P. R. Estrada, “The age of Saturn’s rings constrained by the meteoroid flux into the system,” in AGU Fall Meeting Abstracts, 2017, pp. P34A––05.

264. H. Krüger et al., “Dust analysis on board the Destiny+ mission to 3200 Phaethon,” in European Planetary Science Congress, 2017, pp. EPSC2017––204.

265. Y. Li, S. Kempf, J. Simolka, H. Strack, E. Grün, and R. Srama, “Instrument concept of a single channel dust trajectory detector,” Advances in Space Research, vol. 59, Art. no. 6, 2017.

266. G. Mitri, “Explorer of Enceladus and Titan (E2T): Investigating Ocean Worlds’ Evolution and Habitability in the Saturn System,” in EGU General Assembly Conference Abstracts, 2017, p. 13527.

267. L. Nölle, F. Postberg, N. Khawaja, T. Albin, and R. Srama, “Compositional 3-D mapping of icy dust grains in the E-ring,” in European Planetary Science Congress, 2017, pp. EPSC2017––1009.

268. P. Ortwein et al., “Piclas: A Highly Flexible Particle Code for the Simulation of Reactive Plasma Flows,” in 2017 IEEE International Conference on Plasma Science (ICOPS), May 2017, p. 1. doi: 10.1109/PLASMA.2017.8496309.

269. F. Postberg et al., “Complex organic macromolecular compounds in ice grains from Enceladus,” in 48th Annual Lunar and Planetary Science Conference, 2017, p. 1401.

270. F. Postberg, N. Khawaja, R. Reviol, L. Nölle, F. Klenner, and R. Srama, “Organic compounds from Enceladus in E ring ice grains,” in EGU General Assembly Conference Abstracts, 2017, p. 13686.

271. K. Schindler et al., “Results from a triple chord stellar occultation and far-infrared photometry of the trans-Neptunian object (229762) 2007 UK126,” A&A, vol. 600, p. A12, 2017, doi: 10.1051/0004-6361/201628620.

272. M. Seiss, R. Srama, H. Hoffmann, F. Spahn, and others, “The dust distribution between F and G ring,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 49, 2017, pp. 104–5.

273. B. Southworth, S. Kempf, J. Spitale, R. Srama, J. Schmidt, and F. Postberg, “Resolving the Mass Production and Surface Structure of the Enceladus Dust Plume,” in 48th Annual Lunar and Planetary Science Conference, 2017, p. 2904.

274. R. Srama, “In-situ dust measurements during Cassini’s F-ring and proximal orbits,” in European Planetary Science Congress, 2017, pp. EPSC2017––810.

275. R. Srama et al., “CDA in-situ measurements during Cassini’s F-ring plane crossings in 2017,” in EGU General Assembly Conference Abstracts, 2017, p. 9882.

276. R. Srama, Y.-W. Li, and A. Mocker, “Das Staubinstrument LDEX auf LADEE: Experimentelle Studien und Simulationen: Abschlussbericht: 01.01. 2013-31.12. 2015.” Universität Stuttgart, Institut für Raumfahrtsysteme, 2017.

277. J. Weppler et al., “Überflieger - A student competition for iss experiments,” in Proceedings of the International Astronautical Congress, IAC, 2017, pp. 11157–11168.

278. S. Ye et al., “Dust Observation by the Radio and Plasma Wave Instrument During Cassini’s Grand Finale,” in AGU Fall Meeting Abstracts, 2017, pp. P23B––2725.

279. T. Albin, D. Koschny, R. Soja, R. Srama, and B. Poppe, “A Monte-Carlo based extension of the Meteor Orbit and Trajectory Software (MOTS) for computations of orbital elements,” in International Meteor Conference Egmond, the Netherlands, 2-5 June 2016, 2016, p. 20.

280. N. Altobelli et al., “Flux and composition of interstellar dust at Saturn from Cassini’s Cosmic Dust Analyzer,” Science, vol. 352, Art. no. 6283, 2016.

281. E. Grün et al., “The 2016 Feb 19 outburst of comet 67P/CG: an ESA Rosetta multi-instrument study,” Monthly Notices of the Royal Astronomical Society, vol. 462, Art. no. Suppl\_1, 2016.

282. J. Hillier et al., “Cosmic Dust Analogues for Hypervelocity Impact Research: Expanding the Library,” in 47th Annual Lunar and Planetary Science Conference, 2016, p. 2243.

283. H.-W. Hsu, S. Kempf, S. Badman, W. Kurth, F. Postberg, and R. Srama, “Interplanetary magnetic field structure at Saturn inferred from nanodust measurements during the 2013 aurora campaign,” Icarus, vol. 263, pp. 10–16, 2016.

284. V. Jasmin Sterken et al., “Calibration of impact ionization cosmic dust detectors: first tests to investigate how the dust density influences the signal,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 48, 2016, pp. 521–4.

285. J. Lunine et al., “Looking for life in the plumes of ocean worlds,” 41st COSPAR Scientific Assembly, vol. 41, pp. B0––6, 2016.

286. G. Mitri et al., “Explorer of Enceladus and Titan (E 2 T): Investigating the habitability and evolution of ocean worlds in the Saturn system,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 48, 2016, pp. 225–1.

287. G. Mitri et al., “Poster 14: Explorer of Enceladus and Titan (E2T),” Titan Aeronomy and Climate, p. 26, 2016.

288. W. Reschke et al., “Recent developments of DSMC within the reactive plasma flow solver PICLas,” in AIP Conference Proceedings, American Institute of Physics, Nov. 2016, p. 130003––. doi: 10.1063/1.4967629.

289. K. Schindler, D. Lang, L. Moore, M. Hümmer, J. Wolf, and A. Krabbe, “Computer-aided star pattern recognition with astrometry.net: in-flight support of telescope operations on SOFIA,” Proc. SPIE, vol. 9913, p. 991307, 2016, doi: 10.1117/12.2231531.

290. R. Soja et al., “Collisional lifetimes of meteoroids,” in International Meteor Conference Egmond, the Netherlands, 2-5 June 2016, 2016, p. 284.

291. B. Southworth, S. Kempf, and J. Schmidt, “On Numerically Reproducing the Enceladus Plume,” in AGU Fall Meeting Abstracts, 2016, pp. P33A––2120.

292. R. Srama, C. science Team, and others, “Dust occultation at Titan measured by CDA onboard Cassini,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 48, 2016, pp. 521–6.

293. V. Sterken et al., “Impact ionization experiments with porous cosmic dust particle analogs,” in EGU General Assembly Conference Abstracts, EGU General Assembly Conference Abstracts, 2016, pp. EPSC2016––16018.

294. M. Trieloff, N. Altobelli, F. Postberg, K. Fiege, and R. Srama, “Contemporary Interstellar Dust Measured by Cassini: A Chemically Homogenised Population, not Circumstellar Dust,” in 79th Annual Meeting of the Meteoritical Society, 2016, p. 6310.

295. M. Trieloff and R. Srama, “Kosmischer Staubsammler-Weltraumsonde Cassini meldet Erfolge nach Heidelberg,” 2016.

296. T. Albin, D. Koschny, G. Drolshagen, R. Soja, B. Poppe, and R. Srama, “De-biasing of the velocity determination for double station meteor observations from CILBO,” in International Meteor Conference Mistelbach, Austria, 2015, p. 214.

297. T. Albin, D. Koschny, G. Drolshagen, R. Soja, R. Srama, and B. Poppe, “Influence of the pointing direction and detector sensitivity variations on the detection rate of a double station meteor camera,” in International Meteor Conference Mistelbach, Austria, 2015, p. 226.

298. N. Altobelli, S. Kempf, F. Postberg, M. Horanyi, and R. Srama, “Dust populations in the outer Solar System: 10 years of monitoring by Cassini-CDA,” in European Planetary Science Congress, 2015, pp. EPSC2015––577.

299. K. Fiege, C. Bennett, M. Guglielmino, T. M. Orlando, M. Trieloff, and R. Srama, “Space Weathering of airless bodies in the Solar System-Combining hypervelocity dust impacts with energetic irradiation experiments,” in AGU Fall Meeting Abstracts, 2015, pp. P53C––2139.

300. M. Horanyi et al., “LDEX Observation of the Dust Environment of the Moon,” in 46th Annual Lunar and Planetary Science Conference, 2015, p. 1684.

301. M. Horanyi et al., “The dust environment of the Moon as seen by the Lunar Dust Environment Eplorer (LDEX),” in EGU General Assembly Conference Abstracts, 2015, p. 4296.

302. M. Horányi et al., “A permanent, asymmetric dust cloud around the Moon,” Nature, vol. 522, Art. no. 7556, 2015.

303. H.-W. Hsu et al., “Ongoing hydrothermal activities within Enceladus,” Nature, vol. 519, Art. no. 7542, 2015.

304. S. Kempf, M. Horanyi, R. Srama, and N. Altobelli, “Exogenous dust delivery into the Saturnian system and the age of Saturn’s rings,” in European Planetary Science Congress Abstracts, 2015, p. 411.

305. S. Kempf et al., “Compositional Mapping of Europa’s Surface with SUDA,” in AGU Fall Meeting Abstracts, 2015, pp. P13E––07.

306. S. Kempf, M. Horanyi, J. Schmidt, and B. Southworth, “How much dust does Enceladus eject?,” in EGU General Assembly Conference Abstracts, 2015, p. 10528.

307. E. Khalisi, R. Srama, and E. Grün, “Counter data of the Cosmic Dust Analyzer aboard the Cassini spacecraft and possible “dust clouds” at Saturn,” Advances in Space Research, vol. 55, Art. no. 1, 2015.

308. N. Khawaja, F. Postberg, R. Reviol, F. Klenner, L. Nölle, and R. Srama, “Organic compounds from Enceladus’ sub-surface ocean as seen by CDA,” in European Planetary Science Congress, 2015, p. 652.

309. N. Khawaja, F. Postberg, R. Reviol, and R. Srama, “Characterization of signatures from organic compounds in CDA mass spectra of ice particles in Saturn’s E-ring,” in EGU General Assembly Conference Abstracts, 2015, p. 12799.

310. N. Khawaja, F. Postberg, R. Srama, G. Moragas-Klostermeyer, and S. Kempf, “Compositional mapping of Saturn’s E-ring during Cassini’s flyby of Rhea,” in EGU General Assembly Conference Abstracts, 2015, p. 13523.

311. N. Khawaja, F. Postberg, R. Reviol, L. Nölle, F. Klenner, and R. Srama, “Identification of organics in ice grains from Enceladus,” in AGU Fall Meeting Abstracts, 2015, pp. P13A––2117.

312. Y. Li, H. Strack, S. Bugiel, Y. Wu, and R. Srama, “Instrument study of the Lunar Dust eXplorer (LDX) for a lunar lander mission II: Laboratory model calibration,” Advances in Space Research, vol. 56, Art. no. 8, 2015.

313. Y. Li, R. Srama, Y. Wu, and E. Grün, “Modeling the detection of impact ejecta on the lunar surface,” Planetary and Space Science, vol. 119, pp. 185–193, 2015.

314. Y. Li, S. Bugiel, B. Hofmann, M. Horanyi, Z. Sternovsky, and R. Srama, “Dust accelerator tests of the LDEX laboratory model,” in European Planetary Science Congress, 2015, pp. EPSC2015––277.

315. Y. Li, R. Srama, and S. Bugiel, “Dust Trajectory Detector Using Single Grid Electrodes Plane,” in 46th Annual Lunar and Planetary Science Conference, 2015, p. 2203.

316. C. Montag, R. Laufer, R. Srama, G. Herdrich, O. Przybilski, and T. Hyde, “Integration of a Dust Accelerator into the IPG6-B Test Facility for Material Impact Tests,” in 46th Annual Lunar and Planetary Science Conference, 2015, p. 2068.

317. F. Odom et al., “Piezoelectric Dust Detector Design and Calibration for the Armadillo Program,” in 46th Annual Lunar and Planetary Science Conference, 2015, p. 2191.

318. T. Orlando, K. Fiege, C. Bennett, M. Trieloff, and R. Srama, “Space Weathering of Asteroids, Mercury, and the Moon,” in Space Weathering of Airless Bodies: An Integration of Remote Sensing Data, Laboratory Experiments and Sample Analysis Workshop, 2015, p. 2069.

319. J. Simolka et al., “Calibration of the Cassini Cosmic Dust Analyzer,” in European Planetary Science Congress, 2015, pp. EPSC2015––719.

320. R. H. Soja et al., “Meteor storms and showers with the IMEX model,” in International Meteor Conference Mistelbach, Austria, 2015, p. 66.

321. R. Soja et al., “Characteristics of the dust trail of 67P/Churyumov-Gerasimenko: an application of the IMEX model,” Astronomy & Astrophysics, vol. 583, p. A18, 2015.

322. R. Soja et al., “Use of the IMEX model to characterise meteor showers in the inner solar system,” in European Planetary Science Congress, 2015, pp. EPSC2015––579.

323. R. Srama et al., “Enceladus Icy Jet Analyzer (ENIJA): Search for life with a high resolution TOF-MS for in situ characterization of high dust density regions,” Eur. Planet. Sci. Congr, vol. 10, pp. 8–10, 2015.

324. R. Srama, “In situ dust measurements by the Cassini Cosmic Dust Analyzer in 2014 and beyond,” in European Planetary Science Congress, 2015, pp. EPSC2015––846.

325. R. Srama, “Cassini-CDA Science in 2014 and beyond,” in EGU General Assembly Conference Abstracts, 2015, p. 14081.

326. R. Srama et al., “ENIJA: Search for life with a high-resolution TOF-MS for in-situ compositonal analysis of nano-and micron-sized dust particles,” in EGU General Assembly Conference Abstracts, 2015, p. 13456.

327. R. Srama, “In-situ Staubforschung im Planetensystem-Datenaufbereitung und Staubmessungen mit Cassini: Abschlussbericht: 1.1. 2011-31.12. 2014.” Universität Stuttgart, Institut für Raumfahrtsysteme (IRS), Raumfahrtzentrum~…, 2015.

328. Z. Sternovsky et al., “Advanced In-Situ Detection and Chemical Analysis of Interstellar Dust Particles,” in AGU Fall Meeting Abstracts, 2015, pp. SH41D––2397.

329. Z. Sternovsky et al., “Hyperdust: An advanced in-situ detection and chemical analysis of microparticles in space,” in 2015 IEEE Aerospace Conference, IEEE, 2015, pp. 1–10.

330. F. Wiederschein et al., “Charge separation and isolation in strong water droplet impacts,” Physical Chemistry Chemical Physics, vol. 17, Art. no. 10, 2015.

331. N. Altobelli, “SUDA: A dust mass spectrometer for compositional surface mapping for a mission to Europa,” EPSC, 2014.

332. C. S. Arridge et al., “The science case for an orbital mission to Uranus: exploring the origins and evolution of ice giant planets,” Planetary and Space Science, vol. 104, pp. 122–140, 2014.

333. H. A. Bechtel et al., “Stardust Interstellar Preliminary Examination III: Infrared spectroscopic analysis of interstellar dust candidates,” Meteoritics & Planetary Science, vol. 49, Art. no. 9, 2014.

334. F. E. Brenker et al., “Stardust Interstellar Preliminary Examination V: XRF analyses of interstellar dust candidates at ESRF ID 13,” Meteoritics & Planetary Science, vol. 49, Art. no. 9, 2014.

335. A. Bryant et al., “FIFI-LS observation planning and data reduction,” in Ground-based and Airborne Instrumentation for Astronomy V, S. K. Ramsay, I. S. McLean, and H. Takami, Eds., SPIE, Jul. 2014. doi: 10.1117/12.2055565.

336. A. L. Butterworth et al., “Stardust Interstellar Preliminary Examination IV: Scanning transmission X-ray microscopy analyses of impact features in the Stardust Interstellar Dust Collector,” Meteoritics & Planetary Science, vol. 49, Art. no. 9, 2014.

337. K. Fiege et al., “Calibration of relative sensitivity factors for impact ionization detectors with high-velocity silicate microparticles,” Icarus, vol. 241, pp. 336–345, 2014.

338. G. J. Flynn et al., “Stardust Interstellar Preliminary Examination VII: Synchrotron X-ray fluorescence analysis of six Stardust interstellar candidates measured with the Advanced Photon Source 2-ID-D microprobe,” Meteoritics & Planetary Science, vol. 49, Art. no. 9, 2014.

339. D. R. Frank et al., “Stardust Interstellar Preliminary Examination II: Curating the interstellar dust collector, picokeystones, and sources of impact tracks,” Meteoritics & Planetary Science, vol. 49, Art. no. 9, 2014.

340. Z. Gainsforth et al., “Stardust Interstellar Preliminary Examination VIII: Identification of crystalline material in two interstellar candidates,” Meteoritics & Planetary Science, vol. 49, Art. no. 9, 2014.

341. J. K. Hillier et al., “Impact ionisation mass spectrometry of polypyrrole-coated pyrrhotite microparticles,” Planetary and Space Science, vol. 97, pp. 9–22, 2014.

342. T. Hirai et al., “Microparticle impact calibration of the Arrayed Large-Area Dust Detectors in INterplanetary space (ALADDIN) onboard the solar power sail demonstrator IKAROS,” Planetary and Space Science, vol. 100, pp. 87–97, 2014.

343. M. Horanyi et al., “Lunar Dust Experiment (LDEX): First results,” in EGU General Assembly Conference Abstracts, 2014, p. 4757.

344. M. Horanyi et al., “The lunar dust experiment (LDEX) onboard the lunar atmosphere and dust environment explorer (LADEE) mission,” Space Science Reviews, vol. 185, Art. no. 1, 2014.

345. M. Horányi et al., “The dust environment of the Moon as seen by the Lunar Dust Experiment (LDEX),” in 45th Lunar and Planetary Science Conference, 2014, pp. 93–113.

346. H.-W. Hsu et al., “Silica nanoparticles provide evidence for hydrothermal activities at Enceladus,” in Workshop on the Habitability of Icy Worlds, 2014, p. 4042.

347. H.-W. Hsu et al., “Composition mapping of Saturn’s main rings during the Proximal orbits,” in EGU General Assembly Conference Abstracts, 2014, p. 15755.

348. H.-W. Hsu, F. Postberg, S. Kempf, M. Horanyi, and R. Srama, “From the subsurface ocean of Enceladus to interplanetary space-the journey of Saturnian stream particles,” in EGU General Assembly Conference Abstracts, 2014, p. 15159.

349. S. Kempf et al., “Compositional mapping of Europa’s surface with a dust mass spectrometer,” in Workshop on the Habitability of Icy Worlds, 2014, p. 4052.

350. S. Kempf et al., “Observations of the lunar dust exosphere with LDEX,” in 45th Annual Lunar and Planetary Science Conference, 2014, p. 1389.

351. S. Kempf et al., “The Lunar Dust Exosphere as Observed by LDEX,” in European Planetary Science Congress, 2014, pp. EPSC2014––228.

352. S. Kempf, N. Altobelli, M. Horanyi, and R. Srama, “The mass flux of micrometeoroids into the Saturnian system,” in European Planetary Science Congress, 2014, pp. EPSC2014––227.

353. S. Kempf, N. Altobelli, M. Horanyi, and R. Srama, “The mass flux of micrometeoroids into the Saturn,” in EGU General Assembly Conference Abstracts, 2014, p. 15324.

354. S. Kempf, E. Gruen, M. Horanyi, R. Srama, J. Szalay, and Z. Sternovsky, “The properties of the Lunar dust exosphere,” in AGU Fall Meeting Abstracts, 2014, pp. P23C––4005.

355. M. Kobayashi et al., “Frequency Analysis of Dust Signal from Piezoelectric PZT Sensor,” in 45th Annual Lunar and Planetary Science Conference, 2014, p. 2027.

356. Y. Li et al., “Instrument study of the Lunar Dust eXplorer (LDX) for a lunar lander mission,” Advances in Space Research, vol. 54, Art. no. 10, 2014.

357. Y. Li, S. Bugiel, H. Strack, and R. Srama, “A Cosmic Dust Sensor Based on an Array of Grid Electrodes,” in European Planetary Science Congress, 2014, pp. EPSC2014––269.

358. Y. Li and R. Srama, “A Dust Sensor for Planetary Rovers,” in European Planetary Science Congress, 2014, pp. EPSC2014––485.

359. Y. Li et al., “Morphology of craters generated by hypervelocity impacts of micron-sized polypyrrole-coated olivine particles,” Meteoritics & Planetary Science, vol. 49, Art. no. 8, 2014.

360. Y. Li, R. Srama, and E. Grun, “The Detection of Impact Ejecta on the Lunar Surface,” in European Planetary Science Congress, 2014, pp. EPSC2014––254.

361. A. Masters et al., “Neptune and Triton: Essential pieces of the Solar System puzzle,” Planetary and Space Science, vol. 104, pp. 108–121, 2014.

362. R. Namikis, M. Horanyi, F. Postberg, R. Srama, and S. Kempf, “The dynamical properties of E-ring particles derived from CDA impact mass spectra,” in AGU Fall Meeting Abstracts, 2014, pp. P13A––3791.

363. L. O’Brien et al., “Development of the nano-dust analyzer (NDA) for detection and compositional analysis of nanometer-size dust particles originating in the inner heliosphere,” Review of Scientific Instruments, vol. 85, Art. no. 3, 2014.

364. E. Perinati et al., “Bumber filter against micrometeoroids for eROSITA,” in Space Telescopes and Instrumentation 2014: Ultraviolet to Gamma Ray, SPIE, 2014, pp. 1491–1496.

365. F. Postberg, K. Fiege, N. Altobelli, R. Srama, and M. Trieloff, “Mass spectrometry of contemporary interstellar dust by the Cassini space craft,” in 77th Annual Meeting of the Meteoritical Society, 2014, p. 5272.

366. F. Postberg et al., “Stardust Interstellar Preliminary Examination IX: High-speed interstellar dust analog capture in Stardust flight-spare aerogel,” Meteoritics & Planetary Science, vol. 49, Art. no. 9, 2014.

367. K. Schindler, J. Wolf, and A. Krabbe, “Characterization of InGaAs-based cameras for astronomical applications using a new VIS-NIR-SWIR detector test bench,” Proc. SPIE, vol. 9145, pp. 91450X–91450X, 2014, doi: 10.1117/12.2057052.

368. M. Seiss et al., “Pallene dust torus,” in AGU Fall Meeting Abstracts, 2014, pp. P11B––3758.

369. M. Seiß et al., “Pallene dust torus observations by the cosmic dust analyzer,” in European Planetary Science Congress, 2014, pp. EPSC2014––375.

370. A. Shu, S. Bugiel, E. Gruen, M. Horanyi, T. Munsat, and R. Srama, “Cratering Studies in Thin Plastic Films,” in AGU Fall Meeting Abstracts, 2014, pp. P13D––3857.

371. A. S. Simionovici et al., “Stardust Interstellar Preliminary Examination VI: Quantitative elemental analysis by synchrotron X-ray fluorescence nanoimaging of eight impact features in aerogel,” Meteoritics & Planetary Science, vol. 49, Art. no. 9, 2014.

372. R. Soja et al., “The Interplanetary Meteoroid Environment for eXploration,” Asteroids, Comets, Meteors, 2014.

373. R. H. Soja et al., “The Interplanetary Meteoroid Environment for eXploration-(IMEX) project,” in Proceedings of the International Meteor Conference, Giron, France, 2014, p. 2014.

374. R. Srama et al., “Highlights and discoveries of the Cosmic Dust Analyser (CDA) during its 15 years of exploration,” in European Planetary Science Congress, 2014, pp. EPSC2014––506.

375. R. Srama, H.-W. Hsu, G. Moragas-Klostermeyer, F. Postberg, and S. Kempf, “In-situ dust detection as a tool to study dust-plasma interactions in the Solar System,” in AGU Fall Meeting Abstracts, 2014, pp. P31B––3983.

376. R. Srama, “The Cassini Cosmic Dust Analyser CDA-A 10 year exploration of Saturn’s dust environment,” in EGU General Assembly Conference Abstracts, 2014, p. 7641.

377. V. J. Sterken et al., “Stardust Interstellar Preliminary Examination X: Impact speeds and directions of interstellar grains on the Stardust dust collector,” Meteoritics & Planetary Science, vol. 49, Art. no. 9, 2014.

378. Z. Sternovsky et al., “Modeling the uv signal scattered into the lunar dust experiment (ldex) from the surface,” in 45th Annual Lunar and Planetary Science Conference, 2014, p. 2740.

379. Z. Sternovsky, S. Kempf, E. Gruen, M. Horanyi, and R. Srama, “Surface Dust Mass Analyzer for the Compositional Mapping of Icy Surfaces,” in Workshop on the Habitability of Icy Worlds, 2014, p. 4069.

380. Z. Sternovsky et al., “Modeling the UV Signal Scattered into the Lunar Dust Experiment (LDEX) from the Lunar Surface,” in EGU General Assembly Conference Abstracts, 2014, p. 4679.

381. R. M. Stroud et al., “Stardust Interstellar Preliminary Examination XI: Identification and elemental analysis of impact craters on Al foils from the Stardust Interstellar Dust Collector,” Meteoritics & Planetary Science, vol. 49, Art. no. 9, 2014.

382. J. Szalay, M. Horanyi, S. Kempf, E. Gruen, R. Srama, and Z. Sternovsky, “The Teardrop Shaped Lunar Dust Exosphere,” in AGU Fall Meeting Abstracts, 2014, pp. P21F––05.

383. A. J. Westphal et al., “Coordinated Microanalyses of Seven Particles of Probable Interstellar Origin from the Stardust Mission.,” Microscopy and Microanalysis, vol. 20, Art. no. S3, 2014.

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385. A. J. Westphal et al., “Final reports of the stardust interstellar preliminary examination,” Meteoritics & Planetary Science, vol. 49, Art. no. 9, 2014.

386. A. J. Westphal et al., “Final Reports of the Stardust ISPE: Seven Probable Interstellar Dust Particles,” 2014.

387. A. J. Westphal et al., “Stardust interstellar preliminary examination I: identification of tracks in aerogel,” Meteoritics & planetary science, vol. 49, Art. no. 9, 2014.

388. S.-Y. Ye et al., “Properties of dust particles near Saturn inferred from voltage pulses induced by dust impacts on Cassini spacecraft,” Journal of Geophysical Research: Space Physics, vol. 119, Art. no. 8, 2014.

389. S. Ye et al., “Dust Detection Using Radio and Plasma Wave Instruments in the Solar System,” in AGU Fall Meeting Abstracts, 2014, pp. P31B––3981.

390. N. Altobelli et al., “The Exogenous Dust Populations in the Saturnian’s System: a CDA Inventory,” in European Planetary Science Congress, 2013, pp. EPSC2013––677.

391. N. Altobelli, S. Kempf, G. Moragas, and R. Srama, “The Zodiacal Dust Cloud Populations at Saturn: signs of Centaurs activity? The point of view of CASSINI-CDA,” in EGU General Assembly Conference Abstracts, 2013, p. 13486.

392. C. Briois et al., “DOTS: A High Resolution Orbitrap Mass Spectrometer for In Situ Analysis of the surface samples of Airless Planetary Bodies,” in EGU General Assembly Conference Abstracts 15, 2013, p. 14225.

393. C. Briois et al., “Dust OrbiTrap Sensor (DOTS) for in-situ analysis of airless planetary bodies,” in 44th Lunar and Planetary Science Conference, 2013.

394. S. Close et al., “Detection of electromagnetic pulses produced by hypervelocity micro particle impact plasmas,” Physics of Plasmas, vol. 20, Art. no. 9, 2013.

395. K. Drake, Z. Sternovsky, M. Horányi, S. Kempf, and R. Srama, “Ejecta from Hypervelocity Dust Impacts Based on Light Flash Measurements,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 45, 2013, pp. 311–5.

396. K. Fiege et al., “Compositional Analysis of Interstellar Dust as seen by the Cassini Cosmic Dust Analyzer III,” in AGU Fall Meeting Abstracts, 2013, pp. P41G––1999.

397. E. Grün et al., “Comparative analysis of the esa and nasa interplanetary meteoroid environment models,” in 6th European Conference on Space Debris, 2013, p. 36.

398. J. Hillier et al., “Impact ionisation mass spectra of polypyrrole-coated pyrrhotite microparticles,” in European Planetary Science Congress, 2013, pp. EPSC2013––567.

399. J. K. Hillier, K. Fiege, M. Trieloff, and R. Srama, “Numerical modelling of mineral impact ionisation spectra,” Planetary and Space Science, vol. 89, pp. 159–166, 2013.

400. H.-W. Hsu et al., “Probing IMF using nanodust measurements from inside Saturn’s magnetosphere,” Geophysical Research Letters, vol. 40, Art. no. 12, 2013.

401. A. Juhasz, M. Horanyi, S. Kempf, and R. Srama, “Water Deposition into Titan atmosphere from Saturn’s E-ring,” in AGU Fall Meeting Abstracts, 2013, pp. P53C––1870.

402. S. Kempf, N. Altobelli, M. Horanyi, and R. Srama, “The mass flux of micrometeoroids into the saturnian system,” in AGU Fall Meeting Abstracts, 2013, pp. P21E––05.

403. S. Kempf, R. Srama, G. Moragas-Klostermeyer, H.-W. Hsu, M. Horanyi, and N. Altobelli, “The electro-static potential of E ring grains,” in EGU General Assembly Conference Abstracts, 2013, pp. EGU2013––12443.

404. M. Kobayashi et al., “Dust Observation in Mercurial Orbit by Mercury Dust Monitor of BepiColombo,” in 44th Annual Lunar and Planetary Science Conference, 2013, p. 2172.

405. N. Lee, S. Close, and R. Srama, “Composition of plasmas formed from debris impacts on spacecraft surfaces,” in 6th European Conference on Space Debris, ESA/ESOC, 2013.

406. N. Lee et al., “Theory and experiments characterizing hypervelocity impact plasmas on biased spacecraft materials,” Physics of Plasmas, vol. 20, Art. no. 3, 2013.

407. Y. Li et al., “A new design of charged particle trajectory sensor,” in European Planetary Science Congress, 2013, pp. EPSC2013––313.

408. Y. Li et al., “Morphology of Impact Craters Generated by Hyoervelocity Micron-Sized Olivine and Iron Particles,” in 6th European Conference on Space Debris, 2013, p. 209.

409. A. Mocker, D. James, Z. Sternovsky, S. Kempf, R. Srama, and M. Horányi, “LDEX Sensitivity studies: Material and impact velocity dependence of the total charge yield generated in hy-pervelocity impacts of micron and sub-micron sized dust particles,” Transition, vol. 10, Art. no. 12, 2013.

410. A. Mocker et al., “On the application of a linear time-of-flight mass spectrometer for the investigation of hypervelocity impacts of micron and sub-micron sized dust particles,” Planetary and Space Science, vol. 89, pp. 47–57, 2013.

411. L. O’Brien et al., “Development of the Nano-Dust Analyzer for Detection and Compositional Analysis of Nanometer-Sized Dust Particles Originating in the Inner Heliosphere,” in AGU Fall Meeting Abstracts, 2013, pp. SH13A––2055.

412. L. O’Brien et al., “Nano-Dust Analyzer For the Detection and Chemical Composition Measurement of Particles Originating in the Inner Heliosphere,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 45, 2013, pp. 311–3.

413. K. A. Otto et al., “Application and calibration of a simple position detector for a dust accelerator,” Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, vol. 729, pp. 841–848, 2013.

414. E. Perinati et al., “Micro-Meteoroid and Space Debris Impact Risk Assessment for LOFT Using ESABASE2 and Accelerator Tests,” in 6th European Conference on Space Debris, 2013, p. 207.

415. F. Postberg et al., “Silica nanoparticles as indicator of hydrothermal activities at Enceladus ocean floor,” in AGU Fall Meeting Abstracts, 2013, pp. P53B––1864.

416. F. Postberg et al., “Composition of Exogenous Dust at Saturn from Cassini-CDA Mass Spectra,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 45, 2013, pp. 402–2.

417. A. Shu et al., “Cratering Studies in Thin Plastic Films,” in AGU Fall Meeting Abstracts, 2013, pp. P51E––1775.

418. A. Shu et al., “Cratering Studies in Thin Polyvinylidene Fluoride Films,” in 44th Annual Lunar and Planetary Science Conference, 2013, p. 2490.

419. A. Shu et al., “Cratering studies in polyvinylidene fluoride (PVDF) thin films,” Planetary and Space Science, vol. 89, pp. 29–35, 2013.

420. A. Simionovici et al., “Quantification of Element Abundances of Stardust Interstellar Candidates by Synchrotron Radiation X-Ray Fluorescence Spectroscopy,” Meteoritics and Planetary Science Supplement, vol. 76, p. 5138, 2013.

421. V. J. Sterken et al., “The filtering of interstellar dust in the solar system,” Astronomy & Astrophysics, vol. 552, p. A130, 2013.

422. V. Sterken et al., “Calibration of impact ionization dust detectors with porous or fluffy dust particles,” in Dusty Visions Workshop, 2013, p. 1.

423. V. Sterken, P. Strub, R. Soja, R. Srama, H. Krüger, and E. Grün, “Development of a high resolution interstellar dust engineering model-overview of the project,” in European Planetary Science Congress, 2013, pp. EPSC2013––544.

424. F. Stolz, R. Reviol, R. Srama, M. Trieloff, F. Postberg, and B. Abel, “Liquid Beam Ion Desorption Mass Spectrometry for Evaluating CASSINI Data,” in EGU General Assembly Conference Abstracts, 2013, pp. EGU2013––11007.

425. P. Strub, V. Sterken, R. Soja, R. Srama, H. Krüger, and E. Grün, “Development of a high-resolution interstellar dust engineering model-technical implementation for fast simulations,” in European Planetary Science Congress, 2013, pp. EPSC2013––892.

426. J. Xie et al., “Laboratory testing and data analysis of the Electrostatic Lunar Dust Analyzer (ELDA) instrument,” Planetary and Space Science, vol. 89, pp. 63–70, 2013.

427. N. Altobelli et al., “CASSINI-CDA’s Hunt for Exogenous Dust Particles around Saturn,” in EGU General Assembly Conference Abstracts, 2012, p. 13222.

428. N. Altobelli, S. Kempf, F. Postberg, V. Sterken, R. Srama, and E. Gruen, “Insights on the Zodiacal Cloud Dust Populations at Saturn from CASSINI-CDA,” in European Planetary Science Congress 2012, 2012, pp. EPSC2012––768.

429. J. Carmona Reyes et al., “Multi Wall Carbon Nano Tubes as Material for a Space Elevator on the Moon,” in 43rd Annual Lunar and Planetary Science Conference, 2012, p. 2106.

430. B. Christophe et al., “OSS (Outer Solar System): a fundamental and planetary physics mission to Neptune, Triton and the Kuiper Belt,” Experimental Astronomy, vol. 34, Art. no. 2, 2012.

431. K. Fiege, S. Kempf, M. Trieloff, J. Hillier, and R. Srama, “Compositional Analysis of Interstellar Dust as seen by the Cassini Cosmic Dust Detector,” in AGU Fall Meeting Abstracts, 2012, pp. P31C––1912.

432. Z. Gainsforth et al., “Identification of crystalline material in two interstellar dust candidates from the Stardust mission,” in 43rd Lunar and Planetary Science Conference, 2012.

433. E. Grün et al., “Active cosmic dust collector,” Planetary and Space Science, vol. 60, Art. no. 1, 2012.

434. J. Hiller, F. Postberg, M. Price, M. Trieloff, Y. Li, and R. Srama, “3D laser scanning microscopy of hypervelocity impact features in metal and aerogel targets,” in European Planetary Science Congress, 2012.

435. J. Hillier et al., “Capture of high-speed interstellar dust analogues in Stardust flight spare aerogel,” in European Planetary Science Congress 2012, 2012, pp. EPSC2012––665.

436. J. Hillier et al., “Impact ionization mass spectra of anorthite cosmic dust analogue particles,” Journal of Geophysical Research: Planets, vol. 117, Art. no. E9, 2012.

437. M. Horányi et al., “The dust environment of the Moon: Expectations for the lunar dust experiment (LDEX),” in 43rd Annual Lunar and Planetary Science Conference, 2012, p. 2635.

438. S. Kempf, R. Srama, G. Moragas-Klostermeyer, J. Schmidt, F. Spahn, and M. Horanyi, “Saturn’s egg-shaped E ring,” in EGU General Assembly Conference Abstracts, 2012, p. 11409.

439. S. Kempf et al., “SUDA: a dust mass spectrometer for compositional surface mapping for the JUICE mission to the Galilean moons,” in AGU Fall Meeting Abstracts, 2012, pp. P51A––2015.

440. S. Kempf et al., “SUDA: A Dust Mass Spectrometer for Surface Mapping for the JUICE Mission to the Galilean Moons,” in International Workshop on Instrumentation for Planetary Missions, 2012, p. 1134.

441. S. Kempf et al., “Linear high resolution dust mass spectrometer for a mission to the Galilean satellites,” Planetary and Space Science, vol. 65, Art. no. 1, 2012.

442. S. Kempf, R. Srama, and A. Graps, “The Cosmic Dust Analyser Data Handbook,” cdaDataHB. pdf), available in an electronic version at http://atmos. nmsu. edu/data- and- services/atmospheres- data/Cassini/cda. html or by the author, 2012.

443. E. Khalisi and R. Srama, “Dust Counters onboard the Cassini spacecraft,” in European Planetary Science Congress, 2012.

444. M. Kobayashi et al., “Current status of Development of Mercury Dust Monitor for BepiColombo MMO,” in European Planetary Science Congress 2012, 2012, pp. EPSC2012––588.

445. N. Lee et al., “Measurements of freely-expanding plasma from hypervelocity impacts,” International Journal of Impact Engineering, vol. 44, pp. 40–49, 2012.

446. Y. Li et al., “Instrument Study of the Lunar Dust Experiment (LDX) for the ESA Lunar Lander,” in European Planetary Science Congress 2012, 2012, pp. EPSC2012––108.

447. A. Mocker et al., “A linear tof mass spectrometer as a tool for the investigation of impact ionisation plasma,” in AIP Conference Proceedings, American Institute of Physics, 2012, pp. 859–862.

448. A. Mocker et al., “On the applicability of laser ionization for simulating hypervelocity impacts,” Journal of Applied Physics, vol. 112, Art. no. 10, 2012.

449. A. Mocker et al., “Physics of hyper-velocity impacts of micrometer and sub-micrometer sized particles,” in APS March Meeting Abstracts, 2012, pp. J25––003.

450. L. OBrien et al., “Nano-Dust Analyzer for the detection and chemical composition measurement particles originating from near the Sun,” in AGU Fall Meeting Abstracts, 2012, pp. P31C––1908.

451. E. Perinati et al., “Accelerator experiments with soft protons and hyper-velocity dust particles: application to ongoing projects of future X-ray missions,” in Space Telescopes and Instrumentation 2012: Ultraviolet to Gamma Ray, SPIE, 2012, pp. 166–178.

452. F. Postberg, J. Schmidt, J. Hillier, S. Kempf, and R. Srama, “Geochemistry of Enceladus and the Galilean Moons from in situ Analysis of Ejecta,” in European Planetary Science Congress 2012, 2012, pp. EPSC2012––693.

453. F. Postberg et al., “Compositional Mapping of the Galilean Moons by Mass Spectrometry of Dust Ejecta,” in International Workshop on Instrumentation for Planetary Missions, 2012, p. 1099.

454. R. Reviol, F. Postberg, M. Trieloff, R. Srama, and B. Abel, “Simulation of TOF spectra from cosmic ice particles in the Laboratory by IR-FL-MALDI,” in European Planetary Science Congress 2012, 2012, pp. EPSC2012––489.

455. H. Shibata et al., “Development of MDM (Mercury Dust Monitor) Onboard BepiColombo Mission,” Asteroids, Comets, Meteors 2012, vol. 1667, p. 6480, 2012.

456. A. Shu et al., “3 MV hypervelocity dust accelerator at the Colorado Center for Lunar Dust and Atmospheric Studies,” Review of Scientific Instruments, vol. 83, Art. no. 7, 2012.

457. R. Srama et al., “A Dust Spectrometer for JUICE,” in European Planetary Science Congress 2012, 2012, pp. EPSC2012––839.

458. R. Srama et al., “Dust measurements at Saturn with Cassini: Past, Present and Future,” 39th COSPAR Scientific Assembly, vol. 39, p. 1867, 2012.

459. R. Srama et al., “In-situ dust measurements by a lunar lander,” 39th COSPAR Scientific Assembly, vol. 39, p. 1868, 2012.

460. R. Srama et al., “SARIM PLUS—sample return of comet 67P/CG and of interstellar matter,” Experimental Astronomy, vol. 33, Art. no. 2, 2012.

461. R. Srama, E. Gruen, H. Krueger, R. Laufer, and H.-P. Roeser, “The Earth micro-and submicro-particle environment,” 39th COSPAR Scientific Assembly, vol. 39, p. 1869, 2012.

462. V. J. Sterken, N. Altobelli, S. Kempf, G. Schwehm, R. Srama, and E. Grün, “The flow of interstellar dust into the solar system,” Astronomy & Astrophysics, vol. 538, p. A102, 2012.

463. V. Sterken et al., “An optimum opportunity for interstellar dust measurements by the JUICE mission,” Planetary and Space Science, vol. 71, Art. no. 1, 2012.

464. V. Sterken, A. Westphal, N. Altobelli, F. Postberg, R. Srama, and E. Grün, “Interstellar Dust Simulations for the Stardust Mission,” in 43rd Annual Lunar and Planetary Science Conference, 2012, p. 1878.

465. V. Sterken et al., “Modeling the local size distribution of interstellar dust in the solar system,” in EGU General Assembly Conference Abstracts, 2012, p. 449.

466. Z. Sternovsky et al., “Dust Mass Spectrometer for Compositional Mapping of the Galilean Moons,” in 44th annual meeting of the Division for Planetary Sciences of the American Astronomical Society, 2012.

467. Z. Sternovsky et al., “Improved Dust Detectors and Analyzers for Planetary Missions,” in International Workshop on Instrumentation for Planetary Missions, 2012, p. 1135.

468. R. M. Stroud et al., “Constraining the Origin of Impact Craters on Al Foils from the Stardust Interstellar Dust Collector,” in 43rd Lunar and Planetary Science Conference, 2012.

469. M. Trieloff et al., “Capture of High-Speed Interstellar Dust Analogues in Stardust Flight Spare Aerogel,” Meteoritics and Planetary Science Supplement, vol. 75, p. 5289, 2012.

470. A. Westphal et al., “Status of the Stardust ISPE and the Origin of Four Interstellar Dust Candidates,” in 43rd Lunar and Planetary Science Conference, 2012.

471. A. Wolf et al., “A modular, miniaturised, low-mass in-situ dust detector for piggyback payload opportunities on small spacecraft, landers and rovers,” in Proceedings of the International Astronautical Congress, IAC, 2012, pp. 4758–4765.

472. A. Wolf et al., “Piezo dust detector (PDD)—A modular miniaturized in-situ measurement instrument for dust research,” in 43rd Annual Lunar and Planetary Science Conference, 2012, p. 2136.

473. F. E. Brenker et al., “74 th Annual Meeting of the Meteoritical Society, August 8--12, 2011, London, UK,” Meteoritics & Planetary Science, vol. 46, 2011.

474. K. Drake et al., “Secondary Ejecta from Hypervelocity Dust Impacts,” in AGU Fall Meeting Abstracts, 2011, pp. P43A––1664.

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476. C. Floss et al., “Auger Analysis of Impact Craters from the Stardust Interstellar Foils,” Meteoritics and Planetary Science Supplement, vol. 74, p. 5102, 2011.

477. C. Floss et al., “Stardust Interstellar Foils I1061N, 1 and I1031N, 1: First Results from Automated Crater Searches and Future Analytical Possibilities,” in 42nd Annual Lunar and Planetary Science Conference, 2011, p. 1576.

478. E. Gruen et al., “A Nano-Dust Analyzer on the Moon,” in AGU Fall Meeting Abstracts, 2011, pp. P13D––1715.

479. H. Hoffmann et al., “A Dedicated Small Lunar Exploration Orbiter and a Mobile Surface Element,” 2011.

480. M. Horanyi, Z. Sternovsky, E. Grün, S. Kempf, R. Srama, and F. Postberg, “LDEX+: Lunar Dust Experiment with Chemical Analysis Capability to Search for Water,” in 42nd Annual Lunar and Planetary Science Conference, 2011, p. 1656.

481. M. Horányi et al., “iDUST: A mission concept for the ’dust tomography’of the heliosphere,” in EPSC-DPS Joint Meeting 2011, 2011, p. 1691.

482. M. Horányi, E. Grün, S. Kempf, Z. Sternovsky, F. Postberg, and R. Srama, “Dust Tomography of the Heliosphere,” 2011.

483. H.-W. Hsu et al., “Cassini dust stream particle measurements during the first three orbits at Saturn,” Journal of Geophysical Research: Space Physics, vol. 116, Art. no. A8, 2011.

484. H.-W. Hsu et al., “Stream particles as the probe of the dust-plasma-magnetosphere interaction at Saturn,” Journal of Geophysical Research: Space Physics, vol. 116, Art. no. A9, 2011.

485. T. Johnson et al., “Detection and analysis of RF data from hypervelocity impacts,” in 3rd AIAA Atmospheric Space Environments Conference, 2011, p. 3149.

486. S. Kempf et al., “Impact ionisation spectra of cosmic dust analogues,” in AGU Fall Meeting Abstracts, 2011, pp. P42A––06.

487. S. Kempf et al., “The 3-dimensional structure of Saturn’s E ring inferred from Cassini CDA observations,” Orbit, vol. 128, Art. no. 079, 2011.

488. S. Kempf, M. Horanyi, A. Juhasz, R. Srama, and G. Moragas-Klostermeyer, “The Phoebe dust ring as seen as by the Cassini dust detector CDA,” in AGU Fall Meeting Abstracts, 2011, pp. P13B––1673.

489. S. Kempf et al., “The Structure of Saturn’s E ring as seen by Cassini CDA,” in Proceedings of the 2011 EPSC-DPS Joint Meeting, Nantes, France, 2011, pp. 2–7.

490. E. Khalisi, R. Srama, and E. Grün, “Guide to the Impact Counters of the CDA,” Manual available in an electronic version from the author, 2011.

491. M. Kobayashi et al., “A future observational plan of dust particles around the Moon by LDM (Lunar Dust Monitor) onboard the orbiter of the next Japanese lunar mission,” Earth, planets and space, vol. 63, Art. no. 10, 2011.

492. N. Lee, S. Close, D. Lauben, R. Srama, A. Mocker, and S. Bugiel, “Characterizing Free Plasma Expansion due to Hypervelocity Dust Impacts,” in AGU Fall Meeting Abstracts, 2011, pp. P43A––1660.

493. N. Lee et al., “Study of hypervelocity impact plasma expansion,” in 3rd AIAA Atmospheric Space Environments Conference, 2011, p. 3147.

494. E. Mellado, K. Hornung, R. Srama, J. Kissel, S. Armes, and S. Fujii, “Mass spectrometry of impact fragmented polymers: The role of target properties,” International journal of impact engineering, vol. 38, Art. no. 6, 2011.

495. T. Miyachi et al., “Multimodal characteristics of a piezoelectric lead zirconate titanate element impacted with iron particles having velocities above 20 km/s,” Advances in space research, vol. 48, Art. no. 3, 2011.

496. A. Mocker, Z. Sternovsky, E. Grün, S. Kempf, and R. Srama, “Applicability of laser ionisation for the test and calibration of in-situ dust instruments,” in EPSC-DPS Joint Meeting 2011, 2011, p. 918.

497. A. Mocker et al., “Electrostatic accelerators for micrometer sized dust particles as a tool for planetary and impact physics research,” in EPSC-DPS Joint Meeting 2011, 2011, p. 815.

498. A. Mocker et al., “A 2 MV Van de Graaff accelerator as a tool for planetary and impact physics research,” Review of Scientific Instruments, vol. 82, Art. no. 9, 2011.

499. A. Mocker et al., “Methods for the Investigation of Impact Ionization Plasmas,” in AGU Fall Meeting Abstracts, 2011, pp. P43A––1665.

500. K. Otto, A. Mocker, S. Bugiel, Z. Sternovsky, Y. Xie, and R. Srama, “A Position Sensitive Beam Monitor for a Dust Accelerator,” in EPSC-DPS Joint Meeting 2011, 2011, p. 1052.

501. F. Postberg et al., “A new view on interstellar dust--high fidelity studies of interstellar dust analogue tracks in Stardust flight spare aerogel,” in 42nd Annual Lunar and Planetary Science Conference, 2011, p. 1823.

502. F. Postberg et al., “Geophysics and Geochemistry of Enceladus and the Galilean Moons from Analysis of Ejected Ice Particles,” in AGU Fall Meeting Abstracts, 2011, pp. P22B––07.

503. F. Postberg et al., “High Fidelity Studies of Interstellar Dust analogue Impacts in Stardust Aerogel and Foil,” Meteoritics and Planetary Science Supplement, vol. 74, p. 5447, 2011.

504. F. Postberg, J. Schmidt, J. Hillier, S. Kempf, and R. Srama, “The Compositional Profile of Enceladus Icy Dust Plume from Cassini In-Situ Measurements,” in 42nd Annual Lunar and Planetary Science Conference, 2011, p. 1849.

505. F. Postberg, J. Schmidt, J. Hillier, S. Kempf, and R. Srama, “The salty spray of Enceladus-Implications for the plume formation,” in EPSC-DPS Joint Meeting 2011, 2011, p. 642.

506. F. Postberg, J. Schmidt, J. Hillier, S. Kempf, and R. Srama, “A salt-water reservoir as the source of a compositionally stratified plume on Enceladus,” Nature, vol. 474, Art. no. 7353, 2011.

507. F. Postberg et al., “Compositional mapping of planetary moons by mass spectrometry of dust ejecta,” Planetary and Space Science, vol. 59, Art. no. 14, 2011.

508. J. Schmidt, F. Postberg, J. Hillier, S. Kempf, and R. Srama, “Dynamics of Enceladus’ Plume Particles and the Compositional Profile of the Plume,” in EPSC-DPS Joint Meeting 2011, 2011, p. 806.

509. J. Schmidt, F. Postberg, J. Hilier, S. Kempf, and R. Srama, “Compositional profile of the Enceladus dust plume,” 2011.

510. A. Shu et al., “Initial thin film penetration studies at the Colorado Center for Lunar Dust and Atmospheric Studies,” in AGU Fall Meeting Abstracts, 2011, pp. P43A––1662.

511. A. Simionovici et al., “High Fluence Synchrotron Radiation Microprobe Effects on Stardust Interstellar Dust Candidates,” in 42nd Annual Lunar and Planetary Science Conference, 2011, p. 2812.

512. A. Simionovici et al., “Synchrotron X-Ray irradiation of Stardust interstellar candidates: from″no″to″low″damage effects,” Meteoritics and Planetary Science, vol. 46, Art. no. Supplement s1, 2011.

513. R. Srama, H. Hsu, S. Kempf, and M. Horanyi, “Constraints on the nanoscale minerals on the surface of Saturnian icy moons,” in AGU Fall Meeting Abstracts, 2011, pp. P13B––1676.

514. R. Srama et al., “Dust spectrometry in the Jovian System,” in EPSC-DPS Joint Meeting 2011, 2011, p. 1502.

515. R. Srama et al., “The cosmic dust analyser onboard cassini: ten years of discoveries,” CEAS Space Journal, vol. 2, Art. no. 1, 2011.

516. V. Sterken et al., “Heliospheric filtering effects on the size distribution of interstellar grains in the solar system,” in AGU Fall Meeting Abstracts, 2011, pp. SH33B––2059.

517. V. Sterken et al., “Modeling Interstellar Dust Dynamics in the Solar System: Application to Stardust,” Meteoritics and Planetary Science Supplement, vol. 74, p. 5297, 2011.

518. V. Sterken et al., “The flow of interstellar dust through the solar system: the role of dust charging,” in AIP Conference Proceedings, American Institute of Physics, 2011, pp. 179–182.

519. Z. Sternovsky et al., “The calibration of the Lunar Dust Experiment (LDEX) instrument,” in AGU Fall Meeting Abstracts, 2011, pp. P43A––1666.

520. Z. Sternovsky et al., “Novel instrument for dust astronomy: Dust telescope,” in 2011 aerospace conference, IEEE, 2011, pp. 1–8.

521. Z. Sternovsky et al., “Frontiers in In-Situ Cosmic Dust Detection and Analysis,” in AIP Conference Proceedings, American Institute of Physics, 2011, pp. 173–178.

522. R. Stroud et al., “Identification of Impact Craters in Foils from the Stardust Interstellar Dust Collector,” in 42nd Lunar and Planetary Science Conference, 2011.

523. A. Westphal et al., “Constraints on the Interstellar Dust Flux Based on Stardust@ Home Search Results,” in 42nd Annual Lunar and Planetary Science Conference, 2011, p. 2059.

524. A. J. Westphal et al., “Four Interstellar Dust Candidates from the Stardust Interstellar Dust Collector,” in 42nd Lunar and Planetary Science Conference, 2011.

525. F. Wiederschein et al., “Charge Separation and Isolation in Water and Ice Particles on Strong Impacts,” Biophysical Journal, vol. 100, Art. no. 3, 2011.

526. J. Xie et al., “Dust trajectory sensor: Accuracy and data analysis,” Review of Scientific Instruments, vol. 82, Art. no. 10, 2011.

527. M. Zolensky et al., “FTIR analysis of aerogel keystones from the stardust interstellar dust collector: Assessment of terrestrial organic contamination and X-ray microprobe beam damage,” in 42nd Lunar and Planetary Science Conference, 2011.

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529. S. Auer et al., “A self-triggered dust trajectory sensor,” Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, vol. 622, Art. no. 1, 2010.

530. A. Collette et al., “The Colorado Center for Lunar Dust and Atmospheric Studies,” in AGU Fall Meeting Abstracts, 2010, pp. P51C––1449.

531. J. Cuzzi et al., “An evolving view of Saturn’s dynamic rings,” science, vol. 327, Art. no. 5972, 2010.

532. K. Drake et al., “Dust Telescopes and Active Dust Collectors: Linking Dust to Their Sources,” in AGU Fall Meeting Abstracts, 2010, pp. P33C––1579.

533. C. Floss et al., “Preliminary examination of Al foil I1061N, 1 from the stardust interstellar collector,” in 73rd Annual Meeting of the Meteoritical-Society, 2010, pp. A55––A55.

534. E. Gruen et al., “Compositional Mapping of the Surfaces of Europa and Ganymede,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 42, 2010, pp. 49–8.

535. E. Grün et al., “Nano-Dust Analyzer,” in AGU Fall Meeting Abstracts, 2010, pp. SH11B––1673.

536. E. Grün et al., “Ulysses Dust Detection System V3. 1,” NASA Planetary Data System, vol. 140, pp. ULY––D, 2010.

537. T. Hirai et al., “Development of a Light-Weight and Large-Area Parallel-Plate Impact Ionization Detector for In Situ Measurement of Dust/Debris,” in Advances in Geosciences: Volume 19: Planetary Science (PS), 2010, pp. 295–306.

538. M. Horanyi, Z. Sternovsky, E. Gruen, S. Kempf, R. Srama, and F. Postberg, “LDEX-PLUS: Lunar Dust Experiment with Chemical Analysis Capability to search for Water,” in AGU Fall Meeting Abstracts, 2010, pp. P11C––1353.

539. H.-W. Hsu et al., “Interaction of the solar wind and stream particles, results from the Cassini dust detector,” in AIP Conference Proceedings, American Institute of Physics, 2010, pp. 510–513.

540. T. Iwai et al., “Effect of Heating and Cooling on the Piezoelectric Properties of a PZT Sensor for Mercury Dust Monitor,” TRANSACTIONS OF THE JAPAN SOCIETY FOR AERONAUTICAL AND SPACE SCIENCES, AEROSPACE TECHNOLOGY JAPAN, vol. 8, Art. no. ists27, 2010.

541. A. T. Kearsley et al., “The Search for Interstellar Particle (ISP) Impacts on Stardust Aluminium Foils.,” in 73nd Annual Meeting of the Meteoritical-Society, 2010.

542. A. Kearsley et al., “Finding Interstellar Particle Impacts on Stardust Aluminium Foils: The Safe Handling, Imaging, and Analysis of Samples Containing Femtogram Residues,” in Lunar and Planetary Science Conference, 2010.

543. A. Kearsley et al., “The search for interstellar particle (ISP) impacts on stardust aluminum foils,” in 73rd Annual Meeting of the Meteoritical-Society, 2010, pp. A102––A102.

544. S. Kempf, J. Schmidt, R. Srama, F. Postberg, F. Spahn, and M. Horanyi, “Enceladus Dust production-new insights from Cassini,” in AGU Fall Meeting Abstracts, 2010, pp. P33A––1562.

545. S. Kempf, R. Srama, G. Moragas-Klostermeyer, F. Postberg, J. Schmidt, and F. Spahn, “The large scale structure of Saturn’s E ring and its sources,” in European Planetary Science Congress, 2010.

546. S. Kempf et al., “Observations of the Enceladus dust jets by the Cassini Dust Detector,” 38th COSPAR Scientific Assembly, vol. 38, p. 2, 2010.

547. E. Khalisi, R. Srama, and S. Kempf, “Statistical Analysis of Dust Impacts Acquired on the Cassini-Mission,” in European Planetary Science Congress 2010, 2010, p. 660.

548. H. Kruger et al., “Three years of Ulysses dust data: 2005 to 2007,” Planetary and Space Science, vol. 58, pp. 951–964, 2010.

549. N. Krupp, “The Cassini Enceladus encounters in the view of energetic particle measurements,” in EGU General Assembly Conference Abstracts, 2010, p. 4511.

550. H. Krüger et al., “Galileo Dust Detection System V4. 1,” NASA Planetary Data System, vol. 139, pp. GO––D, 2010.

551. H. Krüger et al., “Galileo dust data from the jovian system: 2000 to 2003,” Planetary and Space Science, vol. 58, Art. no. 7–8, 2010.

552. H. Krüger et al., “Three years of Ulysses dust data: 2005 to 2007,” Planetary and Space Science, vol. 58, Art. no. 7–8, 2010.

553. R. Laufer et al., “A Baylor University Payload Contribution to the Universitaet Stuttgart Moon Orbiter LUNAR MISSION BW1,” in 41st Annual Lunar and Planetary Science Conference, 2010, p. 2105.

554. R. Laufer, T. Hyde, L. Matthews, G. Herdrich, R. Srama, and H.-P. Roeser, “Establishing an Environmental Simulation Facility for Lunar Dust Research,” in 41st Annual Lunar and Planetary Science Conference, 2010, p. 2118.

555. R. Laufer, L. Matthews, G. Herdrich, R. Srama, and H.-P. Roeser, “Establishing an environmental simulation facility for complex (dusty) space plasma research,” 38th COSPAR Scientific Assembly, vol. 38, p. 6, 2010.

556. J. Leitner et al., “Preliminary examination of the stardust interstellar collector: Al foil I1044N, 1,” in 73rd Annual Meeting of the Meteoritical-Society, 2010, pp. A116––A116.

557. T. Miyachi et al., “Mass determination of hypervelocity microparticles using a piezoelectric PZT element,” 38th COSPAR Scientific Assembly, vol. 38, p. 11, 2010.

558. A. Mocker et al., “Progress in Dust Acceleration Techniques,” in European Planetary Science Congress 2010, 2010, p. 707.

559. A. Mocker et al., “The Heidelberg dust accelerator: Investigating hypervelocity particle impacts,” in AGU Fall Meeting Abstracts, 2010, pp. P31B––1524.

560. K. Nogami et al., “Development of the Mercury dust monitor (MDM) onboard the BepiColombo mission,” Planetary and Space Science, vol. 58, Art. no. 1–2, 2010.

561. F. Postberg et al., “A new Approach to Lab Simulation of High Speed Dust Impacts on Aerogel and Foils,” in European Planetary Science Congress 2010, 2010, p. 681.

562. F. Postberg et al., “Lab Simulation of Interstellar Dust: A New Approach for Hypervelocity Impact,” Meteoritics and Planetary Science Supplement, vol. 73, p. 5333, 2010.

563. F. Postberg et al., “Lab simulation of interstellar dust: a new approach for hypervelocity impact studies,” Meteoritics & Planetary Science, vol. 45, Art. no. Suppl. Suppl. S, 2010.

564. F. Postberg, J. Schmidt, S. Kempf, J. Hillier, and R. Srama, “The Compositional Profile of the Enceladian Ice Plume,” in European Planetary Science Congress 2010, 2010, p. 687.

565. F. Postberg et al., “High velocity Van de Graaff shots of mineral dust: Application to STARDUST and other in situ space missions,” in EGU General Assembly Conference Abstracts, 2010, p. 10935.

566. F. Postberg, J. Schmidt, J. Hillier, S. Kempf, and R. Srama, “The Compositional Profile of the Enceladus’ Ice Plume,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 42, 2010, pp. 16–8.

567. F. Postberg, J. Schmidt, S. Kempf, J. K. Hillier, and R. Srama, “The compositional profile of the ice particle plume at Enceladus,” 38th COSPAR Scientific Assembly, vol. 38, p. 6, 2010.

568. J. Schmidt, F. Postberg, S. Kempf, J. Hillier, and R. Srama, “Compositional profile of the Enceladian ice plume from in situ measurements,” in AGU Fall Meeting Abstracts, 2010, pp. P33A––1565.

569. J. Schmidt, F. Postberg, R. Srama, S. Kempf, and J. Hillier, “The Compositional Profile of the Enceladus Dust Plume II. Modeling,” in European Planetary Science Congress 2010, 2010, p. 847.

570. J. Schmidt et al., “Grain Dynamics in Enceladus’ Dust Plume and Feeding of the E Ring,” in EGU General Assembly Conference Abstracts, 2010, p. 13685.

571. A. Shu et al., “The Dust Accelerator Facility at CCLDAS,” in AGU Fall Meeting Abstracts, 2010, pp. P33C––1581.

572. R. Srama, G. Moragas-Klostermeyer, S. Kempf, M. Burton, and M. Roy, “Equatorial scans of Saturn’s dust density,” in European Planetary Science Congress 2010, 2010, p. 311.

573. R. Srama, “Two interstellar dust candidates from the stardust aerogel interstellar dust collector,” 2010.

574. R. Srama et al., “Faint dusty rings and streams: In-situ observations with Cassini at Saturn,” 38th COSPAR Scientific Assembly, vol. 38, p. 2, 2010.

575. R. Srama et al., “Lab Simulation Of Interstellar And Cometary Dust: A New Approach For Hypervelocity Impact Studies,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 42, 2010, pp. 48–14.

576. R. Srama, “Micrometeoroids,” Encyclopedia of Aerospace Engineering, 2010.

577. V. Sterken, S. Kempf, N. Altobelli, R. Srama, G. Moragas-Klostermeyer, and G. Schwehm, “Impacts and ejecta on and from Rhea using Cassini Cosmic Dust Analyser data,” 38th COSPAR Scientific Assembly, vol. 38, p. 7, 2010.

578. V. Sterken, S. Kempf, N. Altobelli, E. Grün, R. Srama, and G. Schwehm, “Simulations of interstellar dust particle trajectories in our Solar System,” in EGU General Assembly Conference Abstracts, 2010, p. 14004.

579. V. Sterken et al., “Constraining interstellar dust properties from dynamical studies and observations,” in European Planetary Science Congress 2010, 2010, p. 728.

580. Z. Sternovsky et al., “Planetary Magnetosphere Probed by Charged Dust Particles,” in AGU Fall Meeting Abstracts, 2010, pp. SM11C––1769.

581. Z. Sternovsky et al., “Interstellar Dust Instrumentation,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 42, 2010, pp. 49–10.

582. Z. Sternovsky, M. Horanyi, E. Gruen, and R. Srama, “The Lunar Dust EXperiment (LDEX) instrument for the Lunar Atmosphere and Dust Environment Explorer (LADEE) Mission,” 38th COSPAR Scientific Assembly, vol. 38, p. 5, 2010.

583. R. Stroud et al., “Preliminary examination of Al foil I1077W, 1 from the stardust interstellar collector,” in 73rd Annual Meeting of the Meteoritical-Society, 2010, pp. A198––A198.

584. A. Westphal et al., “Analysis of” Midnight” Tracks in the Stardust Interstellar Dust Collector: Possible Discovery of a Contemporary Interstellar Dust Grain,” in 41st Lunar and Planetary Science Conference, 2010.

585. A. J. Westphal et al., “Non-destructive search for interstellar dust using synchrotron microprobes,” in AIP Conference Proceedings, American Institute of Physics, 2010, pp. 131–138.

586. A. J. Westphal et al., “Two interstellar dust candidates from the stardust aerogel interstellar dust collector,” in 73rd Annual Meeting of the Meteoritical-Society, 2010, pp. A215––A215.

587. N. Altobelli et al., “Exploration of zodiacal dust environment at Saturn by CASSINI-CDA,” in AGU Fall Meeting Abstracts, 2009, pp. P51B––1127.

588. G. Davies et al., “Europlanet research infrastructure: planetary simulation facilities,” EPSC Abstracts, vol. 4, pp. 2009–63, 2009.

589. A. J. Espy et al., “Planetary Science Decadal Survey White Paper: Interplanetary Dust,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 41, 2009, pp. 16–33.

590. E. Grün et al., “DuneXpress,” Experimental astronomy, vol. 23, Art. no. 3, 2009.

591. J. K. Hillier, S. Sestak, S. Green, F. Postberg, R. Srama, and M. Trieloff, “The preparation of metal-coated mineral micro-particles for use in hypervelocity impact experiments,” Planetary and Space Science, vol. 57, Art. no. 14––15, 2009.

592. J. K. Hillier, S. Sestak, S. Green, F. Postberg, R. Srama, and M. Trieloff, “The production of platinum-coated silicate nanoparticle aggregates for use in hypervelocity impact experiments,” Planetary and Space Science, vol. 57, Art. no. 14–15, 2009.

593. M. Horányi, Z. Sternovsky, E. Gruen, R. Srama, M. Lankton, and D. Gathright, “The lunar dust experiment (LDEX) on the lunar atmosphere and dust environment explorer (LADEE) mission,” in 40th Annual Lunar and Planetary Science Conference, 2009, p. 1741.

594. H.-W. Hsu et al., “Stream particles observation during the Cassini-Huygens flyby of Jupiter,” in EGU General Assembly Conference Abstracts, 2009, p. 11638.

595. R. Jaumann et al., “Icy satellites: Geological evolution and surface processes,” in Saturn from Cassini-Huygens, Springer Netherlands Dordrecht, 2009, pp. 637–681.

596. S. Kempf, B. Uwe, J. Schmidt, F. Postberg, and R. Srama, “How the Enceladus Dust Jets Form Saturn’s E Ring,” in AGU Spring Meeting Abstracts, 2009, pp. P32A––05.

597. S. Kempf et al., “Long-term evolution of Saturn’s E ring particles,” in AGU Fall Meeting Abstracts, 2009, pp. P54A––01.

598. M. Küppers et al., “Triple F—a comet nucleus sample return mission,” Experimental Astronomy, vol. 23, Art. no. 3, 2009.

599. T. Munsat et al., “Program of the Colorado Center for Lunar Dust and Atmospheric Sciences,” in AGU Fall Meeting Abstracts, 2009, pp. P23C––1254.

600. F. Postberg, “Analysis of high velocity impacts of mineral dust-Applications for in situ space missions,” in European Planetary Science Congress 2009, 2009, p. 406.

601. F. Postberg et al., “Discriminating contamination from particle components in spectra of Cassini’s dust detector CDA,” Planetary and Space Science, vol. 57, Art. no. 12, 2009.

602. F. Postberg et al., “High Velocity van de Graaf Shots of Mineral Dust: Application to in Situ Space Missions,” Meteoritics & Planetary Science, vol. 44, Art. no. Suppl. S, 2009.

603. F. Postberg et al., “Salt-ice grains from Enceladus’ plumes: frozen samples of a subsurface ocean,” EPSC Abstracts, vol. 4, p. 411, 2009.

604. F. Postberg et al., “Sodium Salts in Ice Grains from Enceladus,” in EGU General Assembly Conference Abstracts, 2009, p. 12013.

605. F. Postberg et al., “Salt-Ice Grains from Enceladus’ Plumes: Frozen Samples of Subsurface Water,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 41, 2009, pp. 64–2.

606. F. Postberg et al., “Sodium salts in E-ring ice grains from an ocean below the surface of Enceladus,” Nature, vol. 459, Art. no. 7250, 2009.

607. J. Salter et al., “Mass spectra of organic and inorganic dust particles measured by an impact ionization mass analyzer instrument,” in AGU Fall Meeting Abstracts, 2009, pp. P11A––1194.

608. J. Schmidt et al., “On the Formation of Sodium Bearing E Ring Ice Grains on Enceladus,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 41, 2009, pp. 38–9.

609. A. Shu et al., “The Dust Accelerator Facility at CCLDAS,” in APS Division of Plasma Physics Meeting Abstracts, 2009, pp. BP8––105.

610. R. Srama et al., “High-Rate Dust Measurements with the Cosmic-Dust-Analyser,” in EGU General Assembly Conference Abstracts, 2009, p. 10742.

611. R. Srama, “Cassini-Huygens and beyond-tools for dust astronomy,” Universität Stuttgart Stuttgart, 2009.

612. R. Srama et al., “High velocity Van-de-Graff shots with mineral dust: An application for Stardust and other in-situ space missions,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 41, 2009, pp. 37–14.

613. R. Srama et al., “Mass spectrometry of hyper-velocity impacts of organic micrograins,” Rapid Communications in Mass Spectrometry: An International Journal Devoted to the Rapid Dissemination of Up-to-the-Minute Research in Mass Spectrometry, vol. 23, Art. no. 24, 2009.

614. R. Srama et al., “Sample return of interstellar matter (SARIM),” Experimental astronomy, vol. 23, Art. no. 1, 2009.

615. V. Sterken, N. Altobelli, S. Kempf, R. Srama, E. Grün, and G. Schwehm, “Adapting Cassini-CDA observation strategy to ISD detection in the Saturnian System,” in European Planetary Science Congress 2009, 2009, p. 174.

616. Z. Sternovsky, E. Gruen, F. Postberg, R. Srama, S. Kempf, and M. Horanyi, “In-situ composition analysis of dust particles originating from Europa and Ganymede in future missions and its scientific value,” in AGU Fall Meeting Abstracts, 2009, pp. P51E––1175.

617. S. Takechi et al., “Characteristics of piezoelectric lead zirconate titanate multilayered detector bombarded with hypervelocity iron particles,” Advances in space research, vol. 43, Art. no. 3, 2009.

618. S. Takechi et al., “Estimating the impact parameters of cosmic dust particles using a piezoelectric lead zirconate titanate detector,” Journal of atmospheric and solar-terrestrial physics, vol. 71, Art. no. 2, 2009.

619. S. Takechi et al., “Laboratory calibration measurements of a piezoelectric lead zirconate titanate cosmic dust detector at low velocities,” Advances in space research, vol. 43, Art. no. 6, 2009.

620. M. S. Tiscareno et al., “Rings Research in the Next Decade,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 41, 2009, pp. 16–32.

621. A. Westphal et al., “Stardust interstellar preliminary examination (ISPE),” in Lunar Planetary Science Conference, 2009.

622. N. André et al., “Identification of Saturn’s magnetospheric regions and associated plasma processes: Synopsis of Cassini observations during orbit insertion,” Reviews of Geophysics, vol. 46, Art. no. 4, 2008.

623. S. Auer et al., “Characteristics of a dust trajectory sensor,” Review of scientific instruments, vol. 79, Art. no. 8, 2008.

624. E. Grün, M. Horanyi, S. Auer, S. Robertson, R. Srama, and Z. Sternovsky, “Dust Telescope on the Lunar Surface,” in NLSI Lunar Science Conference, 2008, p. 2132.

625. M. Horanyi et al., “LDEX: Lunar Dust EXperiment,” in AGU Fall Meeting Abstracts, 2008, pp. P31B––1414.

626. H. Hsu et al., “The stream particle observation during Cassini’s Saturn tour,” in European Planetary Science Congress 2008, 2008, p. 772.

627. R. Jaumann et al., “German Lunar Exploration Orbiter (LEO): providing a globally covered, highly resolved, integrated, geological, geochemical, and geophysical data base of the Moon,” in 39th Annual Lunar and Planetary Science Conference, 2008, p. 1253.

628. G. H. Jones et al., “The dust halo of Saturn’s largest icy moon, Rhea,” Science, vol. 319, Art. no. 5868, 2008.

629. S. Kempf and R. Srama, “Saturn’s dust environment as seen by Cassini,” in European Planetary Science Congress 2008, 2008, p. 370.

630. S. Kempf, R. Srama, U. Beckmann, and J. Schmidt, “Saturn’s E ring as seen by the Cassini dust detector,” in AGU Fall Meeting Abstracts, 2008, pp. P32A––03.

631. S. Kempf et al., “The E ring in the vicinity of Enceladus: I. Spatial distribution and properties of the ring particles,” Icarus, vol. 193, Art. no. 2, 2008.

632. T. Miyachi et al., “Response of a pentagonal PZT element as a component of a 4$\pi$-real-time detector,” Advances in Space Research, vol. 41, Art. no. 7, 2008.

633. T. Miyachi et al., “Calibration of pentagonal PZT elements as a component of a 4-pai real-time detector,” 37th COSPAR Scientific Assembly, vol. 37, p. 2068, 2008.

634. T. Miyachi et al., “Measurement of temperature after hypervelocity collision of microparticles in the range from 10 to 40 km/s,” Applied Physics Letters, vol. 93, Art. no. 17, 2008.

635. T. Miyachi et al., “Position sensitive element for hypervelocity microparticles using a piezoelectric plate,” Japanese journal of applied physics, vol. 47, Art. no. 5R, 2008.

636. T. Munsat et al., “Experimental program for investigating the basic physics of the lunar atmosphere,” in AGU Fall Meeting Abstracts, 2008, pp. P31B––1397.

637. T. Munsat et al., “Micrometeorite Accelerator for Lunar Impact Studies: Needs and Capabilities,” in NLSI Lunar Science Conference, 2008, p. 2062.

638. F. Postberg et al., “Composition of Saturnian E-ring particles. Probing subsurface oceans of Enceladus?,” International Journal of Astrobiology, vol. 7, Art. no. 1, 2008.

639. F. Postberg et al., “Simulating STARDUST: Reproducing impacts of interstellar dust in the laboratory,” in European Planetary Science Congress 2008, 2008, p. 873.

640. F. Postberg, S. Kempf, N. Briliantov, J. Schmidt, U. Buck, and R. Srama, “Sodium discovered in Icy E ring Particles-Indicator for an Ocean Below Enceladus’ Surface,” in European Planetary Science Congress 2008, 2008, p. 778.

641. F. Postberg et al., “Sodium Salts in Ice Grains from Enceladus’ Plumes: Evidence for an Ocean below the Moon’s Surface,” in AGU Fall Meeting Abstracts, 2008, pp. P14A––03.

642. F. Postberg et al., “The E-ring in the vicinity of Enceladus II: Signatures of Enceladus in the elemental composition of E-ring particles,” Icarus, vol. 193, Art. no. 2, 2008.

643. F. Postberg et al., “The E-ring in the vicinity of Enceladus: II. Probing the moon’s interior—the composition of E-ring particles,” Icarus, vol. 193, Art. no. 2, 2008.

644. F. Postberg et al., “Organic molecules in saturnian E-ring particles. Probing subsurface oceans of Enceladus?,” in Organic Matter in Space, 2008, pp. 317–318.

645. S. Sasaki et al., “Development of plane parallel impact-ionization dust/debris detector,” 37th COSPAR Scientific Assembly, vol. 37, p. 2740, 2008.

646. J. Schmidt et al., “On the formation of sodium bearing E ring ice grains on Enceladus.,” in AGU Fall Meeting Abstracts, 2008, pp. P23B––1371.

647. R. Srama et al., “A Small Dust Telescope for the Measurement of Interplanetary Dust,” in European Planetary Science Congress 2008, 2008, p. 584.

648. R. Srama and S. Auer, “Low-charge detector for the monitoring of hyper-velocity micron-sized dust particles,” Measurement Science and Technology, vol. 19, Art. no. 5, 2008.

649. R. Srama et al., “Recent results of the Cosmic Dust Analyzer onboard Cassini,” 37th COSPAR Scientific Assembly, vol. 37, p. 3007, 2008.

650. R. Srama et al., “Saturn’s E-Ring: Dust distribution and dust potentials,” 37th COSPAR Scientific Assembly, vol. 37, p. 3006, 2008.

651. Z. Sternovsky et al., “Chemical Composition Measurement of Cosmic Dust from Impact Generated Plasmas,” in AGU Fall Meeting Abstracts, 2008, pp. MR13B––1712.

652. S. Takechi et al., “Investigation on piezoelectric lead zirconate titanate detector bombarded obliquely with hypervelocity iron particles,” Planetary and Space Science, vol. 56, Art. no. 9, 2008.

653. S. Takechi et al., “Response of piezoelectric lead zirconate titanate detector to oblique impact with hypervelocity iron particles,” Earth, planets and space, vol. 60, Art. no. 12, 2008.

654. S. Takechi et al., “Measurement of incident position of hypervelocity particles on piezoelectric lead zirconate titanate detector,” Review of Scientific Instruments, vol. 79, Art. no. 4, 2008.

655. S. Takechi et al., “Progress report on Mercury Dust Monitor for BepiColombo mission,” 37th COSPAR Scientific Assembly, vol. 37, p. 3130, 2008.

656. N. Altobelli et al., “Preliminary Results on Analysis of the Cosmic Dust Analyzer Data Between Jupiter and Saturn,” Dust in Planetary Systems, vol. 643, pp. 65–68, 2007.

657. N. Altobelli et al., “Solar and Heliospheric Physics-A07105-Cassini/Cosmic Dust Analyzer in situ dust measurements between Jupiter and Saturn (DOI 10. 102.9/2006JA011978),” Journal of Geophysical Research-Part A-Space Physics, vol. 112, Art. no. 7, 2007.

658. N. Altobelli et al., “Cassini/Cosmic Dust Analyzer in situ dust measurements between Jupiter and Saturn,” Journal of Geophysical Research: Space Physics, vol. 112, Art. no. A7, 2007.

659. U. Beckmann, S. Kempf, R. Srama, G. Moragas-Klostermeyer, S. Helfert, and E. Grün, “Feeding of Saturn’s E ring by Enceladus’ plumes,” in European Planetary Science Congress 2007, 2007, p. 806.

660. U. Beckmann, S. Kempf, R. Srama, G. Moragas-Klostermeyer, S. Helfert, and E. Grün, “Saturn’s E ring: in-situ measurements and modelling,” in European Planetary Science Congress 2007, 2007, p. 870.

661. U. Beckmann, S. Kempf, R. Srama, G. Moragas-Klostermeyer, S. Helfert, and E. Grün, “Stream particles inside Saturn’s magnetosphere,” in European Planetary Science Congress 2007, 2007, p. 738.

662. E. Gruen et al., “Prospects of dust astronomy missions,” Dust in Planetary Systems, vol. 643, pp. 245–249, 2007.

663. E. Grün and R. Srama, “DuneXpress, in situ analysis of interstellar dust,” Geochimica et Cosmochimica Acta, vol. 71, Art. no. 15 Suppl. Suppl. S, 2007.

664. J. Hillier et al., “Impact Ionisation Mass Spectra of Mineral Microparticles,” MNRAS, vol. 377, pp. 1588–1596, 2007.

665. J. K. Hillier et al., “Interplanetary dust detected by the Cassini CDA Chemical Analyser,” Icarus, vol. 190, Art. no. 2, 2007.

666. J. K. Hillier et al., “The composition of Saturn’s E ring,” Monthly Notices of the Royal Astronomical Society, vol. 377, Art. no. 4, 2007.

667. R. Jaumann et al., “Lunar Exploration Orbiter (LEO): Providing a Globally Covered, Highly Resolved, Integrated Geological, Geochemical and Gephysical Data Base of the Moon,” in LEAG Workshop on Enabling Exploration: The Lunar Outpost and Beyond, 2007, pp. abstract––3010.

668. S. Kempf, R. Srama, G. Moragas-Klostermeyer, H. Henkel, R. Laufer, and E. Grün, “Dust camera for a Lunar orbiter,” in European Planetary Science Congress 2007, 2007, p. 346.

669. S. Kempf, R. Srama, U. Beckmann, F. Postberg, T. Economou, and J. Hillier, “The E ring as seen by the Cassini dust detector,” in European Planetary Science Congress 2007, 2007, p. 795.

670. S. Kempf, U. Beckmann, F. Postberg, R. Srama, and J. Schmidt, “The vertical structure of Saturn’s E ring as a consequence of the Enceladus plumes,” in AGU Fall Meeting Abstracts, 2007, pp. P21B––0543.

671. R. Laufer, W. Tost, O. Zeile, R. Srama, and H.-P. Roeser, “The Kordylewsky Clouds-An example for a cruise phase observation during the Lunar Mission BW1,” 2007.

672. N. McBride et al., “Cassini cosmic dust analyser: composition of dust at Saturn,” Dust in Planetary Systems, vol. 643, pp. 107–110, 2007.

673. F. Postberg et al., “Composition of submicron-sized particles in the Saturnian System,” in European Planetary Science Congress 2007, 2007, p. 793.

674. J. Saur, N. Schilling, F. Neubauer, D. Strobel, M. Dougherty, and C. Russell, “Properties of Enceladus’ gas plumes from simulations of the their plasma interaction with Saturn’s magnetosphere,” in AGU Fall Meeting Abstracts, 2007, pp. P12B––01.

675. R. Srama et al., “Galactic dust measurements with DuneXpress,” in European Planetary Science Congress 2007, 2007, p. 332.

676. R. Srama et al., “Laboratory tests of the large area mass analyser,” Dust in Planetary Systems, vol. 643, pp. 209–212, 2007.

677. R. Srama and E. Gruen, “SARIM: A mission for SAmple Return of Interstellar Matter,” in European Planetary Science Congress 2007, 2007, p. 338.

678. R. Srama et al., “A trajectory sensor for sub-micron sized dust,” Dust in Planetary Systems, vol. 643, pp. 213–217, 2007.

679. Z. Sternovsky et al., “Impact ionization mass spectrometer instrument development for cosmic dust particles,” in AGU Fall Meeting Abstracts, 2007, pp. P53A––0991.

680. Z. Sternovsky et al., “Large area mass analyzer instrument for the chemical analysis of interstellar dust particles,” Review of Scientific Instruments, vol. 78, Art. no. 1, 2007.

681. Z. Sternovsky et al., “The Large Area Mass Analyzer (LAMA) for in-situ chemical analysis of interstellar dust particles,” Dust in planetary systems, vol. 643, pp. 205–208, 2007.

682. N. Altobelli et al., “Cassini CDA dust measurements between Jupiter and Saturn,” in European Planetary Science Congress 2006, 2006, p. 475.

683. N. Altobelli, S. Lera, R. Srama, X. Vo, J. de Kam, and E. Gruen, “DuneXpress: dust astronomy with Dune and ConeXpress,” in European Planetary Science Congress 2006, 2006, p. 480.

684. K. Amyx et al., “Calibration of the Large Area Mass Analyzer (LAMA) instrument for the detection of cosmic dust,” in AGU Fall Meeting Abstracts, 2006, pp. P51C––1206.

685. U. Beckmann, S. Kempf, R. Srama, G. Moragas-Klostermeyer, S. Helfert, and E. Grun, “Dust in the vicinity of Enceladus’ orbit,” in European Planetary Science Congress 2006, 2006, p. 360.

686. U. Beckmann, S. Kempf, R. Srama, G. Moragas-Klostermeyer, S. Helfert, and E. Grun, “Origin of Saturnian dust streams,” in European Planetary Science Congress 2006, 2006, p. 362.

687. U. Beckmann, S. Kempf, R. Srama, G. Moragas-Klostermeyer, S. Helfert, and E. Grun, “Stream particles inside Saturn’s magnetosphere: models for sources,” in European Planetary Science Congress 2006, 2006, p. 361.

688. U. Beckmann, S. Kempf, R. Srama, G. Moragas-Klostermeyer, S. Helfert, and E. Grün, “Saturn’s E ring: sources and dynamics,” in 36th COSPAR Scientific Assembly, 2006, p. 2320.

689. T. Economou, R. Srama, S. Kempf, G. Moragas-Klostermeyer, M. Burton, and M. Roy, “HRD Dust Results from Saturn’s E and G Ring Crossings,” in 36th COSPAR Scientific Assembly, 2006, p. 3301.

690. S. Fujii et al., “Synthesis and characterization of polypyrrole-coated sulfur-rich latex particles: New synthetic mimics for sulfur-based micrometeorites,” Chemistry of materials, vol. 18, Art. no. 11, 2006.

691. E. Gruen, R. Srama, M. Horanyi, Z. Sternovsky, and S. Auer, “A Dust Observatory on the Lunar Surface,” in AGU Fall Meeting Abstracts, 2006, pp. SM43A––1479.

692. E. Grün, R. Srama, and C. D. Team, “The Cosmic DUNE dust astronomy mission,” in 36th COSPAR Scientific Assembly, 2006, p. 3008.

693. E. Grün, I. de Pater, M. Showalter, F. Spahn, and R. Srama, “Physics of dusty rings: History and perspective,” Planetary and Space Science, vol. 54, Art. no. 9–10, 2006.

694. J. Hillier et al., “Interplanetary dust detected by Cassini’s cosmic dust analyser,” in European Planetary Science Congress 2006, 2006, p. 453.

695. J. K. Hillier, N. McBride, S. Green, S. Kempf, and R. Srama, “Modelling CDA mass spectra,” Planetary and Space Science, vol. 54, Art. no. 9–10, 2006.

696. S. Kempf et al., “Saturn’s E ring as seen by Cassini,” in European Planetary Science Congress 2006, 2006, p. 367.

697. S. Kempf, U. Beckmann, R. Srama, M. Horanyi, S. Auer, and E. Grün, “The electrostatic potential of E ring particles,” Planetary and Space Science, vol. 54, Art. no. 9–10, 2006.

698. H. Kruger et al., “In-situ Monitoring of Interstellar Dust in the Solar System,” in European Planetary Science Congress 2006, 2006, p. 174.

699. H. Krüger et al., “Five years of Ulysses dust data: 2000--2004,” Planetary and Space Science, vol. 54, Art. no. 9–10, 2006.

700. H. Krüger et al., “Galileo dust data from the jovian system: 1997--1999,” Planetary and Space Science, vol. 54, Art. no. 9–10, 2006.

701. M. Landgraf et al., “The Sky in Dust--Methods and Prospects of Dust Astronomy,” arXiv preprint astro-ph/0602096, 2006.

702. G. Moragas-Klostermeyer et al., “Dust impact charge measurements and calibration aspects by Cassini’s Dust Instrument, CDA,” in European Planetary Science Congress 2006, 2006, p. 648.

703. F. Postberg, R. Srama, S. Kempf, J. Hillier, S. Green, and N. McBride, “Cassini at Jupiter: composition of Jovian dust streams and the implications for the volcanism on Io,” in European Planetary Science Congress 2006, 2006, p. 123.

704. F. Postberg et al., “Eneceladus’ signatures in Saturbs E-ring,” in European Planetary Science Congress 2006, 2006, p. 246.

705. F. Postberg et al., “Composition of jovian dust stream particles,” Icarus, vol. 183, Art. no. 1, 2006.

706. F. Spahn et al., “Cassini dust measurements at Enceladus and implications for the origin of the E ring,” Science, vol. 311, Art. no. 5766, 2006.

707. R. Srama, Z. Sternowsky, E. Grün, and C. D. Team, “A real dust telescope for Cosmic DUNE,” in 36th COSPAR Scientific Assembly, 2006, p. 3128.

708. R. Srama et al., “Characteristics of a Dust Telescope,” in European Planetary Science Congress 2006, 2006, p. 413.

709. R. Srama et al., “Saturn’s dust environment: Experience from a two year survey with CDA,” in European Planetary Science Congress 2006, 2006, p. 441.

710. R. Srama et al., “DUNE-eXpress--Dust astronomy with ConeXpress,” Advances in Space Research, vol. 38, Art. no. 9, 2006.

711. R. Srama et al., “In situ dust measurements in the inner Saturnian system,” Planetary and Space Science, vol. 54, Art. no. 9–10, 2006.

712. T. Stephan, A. Butterworth, C. Snead, R. Srama, and A. Westphal, “TOF-SIMS Analysis of Aerogel Picokeystones-An Analogue to Stardust’s Interstellar Dust Collection,” in 37th Annual Lunar and Planetary Science Conference, 2006, p. 1448.

713. Z. Sternovsky et al., “The Large Area Mass Analyzer instrument for interplanetary dust particles,” in AGU Spring Meeting Abstracts, 2006, pp. P41A––03.

714. A. Westphal et al., “Stardust@ home: virtual microscope validation and first results,” in 37th Annual Lunar and Planetary Science Conference, 2006, p. 2225.

715. N. Altobelli, S. Kempf, and R. Srama, “Cassini Cosmic Dust Analyser Data V1. 0,” NASA Planetary Data System, vol. 49, pp. CO––D, 2005.

716. N. Altobelli, E. Griln, S. Kempf, H. Krilger, M. Landgraf, and R. Srama, “In-Situ Spacecraft Monitoring of the Interstellar Dust Stream in the Inner Solar System,” in Dust in Planetary Systems: Workshop Program and Abstracts, 2005, pp. 16–17.

717. N. Altobelli, M. Roy, S. Kempf, R. Srama, G. Moragas-Klostermeyer, and E. Grün, “Interplanetary Dust Between Jupiter and Saturn: Preliminary Results from the Cassini Cosmic Dust Analyzer,” Dust in Planetary Systems, vol. 1280, p. 18, 2005.

718. N. Altobelli, S. Kempf, H. Krüger, M. Landgraf, R. Srama, and E. Grün, “In-Situ Monitoring of Interstellar Dust in the Inner Solar System,” in AIP Conference Proceedings, American Institute of Physics, 2005, pp. 149–154.

719. M. Blanc et al., “The Cassini View of Saturn’s Magnetosphere,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 37, 2005, pp. 65–1.

720. M. Blanc et al., “Tracing the origins of the Solar System,” in 39th ESLAB Symposium” Trends in Space Science and Cosmic Vision 2020″, 2005.

721. E. Gruen et al., “Development and Tests of Elements of a Dust Telescope,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 37, 2005, pp. 18–9.

722. E. Grun et al., “Performance Tests of a Dust Telescope,” in AGU Fall Meeting Abstracts, 2005, pp. P41A––0927.

723. E. Grun et al., “PROSPECTS OF DUST A ASTRONOMY MISSION.,” in Dust in Planetary Systems: Workshop Program and Abstracts, 2005, pp. 61–62.

724. E. Grün et al., “Prospects of a Dust Astronomy Mission,” Dust in Planetary Systems, vol. 1280, p. 61, 2005.

725. E. Grün et al., “2002 Kuiper prize lecture: dust astronomy,” Icarus, vol. 174, Art. no. 1, 2005.

726. J. Hillier et al., “CASSINI COSMIC DUST ANALYSER: COMPOSITION OF DUST AT SATURN. N. McBride1,” in WORKSHOP PROGRAM AND ABSTRACTS, 2005, p. 117.

727. S. Kempf, R. Srama, M. Horanyi, C. S. Team, and others, “Electro-static potential of E ring particles,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 37, 2005, pp. 66–5.

728. S. Kempf, R. Srama, M. Horányi, M. Burton, and E. Griin, “Interaction of Saturnian Dust Streams with the Solar Wind,” in Dust in Planetary Systems: Workshop Program and Abstracts, 2005, p. 91.

729. S. Kempf et al., “Composition of saturnian stream particles,” Science, vol. 307, Art. no. 5713, 2005.

730. S. Kempf et al., “High-velocity streams of dust originating from Saturn,” Nature, vol. 433, Art. no. 7023, 2005.

731. N. McBride et al., “Cassini cosmic dust analyser: composition of dust at Saturn,” 2005.

732. T. Mendez, C. Snead, R. Srama, S. Tsitrin, J. Warren, and M. Zolensky, “STARDUST@ HOME: VIRTUAL MICROSCOPE VALIDATION AND FIRST RESULTS. AJ Westphal1,” in Proc. of the 36th Lunar Planet. Sci. Conf, 2005, pp. 108–212.

733. D. Mitchell et al., “Magnetospheric interaction with Saturn’s icy satellites,” in AGU Fall Meeting Abstracts, 2005, pp. P52A––01.

734. T. Miyachi et al., “Empirical formulas for hypervelocity impact with a piezoelectric element and their application to a new real-time dust detector,” in IEEE Nuclear Science Symposium Conference Record, 2005, IEEE, 2005, pp. 423–427.

735. T. Miyachi et al., “Velocity-dependent wave forms of piezoelectric elements undergoing collisions with iron particles having velocities ranging from 5to63km/ s,” Applied Physics Letters, vol. 86, Art. no. 23, 2005.

736. G. Moragas-Klostermeyer et al., “Generated dust impact charge measurements by Cassini’s Dust Instrument, CDA,” in Dust in Planetary Systems: Workshop Program and Abstracts, 2005, p. 121.

737. M. Rachev, R. Srama, R. Fettig, U. Köhler, D. Maas, and E. Grün, “Development of an ion-to-electron converter,” Review of scientific instruments, vol. 76, Art. no. 6, 2005.

738. M. Roy, M. Burton, G. M. Klostermeyer, R. Srama, S. Kempf, and S. Helfert, “The Cassini Spacecraft at Saturn: An Overview of Science and Science Operations,” in Dust in Planetary Systems: Workshop Program and Abstracts, 2005, p. 126.

739. F. Spahn et al., “E Ring Sources-Cassini Flybys with Enceladus,” Dust in Planetary Systems, vol. 1280, p. 132, 2005.

740. R. Srama et al., “A New Large Area TOF Mass Spectrometer,” Dust in Planetary Systems, vol. 1280, p. 134, 2005.

741. R. Srama et al., “Cassini Saturn Dust Measurements,” Dust in Planetary Systems, vol. 1280, p. 133, 2005.

742. R. Srama et al., “CDA measurements of Saturn’s E ring,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 37, 2005, pp. 6–5.

743. R. Srama et al., “Performance of an advanced dust telescope,” in 4th European Conference on Space Debris, 2005, p. 171.

744. R. Srama et al., “Trajectory Sensor for Sub-Micron Sized Dust,” Dust in Planetary Systems, vol. 1280, p. 135, 2005.

745. Z. Stemovsky et al., “DEVELOPMENT OF THE LARGE AREA MASS ANALYZER.,” in Dust in Planetary Systems: Workshop Program and Abstracts, 2005, p. 138.

746. Z. Sternovsky et al., “The Large Area Mass Analyzer: instrument to detect and analyze dust particles in space,” in AGU Fall Meeting Abstracts, 2005, pp. P41A––0928.

747. H. Abgrall et al., “Innanen, KA, 102 Ivanov, Boris, 84,” Icarus, vol. 171, p. 561, 2004.

748. N. Altobelli, E. Gruen, S. Kempf, H. Krueger, M. Landgraf, and R. Srama, “In-situ detection of interstellar dust at Earth orbit distance: possible delivery of pre-biotic material.,” in 35th COSPAR Scientific Assembly, 2004, p. 1845.

749. W. Brinckerhoff et al., “Universal mechanism of abiogenous synthesis of organic substances in the processes of SHVI. Pr-2104,” Preprint of Space Research Institute, Russian Academy of Sciences Moscow, Also in Geophysical Research Abstracts, vol. 7, p. 11171, 2004.

750. M. Burton et al., “Interaction of Saturnian Dust Stream Particles Detected by the Cassini Cosmic Dust Analyser (CDA) With the Interplanetary Medium on Approach to Saturn,” in AGU Fall Meeting Abstracts, 2004, pp. P51A––1420.

751. E. Grün et al., “Development of an advanced Dust Telescope,” in 35th COSPAR Scientific Assembly, 2004, p. 1735.

752. E. Grün et al., “Dust in interplanetary space and in the local galactic environment,” in Astrophysics of Dust, 2004, p. 245.

753. S. Kempf et al., “Exploring the dust cloud around phoebe,” in 35th COSPAR Scientific Assembly, 2004, p. 3768.

754. S. Kempf et al., “Stream particles as messengers from Saturn’s rings,” in AGU Fall Meeting Abstracts, 2004, pp. P51C––09.

755. S. Kempf et al., “Cassini between Earth and asteroid belt: first in-situ charge measurements of interplanetary grains,” Icarus, vol. 171, Art. no. 2, 2004.

756. K. Nogami et al., “Interplanetary and interstellar dust observation using PZT detector on board Bepi-Colombo MMO mission,” in 35th COSPAR Scientific Assembly, 2004, p. 4397.

757. M. Rachev, R. Srama, A. Srowig, and E. Grün, “Large area mass analyzer,” Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, vol. 535, Art. no. 1–2, 2004.

758. R. Srama et al., “Cruise results of the Cassini Cosmic-Dust-Analyzer,” in 35th COSPAR Scientific Assembly, 2004, p. 2587.

759. R. Srama et al., “Development of an advanced dust telescope,” Earth, Moon, and Planets, vol. 95, Art. no. 1, 2004.

760. R. Srama et al., “Dust astronomy with a dust telescope,” in Proceedings of the 37th ESLAB SymposiumTools and Technologies for Future Planetary Exploration’, Noordwijk, The Netherlands (ESA SP-543, April 2004). Editor: B. Battrick, p. 73-78, 2004, pp. 73–78.

761. R. Srama, M. Stübig, and E. Grün, “Laboratory detection of organic dust with the Cassini-CDA instrument,” Advances in Space Research, vol. 33, Art. no. 8, 2004.

762. R. Srama, “Staubmessungen mit CASSINI,” Sterne und Weltraum, vol. 43, Art. no. 9, 2004.

763. R. Srama et al., “The Cassini cosmic dust analyzer,” Space Science Reviews, vol. 114, Art. no. 1, 2004.

764. N. Altobelli et al., “Cassini between Venus and Earth: detection of interstellar dust grains,” in EGS-AGU-EUG Joint Assembly, 2003, p. 8767.

765. N. Altobelli, S. Kempf, R. Srama, E. Grün, M. Stübig, and M. Landgraf, “Dust measurements at 1 AU with Cassini-CDA,” Astrophysics of Dust, p. 99, 2003.

766. N. Altobelli et al., “Measurements of Interstellar Dust in the Heliosphere at 1 AU,” Astronomische Nachrichten Supplement, vol. 324, Art. no. 3, 2003.

767. N. Altobelli et al., “Cassini between Venus and Earth: Detection of interstellar dust,” Journal of Geophysical Research: Space Physics, vol. 108, Art. no. A10, 2003.

768. B. Goldsworthy et al., “INSTRUMENTS, OBSERVATIONAL TECHNIQUES, AND DATA PROCESSING-Time of flight mass spectra of ions in plasmas produced by hypervelocity impacts of organic and mineralogical microparticles on a cosmic,” Astronomy and Astrophysics-Les Ulis, vol. 409, Art. no. 3, 2003.

769. B. Goldsworthy et al., “Time of flight mass spectra of ions in plasmas produced by hypervelocity impacts of organic and mineralogical microparticles on a cosmic dust analyser,” Astronomy & Astrophysics, vol. 409, Art. no. 3, 2003.

770. E. Grün et al., “An Advanced Dust Telescope,” in AGU Fall Meeting Abstracts, 2003, pp. P41B––0401.

771. E. Grün et al., “Simulated Characteristics of an Advanced Dust Telescope,” in EGS-AGU-EUG Joint Assembly, 2003, p. 2005.

772. S. Kempf, N. Altobelli, S. Auer, E. Gruen, and R. Srama, “Discovery of charged interplanetary dust grains by Cassini,” in EGS-AGU-EUG Joint Assembly, 2003, p. 9976.

773. H. Krueger et al., “A Secondary Ion Mass Analyzer for Remote Surface Composition Analysis of the Galilean Moons,” in Forum on Concepts and Approaches for Jupiter Icy Moons Orbiter, 2003.

774. H. Kruger and R. Srama, “THEMEN DER WISSENSCHAFT-Staubastronomie,” Sterne und Weltraum, vol. 42, Art. no. 6, 2003.

775. H. Krüger et al., “Jovian dust streams: A monitor of Io’s volcanic plume activity,” Geophysical research letters, vol. 30, Art. no. 21, 2003.

776. H. Krüger and R. Srama, “Staubastronomie, ein neues Beobachtungsfenster in unsere Galaxis,” Sterne und Weltraum, vol. 41, Art. no. 6/2003, 2003.

777. N. Meidinger et al., “Experimental verification of a micrometeoroid damage in the PN-CCD camera system aboard XMM-Newton,” in X-ray and gamma-ray telescopes and instruments for astronomy, SPIE, 2003, pp. 243–254.

778. R. Srama et al., “Calibration limits of the Cosmic-Dust-Analyzer,” in EGS-AGU-EUG Joint Assembly, 2003, p. 3692.

779. R. Srama, “Cassini between Venus and Earth: Detection of interstellar dust,” Journal of Geophysical Research, 2003.

780. R. Srama et al., “Development of a Dust Telescope for a Dust Observatory,” Astronomische Nachrichten Supplement, vol. 324, Art. no. 3, 2003.

781. S. Auer, E. Grün, R. Srama, S. Kempf, and R. Auer, “The charge and velocity detector of the cosmic dust analyzer on Cassini,” Planetary and Space Science, vol. 50, Art. no. 7–8, 2002.

782. B. Goldsworthy et al., “Application of new, low density projectiles to the laboratory calibration of the Cassini Cosmic Dust Analyser (CDA),” in COSPAR Colloquia Series, Pergamon, 2002, pp. 300–304.

783. B. Goldsworthy et al., “Laboratory calibration of the cassini cosmic dust analyser (CDA) using new, low density projectiles,” Advances in Space Research, vol. 29, Art. no. 8, 2002.

784. M. Gordon et al., “Planetary Rings,” in The Future of Solar System Exploration (2003-2013)--First Decadal Study contributions, 2002, pp. 263–282.

785. A. Graps, E. Grün, H. Krüger, M. Horányi, R. Srama, and S. Kempf, “Fathom The Jovian Dust Streams: Recent Modeling Results,” in EGS General Assembly Conference Abstracts, 2002, p. 2484.

786. W. Grundy et al., “Probing The Solar System’s Outermost Frontier: The Future of Kuiper Belt Studies,” in The Future of Solar System Exploration (2003-2013)--First Decadal Study contributions, 2002, pp. 337–354.

787. E. Grün, S. Kempf, R. Srama, G. Moragas-Klostermeyer, and N. Altobelli, “Analysis of Impact Ionization From 300 Km/s Fast Projectiles,” in EGS General Assembly Conference Abstracts, 2002, p. 1921.

788. E. Grün et al., “Characteristics of an Advanced Dust Telescope,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 34, 2002, pp. 32–6.

789. E. Grün et al., “Dust astronomy: New venues in interplanetary and interstellar dust research,” in The Future of Solar System Exploration (2003-2013)--First Decadal Study contributions, 2002, pp. 283–296.

790. E. Grün et al., “Dust telescope: A new tool for dust research,” in COSPAR Colloquia Series, Pergamon, 2002, pp. 181–194.

791. S. Kempf, R. Srama, E. Gün, H. Krüger, M. Burton, and C. Team, “Jovian Dust Streams Revisited-Cassini Dust Detector At Jupiter,” in EGS General Assembly Conference Abstracts, 2002, p. 2407.

792. H. Krüger, E. Grün, M. Horanyi, A. Graps, R. Srama, and S. Kempf, “Five Years of Dust Measurements In The Jovian System,” in EGS General Assembly Conference Abstracts, 2002, p. 2437.

793. M. Muller et al., “CDA Cruise Science: Comparison of measured dust flux at 1 AU with models,” Advances in Space Research, vol. 29, Art. no. 15, 2002.

794. M. Müller et al., “CDA cruise science: Comparison of measured dust flux at 1AU with models,” in COSPAR Colloquia Series, Pergamon, 2002, pp. 160–163.

795. R. Srama, S. Kempf, and E. Grün, “CDA cruise science: Comparison of measured dust flux at 1AU with models M. Müllerab, BJ Goldsworthy, N. McBridea, b, SF Greena, b, JAM McDonnella, b,” Dust in the Solar System and Other Planetary Systems, vol. 15, p. 160, 2002.

796. R. Srama et al., “Detection of organic dust particles with the Cassini-CDA instrument,” in 34th COSPAR Scientific Assembly, 2002, p. 375.

797. R. Srama et al., “The cosmic dust analyzer onboard cassini-huygens: An overview of cruise science results,” in EGS General Assembly Conference Abstracts, 2002, p. 5464.

798. M. Stübig, G. Schäfer, T.-M. Ho, R. Srama, and E. Grün, “A new dust source for the Heidelberg dust accelerator,” in COSPAR Colloquia Series, Pergamon, 2002, pp. 290–295.

799. M. Stübig, R. Srama, E. Grün, and G. Schäfer, “Time-of-flight mass spectra from new projectile materials for calibration of the micrometeorite detector CDA,” in EGS General Assembly Conference Abstracts, 2002, p. 1364.

800. M. Zolensky, R. Srama, and E. Gruen, “Dust Astronomy: New Venues in Interplanetary and Interstellar Dust Research,” 2002.

801. E. Grun, A. Levasseur-Regourd, N. McBride, P. Palumbo, and R. Srama, “Cosmic Dune: an observatory for the study of interstellar and interplanetary dust,” Mission Definition Report--Draft ESA-SCI, vol. 5, 2001.

802. E. Grün et al., “A Novel Dust Telescope,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 33, 2001, pp. 57–3.

803. E. Grün, S. Kempf, H. Krüger, M. Landgraf, and R. Srama, “Dust astronomy: a new approach to the study of interstellar dust,” in Meteoroids 2001 Conference, 2001, pp. 651–662.

804. S. Kempf, R. Srama, E. Grün, V. Tschernjavski, and S. Auer, “In-situ measurement of the interplanetary dust charge,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 33, 2001, pp. 50–1.

805. H. Krüger, R. Srama, S. Kempf, A. Graps, M. Horányi, and E. Grün, “Simultaneous observations of a Jovian dust stream with Galileo and Cassini,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 33, 2001, p. 5.

806. H. Krüger et al., “Four years of Ulysses dust data: 1996--1999,” Planetary and Space Science, vol. 49, Art. no. 13, 2001.

807. H. Krüger et al., “One year of Galileo dust data from the Jovian system: 1996,” Planetary and Space Science, vol. 49, Art. no. 13, 2001.

808. P. Palumbo et al., “Scientific objectives and technologies for the Solar Orbiter dust detector,” in Solar encounter. Proceedings of the First Solar Orbiter Workshop, 2001, pp. 315–319.

809. R. Srama, “Simulation of Hypervelocity Dust Impacts with a 2MV Dust Accelerator Facility,” Space. Sci, vol. 49, Art. no. 8, 2001.

810. M. Stübig, E. Grün, J. Kissel, G. Schäfer, and R. Srama, “Advanced Laboratory Simulations of Micrometeorite Impacts for In Situ Investigation of Cosmic Dust with Impact Ionization Detectors,” Meteoritics & Planetary Science, vol. 36, Supplement, p. A200, vol. 36, p. A200, 2001.

811. M. Stübig, G. Schäfer, T.-M. Ho, R. Srama, and E. GrunGrün, “Laboratory simulation improvements for hypervelocity micrometeorite impacts with a new dust particle source,” Planetary and Space Science, vol. 49, Art. no. 8, 2001.

812. E. Gruen et al., “Dust Telescope: A New Tool for Dust Research,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 32, 2000, pp. 26–16.

813. E. Grun et al., “Techniques for galactic dust measurements in the heliosphere (Paper 1999JA900376),” JOURNAL OF GEOPHYSICAL RESEARCH-ALL SERIES-, vol. 105, Art. no. A5, 2000.

814. E. Grün, H. Krüger, R. Srama, and M. Horányi, “Unique conjunction of planetary probes,” Eos, Transactions American Geophysical Union, vol. 81, Art. no. 51, 2000.

815. E. Grün et al., “Galactic Dust Measurements Near Earth,” in Astronomische Gesellschaft Meeting Abstracts, 2000.

816. E. Grün et al., “Techniques for galactic dust measurements in the heliosphere,” Journal of Geophysical Research: Space Physics, vol. 105, Art. no. A5, 2000.

817. R. Srama, E. Grün, S. Kempf, S. Auer, C. S. Team, and others, “Dust charge measurements by the Cassini dust detector,” in AAS/Division for Planetary Sciences Meeting Abstracts\# 32, 2000, pp. 47–4.

818. R. Srama et al., “Jupiter dust stream observations with Cassini,” Max-Planck-Institut fr Kernphysik preprint, 2000.

819. R. Srama, “Vom cosmic-dust-analyzer zur modellbeschreibung wissenschaftlicher raumsonden,” Technische Universität München, 2000.

820. V. Sterken et al., “Modeling interstellar dust dynamics in the solar system: applications to Stardust, Ulysses and Cassini,” physical Research, vol. 105, pp. 10303–10316, 2000.

821. E. Grün et al., “Galactic dust measurements in the inner solar system.,” in Bulletin of the Astronomical Society, Vol. 31, No. 4, p. 1160, id. 55.03, 1999, p. 1160.

822. K. Scherer et al., “MOP: A space debris and interplanetary dust sample return mission,” in European Rocket and Balloon Programs and Related Research, 1999, p. 541.

823. F. Spahn, K.-U. Thiessenhusen, J. E. Colwell, R. Srama, and E. Grün, “Dynamics of dust ejected from Enceladus: Application to the Cassini dust detector,” Journal of Geophysical Research: Planets, vol. 104, Art. no. E10, 1999.

824. R. Srama, A. Graps, E. Gruen, S. Helfert, S. Kempf, and H. Krüger, “Initial measurements with the dust detector onboard Cassini.,” in Bulletin of the Astronomical Society, Vol. 31, No. 4, p. 1135, id. 40.06, 1999, p. 1135.

825. E. Grún et al., “A double-arm Møller Polarimeter for Jefferson Lab’s Hall B,” in APS Division of Nuclear Physics Meeting Abstracts, 1998, p. 2171.

826. E. Grün et al., “Galileo observes electromagnetically coupled dust in the Jovian magnetosphere,” Journal of Geophysical Research: Planets, vol. 103, Art. no. E9, 1998.

827. H. Krüger et al., “Three years of Galileo dust data: II. 1993--1995,” Planetary and Space Science, vol. 47, Art. no. 1–2, 1998.

828. H. Krüger et al., “Three years of Ulysses dust data: 1993 to 1995,” arXiv preprint astro-ph/9809133, 1998.

829. M. Baghul et al., “South-north and radial traverses through the zodiacal cloud,” Advances in Space Research, vol. 20, Art. no. 8, 1997.

830. E. Grün et al., “Dust measurements in the Jovian magnetosphere,” Geophysical research letters, vol. 24, Art. no. 17, 1997.

831. E. Grün et al., “South--North and radial traverses through the interplanetary dust cloud,” Icarus, vol. 129, Art. no. 2, 1997.

832. R. Srama and E. Grün, “The dust sensor for CASSINI,” Advances in Space Research, vol. 20, Art. no. 8, 1997.

833. J. G. Bradley, E. Gruen, and R. Srama, “Cosmic dust analyzer for Cassini,” in Cassini/Huygens: A Mission to the Saturnian Systems, SPIE, 1996, pp. 108–117.

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