Your search keyword '"Grundmann, J.T."' showing total 6 results

1. A nanolander for a space mission to an active asteroid in the main belt

Author

Ho, T.M., Kührt, E., Zhang, X.J., Auster, U., Biele, J., Grott, M., Grundmann, J.T., He, H., Hördt, A., Huang, J.C., Ma, T., Mottola, S., Otto, K., Plettemeier, D., Qin, L., Rubin, M., Schmitz, N., Ulamec, S., and Vincent, J.B.

Published

2023

2. Direct observations of asteroid interior and regolith structure: Science measurement requirements

Author

Herique, A., Agnus, B., Asphaug, E., Barucci, A., Beck, P., Bellerose, J., Biele, J., Bonal, L., Bousquet, P., Bruzzone, L., Buck, C., Carnelli, I., Cheng, A., Ciarletti, V., Delbo, M., Du, J., Du, X., Eyraud, C., Fa, W., Gil Fernandez, J., Gassot, O., Granados-Alfaro, R., Green, S.F., Grieger, B., Grundmann, J.T., Grygorczuk, J., Hahnel, R., Heggy, E., Ho, T-M., Karatekin, O., Kasaba, Y., Kobayashi, T., Kofman, W., Krause, C., Kumamoto, A., Küppers, M., Laabs, M., Lange, C., Lasue, J., Levasseur-Regourd, A.C., Mallet, A., Michel, P., Mottola, S., Murdoch, N., Mütze, M., Oberst, J., Orosei, R., Plettemeier, D., Rochat, S., RodriguezSuquet, R., Rogez, Y., Schaffer, P., Snodgrass, C., Souyris, J-C., Tokarz, M., Ulamec, S., Wahlund, J-E., and Zine, S.

Published

2018

3. Flexible Cu(In,Ga)Se2 Thin Film Solar Cells for Space Applications - Recent Results from a German Joint Project (PIPV2)

Author

Kaufmann, C.A., Greiner, D., Harndt, S., Klenk, R., Brunken, S., Schlatmann, R., Nichterwitz, M., Schock, H.-W., Unold, T., Zajac, K., Brunner, S., Daume, F., Scheit, C., Puttnins, S., Braun, A., Rahm, A., Würz, R., Kessler, F., Günthner, M., Pscherer, M., Ihlow, S., Motz, G., Morgner, H., Schmidt, R.G., Lambrecht, A., Grundmann, J.T., Spietz, P., and Schülke, P.

Subjects

THIN FILM SOLAR CELLS, CdTe, CIS and Related Ternary and Quaternary Thin Film Solar Cells

Abstract

29th European Photovoltaic Solar Energy Conference and Exhibition; 1439-1443, Since 2007 a German consortium of academic and industrial partners develops an extremely light and flexible Cu(In,Ga)Se2 (CIGSe) thin film solar cell technology for space applications. The combination with a light support structure and an appropriate interconnection technology enables the construction of a solar generator with previously unmatched specific power (W/kg). This can be attractive as power supply for large platforms in space and is also compatible with alternative, flexible large area applications. The idea of the project is to utilize a solar cell technology, which - in comparison to the highly efficient, multi-junction III-V technology - is cheap and can be fabricated using manufacturing facilities for the terrestrial technology. Project activities encompass topics as fundamental as CIGSe thin film growth, individual aspects of single device components and also device interconnection, together with a corresponding support structure development. So far a maximum efficiency of 12.6% (57.8 cm²; AM1.5) could be demonstrated on an in-line roll-to-roll fabricated single device and a support structure prototype with a projected area density

Published

2014

4. AsteroidFinder - a German Mission for the Search of IEOs

Author

Kührt, E., Mottola, S., Spietz, P., Behrens, J., Gerene, S., Grundmann, J.T., Hahn, G., Hallmann, M., Messina, G., Michaelis, H., and Scheibe, K.

Subjects

asteroids, space debris, space mission, IEOs

Published

2009

5. Direct Observations of Asteroid Interior and Regolith Structure: Science Measurement Requirements

Author

Herique, A., Agnus, B., Asphaug, E., Barucci, A., Beck, P., Bellerose, J., Biele, J., Bonal, L., Bousquet, P., Bruzzone, L., Buck, C., Carnelli, I., Cheng, A., Ciarletti, V., Delbo, M., Du, J., Du, X., Eyraud, C., Fa, W., Gil Fernandez, J., Gassot, O., Granados-Alfaro, R., Green, S. F., Grieger, B., Grundmann, J.T., Grygorczuk, J., Hahnel, R., Heggy, E., Ho, T-M., Karatekin, O., Kasaba, Y., Kobayashi, T., Kofman, W., Krause, C., Kumamoto, A., Küppers, M., Laabs, M., Lange, C., Lasue, J., Levasseur-Regourd, A. C., Mallet, A., Michel, P., Mottola, S., Murdoch, N., Mütze, M., Oberst, J., Orosei, R., Plettemeier, D., Rochat, S., RodriguezSuquet, R., Rogez, Y., Schaffer, P., Snodgrass, C., Souyris, J-C., Tokarz, M., Ulamec, S., Wahlund, J-E., Zine, S., Herique, A., Agnus, B., Asphaug, E., Barucci, A., Beck, P., Bellerose, J., Biele, J., Bonal, L., Bousquet, P., Bruzzone, L., Buck, C., Carnelli, I., Cheng, A., Ciarletti, V., Delbo, M., Du, J., Du, X., Eyraud, C., Fa, W., Gil Fernandez, J., Gassot, O., Granados-Alfaro, R., Green, S. F., Grieger, B., Grundmann, J.T., Grygorczuk, J., Hahnel, R., Heggy, E., Ho, T-M., Karatekin, O., Kasaba, Y., Kobayashi, T., Kofman, W., Krause, C., Kumamoto, A., Küppers, M., Laabs, M., Lange, C., Lasue, J., Levasseur-Regourd, A. C., Mallet, A., Michel, P., Mottola, S., Murdoch, N., Mütze, M., Oberst, J., Orosei, R., Plettemeier, D., Rochat, S., RodriguezSuquet, R., Rogez, Y., Schaffer, P., Snodgrass, C., Souyris, J-C., Tokarz, M., Ulamec, S., Wahlund, J-E., and Zine, S.

Abstract

Our knowledge of the internal structure of asteroids is, so far, indirect – relying entirely on inferences from remote sensing observations of the surface, and theoretical modeling of formation and evolution. What are the bulk properties of the regolith and deep interior? And what are the physical processes that shape asteroid internal structures? Is the composition and size distribution observed on the surface representative of the bulk? These questions are crucial to understand small bodies’ history from accretion in the early Solar System to the present, and direct measurements are needed to answer these questions for the benefit of science as well as for planetary defense or exploration. Radar is one of the main instruments capable of sounding asteroids to characterize internal structure from sub-meter to global scale. In this paper, we review the science case for direct observation of the deep internal structure and regolith of a rocky asteroid of kilometer size or smaller. We establish the requirements and model dielectric properties of asteroids to outline a possible instrument suite, and highlight the capabilities of radar instrumentation to achieve these observations. We then review the expected science return including secondary objectives contributing to the determination of the gravitational field, the shape model, and the dynamical state. This work is largely inherited from MarcoPolo-R and AIDA/AIM studies

6. Direct Observations of Asteroid Interior and Regolith Structure: Science Measurement Requirements

Author

Herique, A., Agnus, B., Asphaug, E., Barucci, A., Beck, P., Bellerose, J., Biele, J., Bonal, L., Bousquet, P., Bruzzone, L., Buck, C., Carnelli, I., Cheng, A., Ciarletti, V., Delbo, M., Du, J., Du, X., Eyraud, C., Fa, W., Gil Fernandez, J., Gassot, O., Granados-Alfaro, R., Green, S. F., Grieger, B., Grundmann, J.T., Grygorczuk, J., Hahnel, R., Heggy, E., Ho, T-M., Karatekin, O., Kasaba, Y., Kobayashi, T., Kofman, W., Krause, C., Kumamoto, A., Küppers, M., Laabs, M., Lange, C., Lasue, J., Levasseur-Regourd, A. C., Mallet, A., Michel, P., Mottola, S., Murdoch, N., Mütze, M., Oberst, J., Orosei, R., Plettemeier, D., Rochat, S., RodriguezSuquet, R., Rogez, Y., Schaffer, P., Snodgrass, C., Souyris, J-C., Tokarz, M., Ulamec, S., Wahlund, J-E., Zine, S., Herique, A., Agnus, B., Asphaug, E., Barucci, A., Beck, P., Bellerose, J., Biele, J., Bonal, L., Bousquet, P., Bruzzone, L., Buck, C., Carnelli, I., Cheng, A., Ciarletti, V., Delbo, M., Du, J., Du, X., Eyraud, C., Fa, W., Gil Fernandez, J., Gassot, O., Granados-Alfaro, R., Green, S. F., Grieger, B., Grundmann, J.T., Grygorczuk, J., Hahnel, R., Heggy, E., Ho, T-M., Karatekin, O., Kasaba, Y., Kobayashi, T., Kofman, W., Krause, C., Kumamoto, A., Küppers, M., Laabs, M., Lange, C., Lasue, J., Levasseur-Regourd, A. C., Mallet, A., Michel, P., Mottola, S., Murdoch, N., Mütze, M., Oberst, J., Orosei, R., Plettemeier, D., Rochat, S., RodriguezSuquet, R., Rogez, Y., Schaffer, P., Snodgrass, C., Souyris, J-C., Tokarz, M., Ulamec, S., Wahlund, J-E., and Zine, S.

Abstract

Our knowledge of the internal structure of asteroids is, so far, indirect – relying entirely on inferences from remote sensing observations of the surface, and theoretical modeling of formation and evolution. What are the bulk properties of the regolith and deep interior? And what are the physical processes that shape asteroid internal structures? Is the composition and size distribution observed on the surface representative of the bulk? These questions are crucial to understand small bodies’ history from accretion in the early Solar System to the present, and direct measurements are needed to answer these questions for the benefit of science as well as for planetary defense or exploration. Radar is one of the main instruments capable of sounding asteroids to characterize internal structure from sub-meter to global scale. In this paper, we review the science case for direct observation of the deep internal structure and regolith of a rocky asteroid of kilometer size or smaller. We establish the requirements and model dielectric properties of asteroids to outline a possible instrument suite, and highlight the capabilities of radar instrumentation to achieve these observations. We then review the expected science return including secondary objectives contributing to the determination of the gravitational field, the shape model, and the dynamical state. This work is largely inherited from MarcoPolo-R and AIDA/AIM studies