Your search keyword '"Buntrock, Sebastian"' showing total 4 results

1. Microchannel-Plate Detector Development for Ultraviolet Missions

Author

Conti, Lauro, Barnstedt, Jürgen, Buntrock, Sebastian, Diebold, Sebastian, Hanke, Lars, Kalkuhl, Christoph, Kappelmann, Norbert, Kaufmann, Thomas, Rauch, Thomas, Stelzer, Beate, Schanz, Thomas, Werner, Klaus, Elsener, Hans-Rudolf, Bougueroua, Sarah, Keilig, Thomas, Krabbe, Alfred, Maier, Philipp, Pahler, Andreas, Taheran, Mahsa, Wolf, Jürgen, Meyer, Kevin, and Schaadt, Daniel M.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The Institute for Astronomy and Astrophysics in T\"ubingen (IAAT) has a long-term experience in developing and building space-qualified imaging and photon counting microchannel-plate (MCP) detectors, which are sensitive in the ultraviolet wavelength range. Our goal is to achieve high quantum efficiency and spatial resolution, while maintaining solar blindness and low-noise characteristics. Our flexible detector design is currently tailored to the specific needs of three missions: For the ESBO DS (European Stratospheric Balloon Observatory Design Study) we provide a sealed detector to the STUDIO instrument (Stratospheric Ultraviolet Demonstrator of an Imaging Observatory), a 50 cm telescope with a UV imager for operation at an altitude of 37-41 km. In collaboration with the Indian Institute of Astrophysics we plan a space mission with a CubeSat-sized far-ultraviolet spectroscopic imaging instrument, featuring an open version of our detector. A Chinese mission, led by the Purple Mountain Observatory, comprises a multi-channel imager using open and sealed detector versions. Our MCP detector has a cesium activated p-doped gallium-nitride photocathode. Other photocathode materials like cesium-telluride or potassium-bromide could be used as an alternative. For the sealed version, the photocathode is operated in semi-transparent mode on a MgF$_2$ window with a cut-off wavelength of about 118 nm. For missions requiring sensitivity below this cut-off, we are planning an open version. We employ a coplanar cross-strip anode and advanced low-power readout electronics with a 128-channel charge-amplifier chip. This publication focuses on the progress concerning the main development challenges: the optimization of the photocathode parameters and the sophisticated detector electronics., Comment: Proc. SPIE Conf., Astronomical Telescopes and Instrumentation, 14-18 December 2020

Published

2020

2. Mapping Diffuse Emission in Lyman UV band

Author

Ji, Li, Lou, Zheng, Zhang, Jinlong, Qiu, Keqiang, Li, Shuangying, Sun, Wei, Yan, Shuping, Zhang, Shuinai, Qian, Yuan, Wang, Sen, Werner, Klaus, Fang, Taotao, Wang, Tinggui, Barnstedt, Jürgen, Buntrock, Sebastian, Cai, Mingsheng, Chen, Wen, Conti, Lauro, Deng, Lei, Diebold, Sebastian, Fu, Shaojun, Guo, Jianhua, Hanke, Lars, Hong, Yilin, Kalkuhl, Christoph, Kappelmann, Norbert, Kaufmann, Thomas, Lei, Shijun, Li, Fu, Li, Xinfeng, Liu, Wei, Meyer, Kevin, Rauch, Thomas, Ruan, Ping, Schaadt, Daniel M., Schanz, Thomas, Song, Qian, Stelzer, Beate, Wang, Zhanshan, Yang, Jianfeng, and Zhang, Wei

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Astrophysics of Galaxies, Astrophysics - High Energy Astrophysical Phenomena

Abstract

The CAFE (Census of warm-hot intergalactic medium, Accretion, and Feedback Explorer) and LyRIC (Lyman UV Radiation from Interstellar medium and Circum-galactic medium) have been proposed to the space agencies in China respectively. CAFE was first proposed in 2015 as a joint scientific CAS-ESA small space mission. LyRIC was proposed in 2019 as an independent external payload operating on the Chinese Space Station. Both missions are dedicated to mapping the Lyman UV emission (ionized oxygen (O VI) resonance lines at 103.2 and 103.8 nm, and Lyman series) for the diffuse sources in our Galaxy and the circum-galactic mediums of the nearby galaxies. We present the primary science objectives, mission concepts, the enabling technologies, as well as the current status., Comment: 9 pages, 6 figures, SPIE Astronomical Telescopes + Instrumentation 2020 conference Paper No. 11444-4

Published

2020

3. Mapping Lyman UV emission for diffuse sources

Author

Ji, Li, primary, Lou, Zheng, additional, Zhang, Jinlong, additional, Qiu, Keqiang, additional, Li, Shuangying, additional, Sun, Wei, additional, Yan, Shuping, additional, Zhang, Shuinai, additional, Qian, Yuan, additional, Wang, Sen, additional, Werner, Klaus, additional, Fang, Taotao, additional, Wang, Tinggui, additional, Barnstedt, Jürgen, additional, Buntrock, Sebastian, additional, Cai, Mingsheng, additional, Chen, Wen, additional, Conti, Lauro, additional, Deng, Lei, additional, Diebold, Sebastian, additional, Fu, Shaojun, additional, Guo, Jianhua, additional, Hanke, Lars, additional, Hong, Yilin, additional, Kalkuhl, Christoph, additional, Kappelmann, Norbert, additional, Kaufmann, Thomas, additional, Lei, Shijun, additional, Li, Fu, additional, Li, Xinfeng, additional, Liu, Wei, additional, Meyer, Kevin, additional, Rauch, Thomas, additional, Ruan, Ping, additional, Schaadt, Daniel M., additional, Schanz, Thomas, additional, Song, Qian, additional, Stelzer, Beate, additional, Wang, Zhanshan, additional, Yang, Jianfeng, additional, and Zhang, Wei, additional

Published

2020

4. MCP detector development for UV space missions

Author

Conti, Lauro, primary, Barnstedt, Jürgen, additional, Buntrock, Sebastian, additional, Diebold, Sebastian, additional, Hanke, Lars, additional, Kalkuhl, Christoph, additional, Kappelmann, Norbert, additional, Kaufmann, Thomas, additional, Rauch, Thomas, additional, Stelzer, Beate, additional, Schanz, Thomas, additional, Werner, Klaus, additional, Elsener, Hans-Rudolf, additional, Bouguerousa, Sarah, additional, Keilig, Thomas, additional, Krabbe, Alfred, additional, Maier, Philipp, additional, Pahler, Andreas, additional, Taheran, Mahsa, additional, Wolf, Jürgen, additional, Meyer, Kevin, additional, and Schaadt, Daniel M., additional

Published

2020