Chih-Hsun Lin
Academia Sinica
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Publication
Featured researches published by Chih-Hsun Lin.
The Astrophysical Journal | 2011
Mark S. Bandstra; Eric C. Bellm; S. E. Boggs; Daniel Perez-Becker; Andreas Zoglauer; Hsiang-Kuang Chang; Jeng-Lun Chiu; Jau-Shian Liang; Y. H. Chang; Zong-Kai Liu; Wei-Che Hung; M.-H. A. Huang; S. J. Chiang; Ray-Shine Run; Chih-Hsun Lin; Mark Amman; Paul N. Luke; P. Jean; P. von Ballmoos; Cornelia B. Wunderer
The Nuclear Compton Telescope (NCT) is a balloon-borne Compton telescope designed for the study of astrophysical sources in the soft gamma-ray regime (200 keV–20 MeV). NCT’s 10 high-purity germanium crossedstrip detectors measure the deposited energies and three-dimensional positions of gamma-ray interactions in the sensitive volume, and this information is used to restrict the initial photon to a circle on the sky using the Compton scatter technique. Thus NCT is able to perform spectroscopy, imaging, and polarization analysis on soft gamma-ray sources. NCT is one of the next generation of Compton telescopes—the so-called compact Compton telescopes (CCTs)—which can achieve effective areas comparable to the Imaging Compton Telescope’s with an instrument that is a fraction of the size. The Crab Nebula was the primary target for the second flight of the NCT instrument, which occurred on 2009 May 17 and 18 in Fort Sumner, New Mexico. Analysis of 29.3 ks of data from the flight reveals an image of the Crab at a significance of 4σ . This is the first reported detection of an astrophysical source by a CCT.
IEEE Transactions on Nuclear Science | 2009
Eric C. Bellm; Steven E. Boggs; Mark S. Bandstra; Jason D. Bowen; Daniel Perez-Becker; Cornelia B. Wunderer; Andreas Zoglauer; Mark Amman; Paul N. Luke; Hsiang-Kuang Chang; Jeng-Lun Chiu; Jau-Shian Liang; Yuan-Hann Chang; Zong-Kai Liu; Wei-Che Hung; Chih-Hsun Lin; M.-H. A. Huang; P. Jean
The Nuclear Compton Telescope (NCT) is a balloon-borne telescope designed to study astrophysical sources of nuclear line emission and polarization at soft gamma-ray (0.2-10 MeV) energies. NCT uses high-purity germanium strip detectors for 3D tracking of photon interactions. Compton imaging enables effective background rejection, resulting in a compact but highly efficient instrument. The NCT prototype completed a successful flight from Fort Sumner, New Mexico in 2005. We have since integrated additional detectors, updated the readout electronics, and improved other flight systems. Two flights of the full instrument are upcoming: a conventional flight in New Mexico and a long duration flight from Australia. We give an overview of the instrument and its status prior to the planned balloon flights.
ieee nuclear science symposium | 2007
Mark E. Bandstra; Eric C. Bellm; Steven E. Boggs; Jason D. Bowen; Daniel Perez-Becker; Cornelia B. Wunderer; Andreas Zoglauer; Mark Amman; Paul N. Luke; Hsiang-Kuang Chang; Jeng-Lun Chiu; Jau-Shian Liang; Yuan-Hann Chang; Zong-Kai Liu; Chih-Hsun Lin; M.-H. A. Huang; P. Jean
The nuclear Compton telescope (NCT) is a balloon- borne soft gamma-ray (0.2 MeV-10 MeV) telescope designed to study astrophysical sources of nuclear line emission and polarization. A prototype instrument was successfully launched from Fort Sumner, New Mexico on June 1, 2005. The NCT prototype consisted of two 3D position sensitive high-purity germanium strip detectors (GeDs) fabricated with amorphous Ge contacts. We are currently working toward two balloon flights: another conventional balloon flight from Fort Sumner, New Mexico in September 2008, and a long-duration balloon flight (LDBF) from Alice Springs, Australia in December 2009. The NCT instrument is being upgraded to include all twelve planned GeDs. The electronics for all twelve detectors have been redesigned for smaller size, lower power consumption, and lower noise, and are now being fabricated and tested. Here we present our current progress in preparing for the flights.
arXiv: Instrumentation and Methods for Astrophysics | 2017
Carolyn A. Kierans; Steven E. Boggs; Jeng-Lun Chiu; Alex Lowell; Clio Sleator; John A. Tomsick; Andreas Zoglauer; Mark Amman; Hsiang-Kuang Chang; Chao-Hsiung Tseng; Chien-Ying Yang; Chih-Hsun Lin; P. Jean; Peter von Ballmoos
The Compton Spectrometer and Imager (COSI) is a balloon-borne, soft-gamma ray imager, spectrometer, and polarimeter with sensitivity from 0.2 to 5 MeV. Utilizing a compact Compton telescope design with twelve cross-strip, high-purity germanium detectors, COSI has three main science goals: study the 511 keV positron annihilation line from the Galactic plane, image diffuse emission from stellar nuclear lines, and perform polarization studies of gamma-ray bursts and other extreme astrophysical environments. COSI has just completed a successful 46-day flight on NASAs new Super Pressure Balloon, launched from Wanaka, New Zealand, in May 2016. We present an overview of the instrument and the 2016 flight, and discuss COSIs main science goals, predicted performance, and preliminary results.
The Astrophysical Journal | 2017
A. Lowell; S. E. Boggs; C. L. Chiu; C. A. Kierans; Clio Sleator; John A. Tomsick; Andreas Zoglauer; H. K. Chang; Chih-Kuo Tseng; C.-Y. Yang; P. Jean; P. von Ballmoos; Chih-Hsun Lin; Mark Amman
A long duration gamma-ray burst, GRB 160530A, was detected by the Compton Spectrometer and Imager (COSI) during the 2016 COSI Super Pressure Balloon campaign. As a Compton telescope, COSI is inherently sensitive to the polarization of gamma-ray sources in the energy range 0.2-5.0 MeV. We measured the polarization of GRB 160530A using 1) a standard method (SM) based on fitting the distribution of azimuthal scattering angles with a modulation curve, and 2) an unbinned, maximum likelihood method (MLM). In both cases, the measured polarization level was below the
ieee nuclear science symposium | 2009
Eric C. Bellm; Jeng-Lun Chiu; Daniel Perez-Becker; Jau-Shian Liang; Andreas Zoglauer; Mark S. Bandstra; Zong-Kai Liu; Steven E. Boggs; Hsiang-Kuang Chang; Yuan-Hann Chang; M.-H. A. Huang; Mark Amman; Wei-Che Hung; P. Jean; Chih-Hsun Lin; Paul N. Luke; Ray-Shine Run; Cornelia B. Wunderer
99\%
IEEE Transactions on Nuclear Science | 2009
Wei-Che Hung; Yuan-Hann Chang; Chih-Hsun Lin; Steven E. Boggs; Hsiang-Kuang Chang; Mark S. Bandstra; Eric C. Bellm; Jeng-Lun Chiu; Jau-Shian Liang; Zong-Kai Liu; Daniel Perez-Becker; Cornelia B. Wunderer; Andreas Zoglauer; Ming-Huey Huang; Mark Amman; Paul N. Luke
confidence minimum detectable polarization levels of
Proceedings of SPIE | 2016
A. Lowell; S. E. Boggs; Jeng-Lun Chiu; C. A. Kierans; S. McBride; Chih-Kuo Tseng; Andreas Zoglauer; Mark Amman; Hsiang-Kuang Chang; P. Jean; Chih-Hsun Lin; Clio Sleator; John A. Tomsick; P. von Ballmoos; C.-Y. Yang
72.3 \pm 0.8\%
ieee nuclear science symposium | 2009
Mark S. Bandstra; Eric C. Bellm; Jeng-Lun Chiu; Jau-Shian Liang; Zong-Kai Liu; Daniel Perez-Becker; Andreas Zoglauer; Steven E. Boggs; Hsiang-Kuang Chang; Yuan-Hann Chang; M.-H. A. Huang; Mark Amman; Shiuan Juang Chiang; Wei-Che Hung; P. Jean; Chih-Hsun Lin; Paul N. Luke; Ray-Shine Run; Cornelia B. Wunderer
(SM) and
IEEE Transactions on Nuclear Science | 2009
Zong-Kai Liu; Yuan-Hann Chang; Steven E. Boggs; Mark S. Bandstra; Eric C. Bellm; Jason D. Bowen; Daniel Perez-Becker; Cornelia B. Wunderer; Andreas Zoglauer; Mark Amman; Paul N. Luke; Hsiang-Kuang Chang; Jeng-Lun Chiu; Jau-Shian Liang; Chih-Hsun Lin; Wei-Che Hung
57.5 \pm 0.8\%
