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1. The Cherenkov Telescope Array Science Goals and Current Status

   Ong, Rene A. (September 2019, EPJ web of conferences)

   The Cherenkov Telescope Array (CTA) is the major ground-based gamma-ray observatory planned for the next decade and beyond. Consisting of two large atmospheric Cherenkov telescope arrays (one in the southern hemisphere and one in the northern hemisphere), CTA will have superior angular resolution, a much wider energy range, and approximately an order of magnitude improvement in sensitivity, as compared to existing instruments. The CTA science programme will be rich and diverse, covering cosmic particle acceleration, the astrophysics of extreme environments, and physics frontiers beyond the Standard Model. This paper outlines the science goals for CTA and covers the current status of the project. 

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2. Gravitational-wave follow-up with CTA after the detection of GRBs in the TeV energy domain

   https://doi.org/10.1093/mnras/stz2848  

   Bartos, I.; Corley, K. R.; Gupte, N.; Ash, N.; Márka, Z.; Márka, S. (October 2019, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT The recent discovery of TeV emission from gamma-ray bursts (GRBs) by the MAGIC and H.E.S.S. Cherenkov telescopes confirmed that emission from these transients can extend to very high energies. The TeV energy domain reaches the most sensitive band of the Cherenkov Telescope Array (CTA). This newly anticipated, improved sensitivity will enhance the prospects of gravitational-wave follow-up observations by CTA to probe particle acceleration and high-energy emission from binary black hole and neutron star mergers, and stellar core-collapse events. Here we discuss the implications of TeV emission on the most promising strategies of choice for the gravitational-wave follow-up effort for CTA and Cherenkov telescopes more broadly. We find that TeV emission (i) may allow more than an hour of delay between the gravitational-wave event and the start of CTA observations; (ii) enables the use of CTA’s small size telescopes that have the largest field of view. We characterize the number of pointings needed to find a counterpart. (iii) We compute the annual follow-up time requirements and find that prioritization will be needed. (iv) Even a few telescopes could detect sufficiently nearby counterparts, raising the possibility of adding a handful of small-sized or medium-sized telescopes to the network at diverse geographic locations. (v) The continued operation of VERITAS/H.E.S.S./MAGIC would be a useful compliment to CTA’s follow-up capabilities by increasing the sky area that can be rapidly covered, especially in the United States and Australia, in which the present network of gravitational-wave detectors is more sensitive. 

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3. Technical and scientific performance of the prototype Schwarzschild-Couder telescope for CTA

   https://doi.org/10.1117/12.2594580  

   Adams, Colin B.; Ambrosi, Giovanni; Ambrosio, Michelangelo; Aramo, Carla; Batista, Pedro I.; Benbow, Wystan; Bertucci, Bruna; Bissaldi, Elisabetta; Bitossi, Massimiliano; Boiano, Alfonso; et al (August 2021, Proceedings Volume 11820, Astronomical Optics: Design, Manufacture, and Test of Space and Ground Systems III;)

   Hallibert, Pascal; Hull, Tony B.; Kim, Daewook; Keller, Fanny (Ed.)

   The Cherenkov Telescope Array (CTA) is the next-generation ground-based observatory for very-high-energy gamma rays. One candidate design for CTA's medium-sized telescopes consists of the Schwarzschild-Couder Telescope (SCT), featuring innovative dual-mirror optics. The SCT project has built and is currently operating a 9.7-m prototype SCT (pSCT) at the Fred Lawrence Whipple Observatory (FLWO); such optical design enables the use of a compact camera with state-of-the art silicon photomultiplier detectors. A partially-equipped camera has recently successfully detected the Crab Nebula with a statistical significance of 8.6 standard deviations. A funded upgrade of the pSCT focal plane sensors and electronics is currently ongoing, which will bring the total number of channels from 1600 to 11328 and the telescope field of view from about 2.7° to 8° . In this work, we will describe the technical and scientific performance of the pSCT. 

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4. Verification of the optical system of the 9.7-m prototype Schwarzschild-Couder Telescope

   https://doi.org/10.1117/12.2568134  

   Adams, Colin; Alfaro, Ruben; Ambrosi, Giovanni; Ambrosio, Michelangelo; Aramo, Carla; Benbow, Wystan; Bertucci, Bruna; Bissaldi, Elisabetta; Bitossi, M.; Boiano, Alfonso; et al (August 2020, SPIE Optical Engineering + Applications, 2020, Online Only)

   Sasián, José; Youngworth, Richard N. (Ed.)

   For the first time in the history of ground-based x-ray astronomy, the on-axis performance of the dual mirror, aspheric, aplanatic Schwarzschild-Couder optical system has been demonstrated in a 9:7-m aperture imaging atmospheric Cherenkov telescope. The novel design of the prototype Schwarzschild-Couder Telescope (pSCT) is motivated by the need of the next-generation Cherenkov Telescope Array (CTA) observatory to have the ability to perform wide (>=8°) field-of-view observations simultaneously with superior imaging of atmospheric cascades (resolution of 0:067 per pixel or better). The pSCT design, if implemented in the CTA installation, has the potential to improve significantly both the x-ray angular resolution and the off-axis sensitivity of the observatory, reaching nearly the theoretical limit of the technique and thereby making a major impact on the CTA observatory sky survey programs, follow-up observations of multi-messenger transients with poorly known initial localization, as well as on the spatially resolved spectroscopic studies of extended x-ray sources. This contribution reports on the initial alignment procedures and point-spread-function results for the challenging segmented aspheric primary and secondary mirrors of the pSCT. 

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5. Probing Extreme Environments with Very-High-Energy Gamma Rays

   Williams, David A.; Alves, Rafael Batista; Bird, Ralph; Biteau, Jonathan; Bulgarelli, Andrea; Cerruti, Matteo; Coppi, Paolo; D'Ammando, Filippo; De Cesare, Giovanni; Dwarkadas, Vikram V.; et al (May 2019, Bulletin of the American Astronomical Society)

   Very-high-energy gamma rays (traditionally above ∼100 GeV) are the most energetic cosmic electromagnetic radiation observed and trace the presence of charged particles of even higher energy. These gamma rays can provide unique views of the strong magnetic fields around neutron stars and the strong gravitational fields around neutron stars and black holes. At the other extreme of density, they can probe the environment of cosmic voids. This white paper briefly summarizes what can be learned over the coming decade about extreme astrophysical environments through ground-based gamma-ray observations over the 20 GeV to 300 TeV range. The majority of the material is drawn directly from Science with the Cherenkov Telescope Array, which describes the overall science case for CTA. We request that authors wishing to cite results contained in this white paper cite the original work. 

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