HI Intensity Mapping / Tianlai
O. Perdereau, R. Ansari, A. Stebbins, P. T. Timbie, X. Chen, F.Wu, J. Li, J. P. Marriner, G. S. Tucker, Y. Cong, S. Das, Y. Li, Y. Liu, C. Magneville, J. B. Peterson, A. Phan, L. Robinthal, S. Sun, Y. Wang, Y. Wu, Y. Xu, K. Yu, Z. Yu, J. Zhang, J. Zhang, and S. Zuo. “The Tianlai Dish Array Low-z Surveys Forecasts. Mon. Not. R. Astron. Soc., Oct. 2022. http://10.1093/mnras/stac2832
F. Wu, J. Li, S. Zuo, X. Chen, S. Das, J. P. Marriner, T. M. Oxholm, A. Phan, A. Stebbins, P. T. Timbie, R. Ansari, J.-E. Campagne, Z. Chen, Y. Cong, Q. Huang, Y. Li, T. Liu, Y. Liu, C. Niu, C. Osinga, O. Perdereau, J. B. Peterson, H. Shi, G. Siebert, S. Sun, H. Tian, G. S.Tucker, Q. Wang, R. Wang, Y. Wang, Y. Wu, Y. Xu, K. Yu, Z. Yu, J. Zhang, J. Zhang, and J. Zhu. “The Tianlai Dish Pathfinder Array: design, operation and performance of a prototype transit radio interferometer,” Monthly Notices of the Royal Astronomical Society, 506, 3, 2021. 2011.05946
Phan, A., Das, S., Stebbins, A., Timbie, P., et. al. “AlgoSCR: an algorithm for solar contamination removal from radio interferometric data,” submitted to Monthly Notices of the Royal Astronomical Society, arXiv:2105.07126 (2021).
Das, S., et al. “Progress in the Construction and Testing of the Tianlai Radio Interferometers,” Millimeter, Submillimeter, and Far-Infrared Detectors and Instrumentation for Astronomy IX. Vol. 10708. International Society for Optics and Photonics, 2018. 1806.04698
Anderson, C.J. et al., “Lack of clustering in low-redshift 21-cm intensity maps cross-correlated with 2dF galaxy densities,” Monthly Notices of the Royal Astronomical Society 476, 3382-3392, 2018. 1710.00424
Line Intensity Mapping / EXCLAIM
Anthony R. Pullen, Patrick C. Breysse, Trevor Oxholm, Eric R. Switzer, Christopher J. Anderson, Emily Barrentine, Alberto D. Bolatto, Giuseppe Cataldo, Thomas Essinger-Hileman, Abhishek Maniyar, Thomas Stevenson, Rachel S. Somerville, Carrie Volpert, Edward Wollack, Shengqi Yang, L. Y. Aaron Yung, Zilu Zhou, “Extragalactic Science with the Experiment for Cryogenic Large-aperture Intensity Mapping”, arXiv:2209.02497 [astro-ph.CO], submitted 6 Sep 2022.
Siebert, G.L. “Modeling the Optical System of NASA’s EXCLAIM Mission,” Proceedings of the Wisconsin Space Conference, 2021.
Oxholm, T.M. “A beginner’s guide to line intensity mapping power spectra,” Proceedings of the Wisconsin Space Conference, 2021.
Oxholm, T.M., and Switzer, E.R. “Intensity mapping without cosmic variance,” Physical Review D 104, 083501, 2021. 2107.02111
Essinger-Hileman, T., Oxholm, T.M., Siebert, G.L., et. al. “Optical design of the experiment for cryogenic large-aperture intensity mapping (EXCLAIM),” Millimeter, Submillimeter, and Far-Infrared Detectors and Instrumentation for Astronomy X. Vol. 11453. International Society for Optics and Photonics, 2020. 2012.10481
P. A. R. Ade, C. J. Anderson, E. M. Barrentine, N. G. Bellis, A. D. Bolatto, P. C. Breysse, B. T. Bulcha, G. Cataldo, J. A. Connors, P. W. Cursey, N. Ehsan, H. C. Grant, T. M. Essinger-Hileman, L. A. Hess, M. O. Kimball, A. J. Kogut, A. D. Lamb, L. N. Lowe, P. D. Mauskopf, J. McMahon, M. Mirzaei, S. H. Moseley, J. W. Mugge-Durum, O. Noroozian, U. Pen, A. R. Pullen, S. Rodriguez, P. J. Shirron, R. S. Somerville, T. R. Stevenson, E. R. Switzer, C. Tucker, E. Visbal, C. G. Volpert, E. J. Wollack, S. Yang, “The Experiment for Cryogenic Large-aperture Intensity Mapping (EXCLAIM)”, arXiv:1912.07118 [astro-ph.IM], submitted on 15 Dec 2019.
Detector Development
Oxholm, T.M., EXCLAIM detector group. “Operational Optimization to Maximize Dynamic Range in EXCLAIM Microwave Kinetic Inductance Detectors.” Accepted by J Low Temp Phys (2021)
Lowitz, A.E., Brown, A.D., Mikula, V. et al. “Design, Fabrication, and Testing of a TiN/Ti/TiN Trilayer KID Array for 3 mm CMB Observations” Design, Fabrication, and Testing of a TiN/Ti/TiN Trilayer KID Array for 3 mm CMB ObservationsLowitz2016_Article_DesignFabricationAndTestingOfA. J Low Temp Phys 184, 627–633 (2016).
Cosmic Microwave Background
Das, S., and Phan, A.. “Cosmic Microwave Background Anisotropy numerical solution (CMBAns). Part I. An introduction to Cl calculation.” Journal of Cosmology and Astroparticle Physics 2020.05 (2020): 006. 1910.00725
J.-Ch. Hamilton, L. Mousset, E.S. Battistelli, M.-A. Bigot-Sazy, P. Chanial, R. Charlassier, G. D’Alessandro, P. de Bernardis, M. De Petris, M.M. Gamboa Lerena, L. Grandsire1S. Landau5S. Marnieros6S. Masi2,3A. Mennella7,8C. O’Sullivan9M. Piat1G. Riccardi7C. Sc ́occola4M. Stolpovskiy1A. Tartari10S.A. Torchinsky1,11F. Voisin1M. Zannoni12,8P. Ade13J.G. Alberro14A. Almela15G. Amico2L.H. Arnaldi16D. Auguste6J. Aumont17S. Azzoni18S. Banfi12,8B. B ́elier19A. Ba`u12,8D. Bennett9L. Berg ́e6J.-Ph. Bernard17M. Bersanelli7,8J. Bonaparte20J. Bonis6E. Bunn21D. Burke9D. Buzi2F. Cavaliere7,8C. Chapron1A.C. Cobos Cerutti15F. Columbro2,3A. Coppolecchia2,3G. De Gasperis22M. De Leo2,23S. Dheilly1C. Duca15L. Dumoulin6A. Etchegoyen15A. Fasciszewski20L.P. Ferreyro15D. Fracchia15C. Franceschet7,8K.M. Ganga1B. Garc ́ıa15M.E. Garc ́ıa Redondo15M. Gaspard6D. Gayer9M. Gervasi12,8M. Giard17V. Gilles2Y. Giraud-Heraud1M. G ́omezBerisso16M. Gonz ́alez16M. Gradziel9M.R. Hampel15D. Harari16S. Henrot-Versill ́e6F. Incardona7,8E. Jules6J. Kaplan1C. Kristukat24L. Lamagna2,3S. Loucatos1,25T. Louis6B. Maffei26W. Marty17A. Mattei3A. May27M. McCulloch27L. Mele2D. Melo15L. Montier17L.M. Mundo14J.A. Murphy9J.D. Murphy9F. Nati12,8E. Olivieri6C. Oriol6A. Paiella2,3F. Pajot17A. Passerini12,8H. Pastoriza16A. Pelosi3C. Perbost1M. Perciballi3F. Pezzotta7,8F. Piacentini2,3L. Piccirillo27G. Pisano13M. Platino15G. Polenta28D. Prˆele1R. Puddu29D. Rambaud17P. Ringegni14G.E. Romero30E. Rasztocky30J.M. Salum15A. Schillaci31S. Scully9S. Spinelli12G. Stankowiak1A.D. Supanitsky15J.-P. Thermeau1P. Timbie32M. Tomasi7,8C. Tucker13G. Tucker, D. Vigan`o, N. Vittorio, F. Wicek, M. Wright, and A. Zullo, “QUBIC I: Overview and ScienceProgram,” submitted to JCAP. 2011.02213