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Dr. Bustos-Placencia, Ricardo
Research Outputs
On-sky performance of the CLASS Q-band telescope
2019, Appel, John W., Xu, Zhilei, Padilla, Ivan L., Harrington, Kathleen, Pradenas Marquez, BastiĂ¡n, Ali, Aamir, Bennett, Charles L., Brewer, Michael K., Bustos-Placencia, Ricardo, Chan, Manwei, Chuss, David T., Cleary, Joseph, Couto, Jullianna Denes, Dahal, Sumit, Denis, Kevin, DĂ¼nner, Rolando, Eimer, Joseph R., Essinger Hileman, Thomas, Fluxa, Pedro, Gothe, Dominik, Hilton, Gene C., Hubmayr, Johannes, Iuliano, Jeffrey, Karakla, John, Marriage, Tobias A., Miller, Nathan J., NĂºĂ±ez, Carolina, Parker, Lucas, Petroff, Matthew, Reintsema, Carl D., Rostem, Karwan, Stevens, Robert W., Nunes Valle, Deniz Augusto, Wang, Bingjie, Watts, Duncan J., Wollack, Edward J., Zeng, Lingzhen
The Cosmology Large Angular Scale Surveyor (CLASS) is mapping the polarization of the cosmic microwave background (CMB) at large angular scales (2 < ℓ lesssim 200) in search of a primordial gravitational wave B-mode signal down to a tensor-to-scalar ratio of r ≈ 0.01. The same data set will provide a near sample-variance-limited measurement of the optical depth to reionization. Between 2016 June and 2018 March, CLASS completed the largest ground-based Q-band CMB survey to date, covering over 31,000 square-degrees (75% of the sky), with an instantaneous array noise-equivalent temperature sensitivity of $32\,\mu {{\rm{K}}}_{\mathrm{cmb}}\sqrt{{\rm{s}}}$. We demonstrate that the detector optical loading (1.6 pW) and noise-equivalent power (19 $\mathrm{aW}\sqrt{{\rm{s}}}$) match the expected noise model dominated by photon bunching noise. We derive a 13.1 ± 0.3 K pW−1 calibration to antenna temperature based on Moon observations, which translates to an optical efficiency of 0.48 ± 0.02 and a 27 K system noise temperature. Finally, we report a Tau A flux density of 308 ± 11 Jy at 38.4 ± 0.2 GHz, consistent with the Wilkinson Microwave Anisotropy Probe Tau A time-dependent spectral flux density model.
Two-year Cosmology Large Angular Scale Surveyor (CLASS) Observations: A measurement of circular polarization at 40 GHz
2020, Padilla, Ivan L., Eimer, Joseph R., Li, Yunyang, Addison, Graeme E., Ali, Aamir, Appel, John W., Bennett, Charles L., Bustos-Placencia, Ricardo, Brewer, Michael K., Chan, Manwei, Chuss, David T., Cleary, Joseph, Couto, Jullianna Denes, Dahal, Sumit, Denis, Kevin, DĂ¼nner, Rolando, Essinger-Hileman, Thomas, FluxĂ¡, Pedro, Gothe, Dominik, Haridas, Saianeesh K., Harrington, Kathleen, Iuliano, Jeffrey, Karakla, John, Marriage, Tobias A., Miller, Nathan J., NĂºĂ±ez, Carolina, Parker, Lucas, Petroff, Matthew A., Reeves, Rodrigo, Rostem, Karwan, Stevens, Robert W., Nunes Valle, Deniz Augusto, Watts, Duncan J., Weiland, Janet L., Wollack, Edward J., Xu, Zhilei
We report measurements of circular polarization from the first two years of observation with the 40 GHz polarimeter of the Cosmology Large Angular Scale Surveyor (CLASS). CLASS is conducting a multi-frequency survey covering 75% of the sky from the Atacama Desert designed to measure the cosmic microwave background (CMB) linear E and B polarization on angular scales 1°  θ 90°, corresponding to a multipole range of 2 ℓ  200. The modulation technology enabling measurements of linear polarization at the largest angular scales from the ground, the Variable-delay Polarization Modulator, is uniquely designed to provide explicit sensitivity to circular polarization (Stokes V ). We present a first detection of circularly polarized atmospheric emission at 40 GHz that is well described by a dipole with an amplitude of 124 4 K  m when observed at an elevation of 45°, and discuss its potential impact on the recovery of linear polarization by CLASS. Filtering the atmospheric component, CLASS places a 95% confidence upper limit of 0.4 Km 2 to 13.5 Km 2 on ℓℓ C ( ) () + 1 2 ℓ p VV for 1 120  ℓ , representing an improvement by two orders of magnitude over previous CMB limits.
Two-year Cosmology Large Angular Scale Surveyor (CLASS) Observations: A First Detection of Atmospheric Circular Polarization at Q band
2020, Petroff, Matthew A., Eimer, Joseph R., Harrington, Kathleen, Ali, Aamir, Appel, John W., Bennett, Charles L., Brewer, Michael K., Bustos-Placencia, Ricardo, Chan, Manwei, Chuss, David T., Cleary, Joseph, Denes Couto, Jullianna, Dahal, Sumit, DĂ¼nner, Rolando, Essinger-Hileman, Thomas, FluxĂ¡ Rojas, Pedro, Gothe, Dominik, Iuliano, Jeffrey, Marriage, Tobias A., Miller, Nathan J., NĂºĂ±ez, Carolina, Padilla, Ivan L., Parker, Lucas, Reeves, Rodrigo, Rostem, Karwan, Nunes Valle, Deniz Augusto, Watts, Duncan J., Weiland, Janet L., Wollack, Edward J., Xu, Zhilei
The Earth’s magnetic field induces Zeeman splitting of the magnetic dipole transitions of molecular oxygen in the atmosphere, which produces polarized emission in the millimeter-wave regime. This polarized emission is primarily circularly polarized and manifests as a foreground with a dipole-shaped sky pattern for polarizationsensitive ground-based cosmic microwave background experiments, such as the Cosmology Large Angular Scale Surveyor (CLASS), which is capable of measuring large angular scale circular polarization. Using atmospheric emission theory and radiative transfer formalisms, we model the expected amplitude and spatial distribution of this signal and evaluate the model for the CLASS observing site in the Atacama Desert of northern Chile. Then, using two years of observations at 32°. 3 to 43.7 GHz from the CLASS Q-band telescope, we present a detection of this signal and compare the observed signal to that predicted by the model. We recover an angle between magnetic north and true north of −5°. 5 ± 0°. 6, which is consistent with the expectation of −5°.9 for the CLASS observing site. When comparing dipole sky patterns fit to both simulated and data-derived sky maps, the dipole directions match to within a degree, and the measured amplitudes match to within ∼20%.