Your search keyword '"Rennie, Thomas J."' showing total 17 results

1. COMAP Galactic Science I: Observations of Spinning Dust Emission at 30GHz in Dark Clouds Surrounding the {\lambda}-Orionis Hii Region

Author

Harper, Stuart E., Dickinson, Clive, Cleary, Kieran A., Hensley, Brandon S., Hoerning, Gabriel A., Paladini, Roberta, Rennie, Thomas J., Cepeda-Arroita, Roke, Dunne, Delaney A., Eriksen, Hans Kristian, Gundersen, Joshua Ott, Ihle, Havard T., Lunde, Jonas G. S., Ricci, Roberto, Stil, Jeroen, Stutzer, Nils-Ole, Taylor, A. R., and Wehus, Ingunn Kathrine

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

Anomalous Microwave Emission (AME) is a major component of Galactic emission in the frequency band 10 to 60 GHz and is commonly modelled as rapidly rotating spinning dust grains. The photodissociation region (PDR) at the boundary of the $\lambda$-Orionis Hii region has been identified by several recent analyses as one of the brightest spinning dust emitting sources in the sky. We investigate the Barnard 30 dark cloud, a dark cloud embedded within the $\lambda$-Orionis PDR. We use total-power observations of Barnard 30 from the CO Mapping Array Project (COMAP) pathfinder instrument at 26 to 34GHz with a resolution of 4.5 arcminutes alongside existing data from Planck, WISE, IRAS, ACT, and the 1.447GHz GALFACTS survey. We use aperture photometry and template fitting to measure the spectral energy distribution of Barnard 30. We find that the spinning dust is the dominant emission component in the 26 to 34GHz range at the $7 \sigma$ level ($S_{30GHz} = 2.85\pm0.43$Jy). We find no evidence that polycyclic aromatic hydrocarbons are the preferred carrier for the spinning dust emission, suggesting that the spinning dust carriers are due to a mixed population of very small grains. Finally, we find evidence for variations in spinning dust emissivity and peak frequency within Barnard 30, and that these variations are possibly driven by changes in dust grain population and the total radiation field. Confirming the origin of the variations in the spinning dust spectrum will require both future COMAP observations at 15GHz combined with spectroscopic mid-infrared data of Barnard 30., Comment: 21 pages, 13 figures. Submitted to MNRAS

Published

2024

2. The deconvolved distribution estimator: enhancing reionisation-era CO line-intensity mapping analyses with a cross-correlation analogue for one-point statistics

Author

Chung, Dongwoo T., Bangari, Ishika, Breysse, Patrick C., Ihle, Håvard T., Bond, J. Richard, Dunne, Delaney A., Padmanabhan, Hamsa, Philip, Liju, Rennie, Thomas J., and Viero, Marco P.

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

We present the deconvolved distribution estimator (DDE), an extension of the voxel intensity distribution (VID), in the context of future observations proposed as part of the CO Mapping Array Project (COMAP). The DDE exploits the fact that the observed VID is a convolution of correlated signal intensity distributions and uncorrelated noise or interloper intensity distributions. By deconvolving the individual VID of two observables away from their joint VID in a Fourier-space operation, the DDE suppresses sensitivity to interloper emission while maintaining sensitivity to correlated components. The DDE thus improves upon the VID by reducing the relative influence of uncorrelated noise and interloper biases, which is useful in the context of COMAP observations that observe different rotational transitions of CO from the same comoving volume in different observing frequency bands. Fisher forecasts suggest that the theoretical sensitivity in the DDE allows significant improvements in constraining power compared to either the cross power spectrum or the individual VID data, and matches the constraining power of the combination of all other one- and two-point summary statistics. Future work should further investigate the covariance and model-dependent behaviour of this novel one-point cross-correlation statistic., Comment: 11 pages + acknowledgements/bibliography/appendix (12 pages total); 10 figures, 2 tables; v3 reflects the version accepted for publication in MNRAS

Published

2022

3. COMAP Early Science: VII. Prospects for CO Intensity Mapping at Reionization

Author

Breysse, Patrick C., Chung, Dongwoo T., Cleary, Kieran A., Ihle, Håvard T., Padmanabhan, Hamsa, Silva, Marta B., Bond, J. Richard, Borowska, Jowita, Catha, Morgan, Church, Sarah E., Dunne, Delaney A., Eriksen, Hans Kristian, Foss, Marie Kristine, Gaier, Todd, Gundersen, Joshua Ott, Harris, Andrew I., Hobbs, Richard, Keating, Laura, Lamb, James W., Lawrence, Charles R., Lunde, Jonas G. S., Murray, Norman, Pearson, Timothy J., Philip, Liju, Rasmussen, Maren, Readhead, Anthony C. S., Rennie, Thomas J., Stutzer, Nils-Ole, Viero, Marco P., Watts, Duncan J., Wehus, Ingunn Katherine, and Woody, David P.

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

We introduce COMAP-EoR, the next generation of the Carbon Monoxide Mapping Array Project aimed at extending CO intensity mapping to the Epoch of Reionization. COMAP-EoR supplements the existing 30 GHz COMAP Pathfinder with two additional 30 GHz instruments and a new 16 GHz receiver. This combination of frequencies will be able to simultaneously map CO(1--0) and CO(2--1) at reionization redshifts ($z\sim5-8$) in addition to providing a significant boost to the $z\sim3$ sensitivity of the Pathfinder. We examine a set of existing models of the EoR CO signal, and find power spectra spanning several orders of magnitude, highlighting our extreme ignorance about this period of cosmic history and the value of the COMAP-EoR measurement. We carry out the most detailed forecast to date of an intensity mapping cross-correlation, and find that five out of the six models we consider yield signal to noise ratios (S/N) $\gtrsim20$ for COMAP-EoR, with the brightest reaching a S/N above 400. We show that, for these models, COMAP-EoR can make a detailed measurement of the cosmic molecular gas history from $z\sim2-8$, as well as probe the population of faint, star-forming galaxies predicted by these models to be undetectable by traditional surveys. We show that, for the single model that does not predict numerous faint emitters, a COMAP-EoR-type measurement is required to rule out their existence. We briefly explore prospects for a third-generation Expanded Reionization Array (COMAP-ERA) capable of detecting the faintest models and characterizing the brightest signals in extreme detail., Comment: Paper 7 of 7 in series. 19 pages, 10 figures, to be submitted to ApJ

Published

2021

4. COMAP Early Science: V. Constraints and Forecasts at $z \sim 3$

Author

Chung, Dongwoo T., Breysse, Patrick C., Cleary, Kieran A., Ihle, Håvard T., Padmanabhan, Hamsa, Silva, Marta B., Bond, J. Richard, Borowska, Jowita, Catha, Morgan, Church, Sarah E., Dunne, Delaney A., Eriksen, Hans Kristian, Foss, Marie Kristine, Gaier, Todd, Gundersen, Joshua Ott, Harper, Stuart E., Harris, Andrew I., Hensley, Brandon, Hobbs, Richard, Keating, Laura C., Kim, Junhan, Lamb, James W., Lawrence, Charles R., Lunde, Jonas Gahr Sturtzel, Murray, Norman, Pearson, Timothy J., Philip, Liju, Rasmussen, Maren, Readhead, Anthony C. S., Rennie, Thomas J., Stutzer, Nils-Ole, Uzgil, Bade D., Viero, Marco P., Watts, Duncan J., Wechsler, Risa H., Wehus, Ingunn Kathrine, and Woody, David P.

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

We present the current state of models for the $z\sim3$ carbon monoxide (CO) line-intensity signal targeted by the CO Mapping Array Project (COMAP) Pathfinder in the context of its early science results. Our fiducial model, relating dark matter halo properties to CO luminosities, informs parameter priors with empirical models of the galaxy-halo connection and previous CO(1-0) observations. The Pathfinder early science data spanning wavenumbers $k=0.051$-$0.62\,$Mpc$^{-1}$ represent the first direct 3D constraint on the clustering component of the CO(1-0) power spectrum. Our 95% upper limit on the redshift-space clustering amplitude $A_{\rm clust}\lesssim70\,\mu$K$^2$ greatly improves on the indirect upper limit of $420\,\mu$K$^2$ reported from the CO Power Spectrum Survey (COPSS) measurement at $k\sim1\,$Mpc$^{-1}$. The COMAP limit excludes a subset of models from previous literature, and constrains interpretation of the COPSS results, demonstrating the complementary nature of COMAP and interferometric CO surveys. Using line bias expectations from our priors, we also constrain the squared mean line intensity-bias product, $\langle{Tb}\rangle^2\lesssim50\,\mu$K$^2$, and the cosmic molecular gas density, $\rho_\text{H2}<2.5\times10^8\,M_\odot\,$Mpc$^{-3}$ (95% upper limits). Based on early instrument performance and our current CO signal estimates, we forecast that the five-year Pathfinder campaign will detect the CO power spectrum with overall signal-to-noise of 9-17. Between then and now, we also expect to detect the CO-galaxy cross-spectrum using overlapping galaxy survey data, enabling enhanced inferences of cosmic star-formation and galaxy-evolution history., Comment: Paper 5 of 7 in series. 17 pages + appendix and bibliography (30 pages total); 15 figures, 6 tables; accepted for publication in ApJ; v3 reflects the accepted version with minor changes and additions to text

Published

2021

5. COMAP Early Science: VI. A First Look at the COMAP Galactic Plane Survey

Author

Rennie, Thomas J., Harper, Stuart E., Dickinson, Clive, Philip, Liju, Cleary, Kieran A., Bond, Richard J., Borowska, Jowita, Breysse, Patrick C., Catha, Morgan, Cepeda-Arroita, Roke, Chung, Dongwoo T., Church, Sarah E., Dunne, Delaney A., Eriksen, Hans Kristian, Foss, Marie Kristine, Gaier, Todd, Gunderson, Joshua Ott, Harris, Andrew I., Hensley, Brandon, Hobbs, Richard, Ihle, Håvard T., Lamb, James W., Lawrence, Charles R., Lunde, Jonas G. S., Paladini, Roberta, Pearson, Timothy J., Rasmussen, Maren, Readhead, Anthony C. S., Stutzer, Nils-Ole, Watts, Duncan J., Wehus, Ingunn Kathrine, and Woody, David P.

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

We present early results from the COMAP Galactic Plane Survey conducted between June 2019 and April 2021, spanning $20^\circ<\ell<40^\circ$ in Galactic longitude and $|b|<1.\!\!^{\circ}5$ in Galactic latitude with an angular resolution of $4.5^{\prime}$. The full survey will span $\ell \sim 20^{\circ}$- $220^{\circ}$ and will be the first large-scale radio continuum survey at $30$ GHz with sub-degree resolution. We present initial results from the first part of the survey, including diffuse emission and spectral energy distributions (SEDs) of HII regions and supernova remnants. Using low and high frequency surveys to constrain free-free and thermal dust emission contributions, we find evidence of excess flux density at $30\,$GHz in six regions that we interpret as anomalous microwave emission. Furthermore we model UCHII contributions using data from the $5\,$GHz CORNISH catalogue and reject this as the cause of the $30\,$GHz excess. Six known supernova remnants (SNR) are detected at $30\,$GHz, and we measure spectral indices consistent with the literature or show evidence of steepening. The flux density of the SNR W44 at $30\,$GHz is consistent with a power-law extrapolation from lower frequencies with no indication of spectral steepening in contrast with recent results from the Sardinia Radio Telescope. We also extract five hydrogen radio recombination lines to map the warm ionized gas, which can be used to estimate electron temperatures or to constrain continuum free-free emission. The full COMAP Galactic plane survey, to be released in 2023/2024, will be an invaluable resource for Galactic astrophysics., Comment: Paper 6 of 7 in series. 28 pages, 10 figures, submitted to ApJ

Published

2021

6. COMAP Early Science: IV. Power Spectrum Methodology and Results

Author

Ihle, Håvard T., Borowska, Jowita, Cleary, Kieran A., Eriksen, Hans Kristian, Foss, Marie K., Harper, Stuart E., Kim, Junhan, Lunde, Jonas G. S., Philip, Liju, Rasmussen, Maren, Stutzer, Nils-Ole, Uzgil, Bade D., Watts, Duncan J., Wehus, Ingunn Kathrine, Bond, J. Richard, Breysse, Patrick C., Catha, Morgan, Church, Sarah E., Chung, Dongwoo T., Dickinson, Clive, Dunne, Delaney A., Gaier, Todd, Gundersen, Joshua Ott, Harris, Andrew I., Hobbs, Richard, Lamb, James W., Lawrence, Charles R., Murray, Norman, Readhead, Anthony C. S., Padmanabhan, Hamsa, Pearson, Timothy J., Rennie, Thomas J., and Woody, David P.

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

We present the power spectrum methodology used for the first-season COMAP analysis, and assess the quality of the current data set. The main results are derived through the Feed-feed Pseudo-Cross-Spectrum (FPXS) method, which is a robust estimator with respect to both noise modeling errors and experimental systematics. We use effective transfer functions to take into account the effects of instrumental beam smoothing and various filter operations applied during the low-level data processing. The power spectra estimated in this way have allowed us to identify a systematic error associated with one of our two scanning strategies, believed to be due to residual ground or atmospheric contamination. We omit these data from our analysis and no longer use this scanning technique for observations. We present the power spectra from our first season of observing and demonstrate that the uncertainties are integrating as expected for uncorrelated noise, with any residual systematics suppressed to a level below the noise. Using the FPXS method, and combining data on scales $k=0.051-0.62 \,\mathrm{Mpc}^{-1}$ we estimate $P_\mathrm{CO}(k) = -2.7 \pm 1.7 \times 10^4\mu\textrm{K}^2\mathrm{Mpc}^3$, the first direct 3D constraint on the clustering component of the CO(1-0) power spectrum in the literature., Comment: Paper 4 of 7 in series. 18 pages, 11 figures, as accepted in ApJ

Published

2021

7. COMAP Early Science: III. CO Data Processing

Author

Foss, Marie K., Ihle, Håvard T., Borowska, Jowita, Cleary, Kieran A., Eriksen, Hans Kristian, Harper, Stuart E., Kim, Junhan, Lamb, James W., Lunde, Jonas G. S., Philip, Liju, Rasmussen, Maren, Stutzer, Nils-Ole, Uzgil, Bade D., Watts, Duncan J., Wehus, Ingunn K., Woody, David P., Bond, J. Richard, Breysse, Patrick C., Catha, Morgan, Church, Sarah E., Chung, Dongwoo T., Dickinson, Clive, Dunne, Delaney A., Gaier, Todd, Gundersen, Joshua Ott, Harris, Andrew I., Hobbs, Richard, Lawrence, Charles R., Murray, Norman, Readhead, Anthony C. S., Padmanabhan, Hamsa, Pearson, Timothy J., and Rennie, Thomas J.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

We describe the first season COMAP analysis pipeline that converts raw detector readouts to calibrated sky maps. This pipeline implements four main steps: gain calibration, filtering, data selection, and map-making. Absolute gain calibration relies on a combination of instrumental and astrophysical sources, while relative gain calibration exploits real-time total-power variations. High efficiency filtering is achieved through spectroscopic common-mode rejection within and across receivers, resulting in nearly uncorrelated white noise within single-frequency channels. Consequently, near-optimal but biased maps are produced by binning the filtered time stream into pixelized maps; the corresponding signal bias transfer function is estimated through simulations. Data selection is performed automatically through a series of goodness-of-fit statistics, including $\chi^2$ and multi-scale correlation tests. Applying this pipeline to the first-season COMAP data, we produce a dataset with very low levels of correlated noise. We find that one of our two scanning strategies (the Lissajous type) is sensitive to residual instrumental systematics. As a result, we no longer use this type of scan and exclude data taken this way from our Season 1 power spectrum estimates. We perform a careful analysis of our data processing and observing efficiencies and take account of planned improvements to estimate our future performance. Power spectrum results derived from the first-season COMAP maps are presented and discussed in companion papers., Comment: Paper 3 of 7 in series. 26 pages, 23 figures, submitted to ApJ

Published

2021

8. COMAP Early Science: I. Overview

Author

Cleary, Kieran A., Borowska, Jowita, Breysse, Patrick C., Catha, Morgan, Chung, Dongwoo T., Church, Sarah E., Dickinson, Clive, Eriksen, Hans Kristian, Foss, Marie Kristine, Gundersen, Joshua Ott, Harper, Stuart E., Harris, Andrew I., Hobbs, Richard, Håvard, Ihle, T., Kim, Junhan, Kocz, Jonathon, Lamb, James W., Lunde, Jonas G. S., Padmanabhan, Hamsa, Pearson, Timothy J., Philip, Liju, Powell, Travis W., Rasmussen, Maren, Readhead, Anthony C. S., Rennie, Thomas J., Silva, Marta B., Stutzer, Nils-Ole, Uzgil, Bade D., Watts, Duncan J., Wehus, Ingunn Kathrine, Woody, David P., Basoalto, Lilian, Bond, J. Richard, Dunne, Delaney A., Gaier, Todd, Hensley, Brandon, Keating, Laura C., Lawrence, Charles R., Murray, Norman, Reeves, Rodrigo, Viero, Marco P., and Wechsler, Risa

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

The CO Mapping Array Project (COMAP) aims to use line intensity mapping of carbon monoxide (CO) to trace the distribution and global properties of galaxies over cosmic time, back to the Epoch of Reionization (EoR). To validate the technologies and techniques needed for this goal, a Pathfinder instrument has been constructed and fielded. Sensitive to CO(1-0) emission from $z=2.4$-$3.4$ and a fainter contribution from CO(2-1) at $z=6$-8, the Pathfinder is surveying $12$ deg$^2$ in a 5-year observing campaign to detect the CO signal from $z\sim3$. Using data from the first 13 months of observing, we estimate $P_\mathrm{CO}(k) = -2.7 \pm 1.7 \times 10^4\mu\mathrm{K}^2 \mathrm{Mpc}^3$ on scales $k=0.051-0.62 \mathrm{Mpc}^{-1}$ - the first direct 3D constraint on the clustering component of the CO(1-0) power spectrum. Based on these observations alone, we obtain a constraint on the amplitude of the clustering component (the squared mean CO line temperature-bias product) of $\langle Tb\rangle^2<49$ $\mu$K$^2$ - nearly an order-of-magnitude improvement on the previous best measurement. These constraints allow us to rule out two models from the literature. We forecast a detection of the power spectrum after 5 years with signal-to-noise ratio (S/N) 9-17. Cross-correlation with an overlapping galaxy survey will yield a detection of the CO-galaxy power spectrum with S/N of 19. We are also conducting a 30 GHz survey of the Galactic plane and present a preliminary map. Looking to the future of COMAP, we examine the prospects for future phases of the experiment to detect and characterize the CO signal from the EoR., Comment: Paper 1 of 7 in series. 18 pages, 16 figures, submitted to ApJ

Published

2021

9. COMAP Early Science: II. Pathfinder Instrument

Author

Lamb, James W., Cleary, Kieran A., Woody, David P., Catha, Morgan, Chung, Dongwoo T., Gundersen, Joshua Ott, Harper, Stuart E., Harris, Andrew I., Hobbs, Richard, Ihle, Håvard T., Kocz, Jonathon, Pearson, Timothy J., Philip, Liju, Powell, Travis W., Basoalto, Lilian, Bond, J. Richard, Borowska, Jowita, Breysse, Patrick C., Church, Sarah E., Dickinson, Clive, Dunne, Delaney A., Eriksen, Hans Kristian, Foss, Marie Kristine, Gaier, Todd, Kim, Junhan, Lawrence, Charles R., Lunde, Jonas G. S., Padmanabhan, Hamsa, Rasmussen, Maren, Readhead, Anthony C. S., Reeves, Rodrigo, Rennie, Thomas J., Stutzer, Nils-Ole, Watts, Duncan J., and Wehus, Ingunn Kathrine

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

Line intensity mapping (LIM) is a new technique for tracing the global properties of galaxies over cosmic time. Detection of the very faint signals from redshifted carbon monoxide (CO), a tracer of star formation, pushes the limits of what is feasible with a total-power instrument. The CO Mapping Project (COMAP) Pathfinder is a first-generation instrument aiming to prove the concept and develop the technology for future experiments, as well as delivering early science products. With 19 receiver channels in a hexagonal focal plane arrangement on a 10.4 m antenna, and an instantaneous 26-34 GHz frequency range with 2 MHz resolution, it is ideally suited to measuring CO($J$=1-0) from $z\sim3$. In this paper we discuss strategies for designing and building the Pathfinder and the challenges that were encountered. The design of the instrument prioritized LIM requirements over those of ancillary science. After a couple of years of operation, the instrument is well understood, and the first year of data is already yielding useful science results. Experience with this Pathfinder will drive the design of the next generations of experiments., Comment: Paper 2 of 7 in series. 27 pages, 28 figures, submitted to ApJ

Published

2021

10. The deconvolved distribution estimator: enhancing reionization-era CO line-intensity mapping analyses with a cross-correlation analogue for one-point statistics

Author

Chung, Dongwoo T., Bangari, Ishika, Breysse, Patrick C., Ihle, Håvard T., Bond, J. Richard, Dunne, Delaney A., Padmanabhan, Hamsa, Philip, Liju, Rennie, Thomas J., and Viero, Marco P.

Subjects

Cosmology and Nongalactic Astrophysics (astro-ph.CO), Space and Planetary Science, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We present the deconvolved distribution estimator (DDE), an extension of the voxel intensity distribution (VID), in the context of future observations proposed as part of the CO Mapping Array Project (COMAP). The DDE exploits the fact that the observed VID is a convolution of correlated signal intensity distributions and uncorrelated noise or interloper intensity distributions. By deconvolving the individual VID of two observables away from their joint VID in a Fourier-space operation, the DDE suppresses sensitivity to interloper emission while maintaining sensitivity to correlated components. The DDE thus improves upon the VID by reducing the relative influence of uncorrelated noise and interloper biases, which is useful in the context of COMAP observations that observe different rotational transitions of CO from the same comoving volume in different observing frequency bands. Fisher forecasts suggest that the theoretical sensitivity in the DDE allows significant improvements in constraining power compared to either the cross power spectrum or the individual VID data, and matches the constraining power of the combination of all other one- and two-point summary statistics. Future work should further investigate the covariance and model-dependent behaviour of this novel one-point cross-correlation statistic., Comment: 11 pages + acknowledgements/bibliography/appendix (12 pages total); 10 figures, 2 tables; v3 reflects the version accepted for publication in MNRAS

Published

2023

11. COMAP Early Science. VII. Prospects for CO Intensity Mapping at Reionization

Author

Breysse, Patrick C., primary, Chung, Dongwoo T., additional, Cleary, Kieran A., additional, Ihle, Håvard T., additional, Padmanabhan, Hamsa, additional, Silva, Marta B., additional, Bond, J. Richard, additional, Borowska, Jowita, additional, Catha, Morgan, additional, Church, Sarah E., additional, Dunne, Delaney A., additional, Eriksen, Hans Kristian, additional, Foss, Marie Kristine, additional, Gaier, Todd, additional, Gundersen, Joshua Ott, additional, Harris, Andrew I., additional, Hobbs, Richard, additional, Keating, Laura, additional, Lamb, James W., additional, Lawrence, Charles R., additional, Lunde, Jonas G. S., additional, Murray, Norman, additional, Pearson, Timothy J., additional, Philip, Liju, additional, Rasmussen, Maren, additional, Readhead, Anthony C. S., additional, Rennie, Thomas J., additional, Stutzer, Nils-Ole, additional, Viero, Marco P., additional, Watts, Duncan J., additional, Wehus, Ingunn Kathrine, additional, and Woody, David P., additional

Published

2022

12. COMAP Early Science. II. Pathfinder Instrument

Author

Lamb, James W., primary, Cleary, Kieran A., additional, Woody, David P., additional, Catha, Morgan, additional, Chung, Dongwoo T., additional, Gundersen, Joshua Ott, additional, Harper, Stuart E., additional, Harris, Andrew I., additional, Hobbs, Richard, additional, Ihle, Håvard T., additional, Kocz, Jonathon, additional, Pearson, Timothy J., additional, Philip, Liju, additional, Powell, Travis W., additional, Basoalto, Lilian, additional, Bond, J. Richard, additional, Borowska, Jowita, additional, Breysse, Patrick C., additional, Church, Sarah E., additional, Dickinson, Clive, additional, Dunne, Delaney A., additional, Eriksen, Hans Kristian, additional, Foss, Marie Kristine, additional, Gaier, Todd, additional, Kim, Junhan, additional, Lawrence, Charles R., additional, Lunde, Jonas G. S., additional, Padmanabhan, Hamsa, additional, Rasmussen, Maren, additional, Readhead, Anthony C. S., additional, Reeves, Rodrigo, additional, Rennie, Thomas J., additional, Stutzer, Nils-Ole, additional, Viero, Marco P., additional, Watts, Duncan J., additional, and Wehus, Ingunn Kathrine, additional

Published

2022

13. COMAP Early Science. V. Constraints and Forecasts at z ∼ 3

Author

Chung, Dongwoo T., primary, Breysse, Patrick C., additional, Cleary, Kieran A., additional, Ihle, Håvard T., additional, Padmanabhan, Hamsa, additional, Silva, Marta B., additional, Richard Bond, J., additional, Borowska, Jowita, additional, Catha, Morgan, additional, Church, Sarah E., additional, Dunne, Delaney A., additional, Kristian Eriksen, Hans, additional, Kristine Foss, Marie, additional, Gaier, Todd, additional, Ott Gundersen, Joshua, additional, Harper, Stuart E., additional, Harris, Andrew I., additional, Hensley, Brandon, additional, Hobbs, Richard, additional, Keating, Laura C., additional, Kim, Junhan, additional, Lamb, James W., additional, Lawrence, Charles R., additional, Gahr Sturtzel Lunde, Jonas, additional, Murray, Norman, additional, Pearson, Timothy J., additional, Philip, Liju, additional, Rasmussen, Maren, additional, Readhead, Anthony C. S., additional, Rennie, Thomas J., additional, Stutzer, Nils-Ole, additional, Uzgil, Bade D., additional, Viero, Marco P., additional, Watts, Duncan J., additional, Wechsler, Risa H., additional, Kathrine Wehus, Ingunn, additional, and Woody, David P., additional

Published

2022

14. COMAP Early Science. I. Overview

Author

Cleary, Kieran A., primary, Borowska, Jowita, additional, Breysse, Patrick C., additional, Catha, Morgan, additional, Chung, Dongwoo T., additional, Church, Sarah E., additional, Dickinson, Clive, additional, Eriksen, Hans Kristian, additional, Foss, Marie Kristine, additional, Gundersen, Joshua Ott, additional, Harper, Stuart E., additional, Harris, Andrew I., additional, Hobbs, Richard, additional, Ihle, Håvard T., additional, Kim, Junhan, additional, Kocz, Jonathon, additional, Lamb, James W., additional, Lunde, Jonas G. S., additional, Padmanabhan, Hamsa, additional, Pearson, Timothy J., additional, Philip, Liju, additional, Powell, Travis W., additional, Rasmussen, Maren, additional, Readhead, Anthony C. S., additional, Rennie, Thomas J., additional, Silva, Marta B., additional, Stutzer, Nils-Ole, additional, Uzgil, Bade D., additional, Watts, Duncan J., additional, Wehus, Ingunn Kathrine, additional, Woody, David P., additional, Basoalto, Lilian, additional, Bond, J. Richard, additional, Dunne, Delaney A., additional, Gaier, Todd, additional, Hensley, Brandon, additional, Keating, Laura C., additional, Lawrence, Charles R., additional, Murray, Norman, additional, Paladini, Roberta, additional, Reeves, Rodrigo, additional, Viero, Marco P., additional, and Wechsler, Risa H., additional

Published

2022

15. COMAP Early Science. IV. Power Spectrum Methodology and Results

Author

Ihle, Håvard T., primary, Borowska, Jowita, additional, Cleary, Kieran A., additional, Eriksen, Hans Kristian, additional, Foss, Marie K., additional, Harper, Stuart E., additional, Kim, Junhan, additional, Lunde, Jonas G. S., additional, Philip, Liju, additional, Rasmussen, Maren, additional, Stutzer, Nils-Ole, additional, Uzgil, Bade D., additional, Watts, Duncan J., additional, Wehus, Ingunn Kathrine, additional, Bond, J. Richard, additional, Breysse, Patrick C., additional, Catha, Morgan, additional, Church, Sarah E., additional, Chung, Dongwoo T., additional, Dickinson, Clive, additional, Dunne, Delaney A., additional, Gaier, Todd, additional, Gundersen, Joshua Ott, additional, Harris, Andrew I., additional, Hobbs, Richard, additional, Lamb, James W., additional, Lawrence, Charles R., additional, Murray, Norman, additional, Readhead, Anthony C. S., additional, Padmanabhan, Hamsa, additional, Pearson, Timothy J., additional, Rennie, Thomas J., additional, and Woody, David P., additional

Published

2022

16. COMAP Early Science. III. CO Data Processing

Author

Foss, Marie K., primary, Ihle, Håvard T., additional, Borowska, Jowita, additional, Cleary, Kieran A., additional, Eriksen, Hans Kristian, additional, Harper, Stuart E., additional, Kim, Junhan, additional, Lamb, James W., additional, Lunde, Jonas G. S., additional, Philip, Liju, additional, Rasmussen, Maren, additional, Stutzer, Nils-Ole, additional, Uzgil, Bade D., additional, Watts, Duncan J., additional, Wehus, Ingunn K., additional, Woody, David P., additional, Bond, J. Richard, additional, Breysse, Patrick C., additional, Catha, Morgan, additional, Church, Sarah E., additional, Chung, Dongwoo T., additional, Dickinson, Clive, additional, Dunne, Delaney A., additional, Gaier, Todd, additional, Gundersen, Joshua Ott, additional, Harris, Andrew I., additional, Hobbs, Richard, additional, Lawrence, Charles R., additional, Murray, Norman, additional, Readhead, Anthony C. S., additional, Padmanabhan, Hamsa, additional, Pearson, Timothy J., additional, and Rennie, Thomas J., additional

Published

2022

17. COMAP Early Science. VI. A First Look at the COMAP Galactic Plane Survey

Author

Rennie, Thomas J., primary, Harper, Stuart E., additional, Dickinson, Clive, additional, Philip, Liju, additional, Cleary, Kieran A., additional, Bond, Richard J., additional, Borowska, Jowita, additional, Breysse, Patrick C., additional, Catha, Morgan, additional, Cepeda-Arroita, Roke, additional, Chung, Dongwoo T., additional, Church, Sarah E., additional, Dunne, Delaney A., additional, Eriksen, Hans Kristian, additional, Foss, Marie Kristine, additional, Gaier, Todd, additional, Gundersen, Joshua Ott, additional, Harris, Andrew I., additional, Hensley, Brandon, additional, Hobbs, Richard, additional, Ihle, Håvard T., additional, Lamb, James W., additional, Lawrence, Charles R., additional, Lunde, Jonas G. S., additional, Paladini, Roberta, additional, Pearson, Timothy J., additional, Rasmussen, Maren, additional, Readhead, Anthony C. S., additional, Stutzer, Nils-Ole, additional, Watts, Duncan J., additional, Wehus, Ingunn Kathrine, additional, and Woody, David P., additional

Published

2022