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   John Carlstrom, Kevork Abazajian (September 2019, Bulletin of the American Astronomical Society)

   We describe the stage 4 cosmic microwave background ground-based experiment CMB-S4. 

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2. CMB-S4 systems engineering

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3. unWISE tomography of Planck CMB lensing

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4. Axion dark matter detection with CMB polarization

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5. A CMB Millikan experiment with cosmic axiverse strings

   https://doi.org/10.1007/JHEP07(2020)138  

   Agrawal, Prateek; Hook, Anson; Huang, Junwu (July 2020, Journal of High Energy Physics)

   A bstract We study axion strings of hyperlight axions coupled to photons. Hyperlight axions — axions lighter than Hubble at recombination — are a generic prediction of the string axiverse. These axions strings produce a distinct quantized polarization rotation of CMB photons which is $$ \mathcal{O} $$ O ( α em ). As the CMB light passes many strings, this polarization rotation converts E-modes to B-modes and adds up like a random walk. Using numerical simulations we show that the expected size of the final result is well within the reach of current and future CMB experiments through the measurement of correlations of CMB B-modes with E- and T-modes. The quantized polarization rotation angle is topological in nature and can be seen as a geometric phase. Its value depends only on the anomaly coefficient and is independent of other details such as the axion decay constant. Measurement of the anomaly coefficient by measuring this rotation will provide information about the UV theory, such as the quantization of electric charge and the value of the fundamental unit of charge. The presence of axion strings in the universe relies only on a phase transition in the early universe after inflation, after which the string network rapidly approaches an attractor scaling solution. If there are additional stable topological objects such as domain walls, axions as heavy as 10 − 15 eV would be accessible. The existence of these strings could also be probed by measuring the relative polarization rotation angle between different images in gravitationally lensed quasar systems. 

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