We discuss the first detection of anomalous microwave emission, in the Owens Valley RING5M experiment, and its interpretation in the context of the ground-based cosmic microwave background (CMB) experiments of the early 1990s. The RING5M experiment was one of the first attempts to constrain the anisotropy power on sub-horizon scales, by observing a set of7′-size fields around the North Celestial Pole (NCP). Fields were selected close to the NCP to allow continuous integration from the Owens Valley site. The experiment detected significant emission at both 14.5 GHz and 30 GHz, consistent with a mixture of CMB and a flat-spectrum foreground component, which we termedanomalous, as it could be explained neither by thermal dust emission, nor by standard models for synchrotron or free-free emission. A significant spatial correlation was found between the extracted foreground component and structure in the IRAS 100 μm maps. While microwave emission from spinning dust may be the most natural explanation for this correlation, spinning dust is unlikely to accountfor all of the anomalous emission seen in the RING5M data.
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机译:我们讨论了在Owens Valley RING5M实验中首次检测到异常微波发射的情况,以及在1990年代初的地面宇宙微波背景(CMB)实验的背景下对它的解释。 RING5M实验是通过观察北天极(NCP)周围一组7'大小的场来在亚水平尺度上限制各向异性功率的首次尝试之一。选择了靠近NCP的字段,以允许与Owens Valley站点进行持续集成。实验在14.5 GHz和30 GHz处均检测到显着发射,这与CMB和平坦频谱前景分量的混合物一致,我们称其为异常,因为它既不能用热尘埃发射来解释,也不能用同步加速器或免费的标准模型来解释。排放。在IRAS 100μm图中,提取的前景成分与结构之间存在显着的空间相关性。虽然旋转尘埃产生的微波发射可能是这种相关关系的最自然的解释,但是旋转尘埃不太可能解释RING5M数据中看到的所有异常发射。
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