Alignment and signed-intensity anomalies in WMAP data

TL;DR

This paper identifies significant alignment and intensity anomalies in the WMAP cosmic microwave background data, suggesting possible violations of isotropy and indicating intrinsic statistical anisotropy in the universe.

Contribution

The study introduces a wavelet-based analysis revealing preferred directions and anomalies in the CMB, providing new insights into cosmic anisotropy beyond previous findings.

Findings

Detected two preferred planes aligned with the CMB dipole and ecliptic poles.

Identified three anomalous temperature spots in the southern galactic hemisphere.

Anomalies are scale-dependent and unlikely due to noise or foreground contamination.

Abstract

Significant alignment and signed-intensity anomalies of local features of the cosmic microwave background (CMB) are detected on the three-year WMAP data, through a decomposition of the signal with steerable wavelets on the sphere. Firstly, an alignment analysis identifies two mean preferred planes in the sky, both with normal axes close to the CMB dipole axis. The first plane is defined by the directions toward which local CMB features are anomalously aligned. A mean preferred axis is also identified in this plane, located very close to the ecliptic poles axis. The second plane is defined by the directions anomalously avoided by local CMB features. This alignment anomaly provides further insight on recent results (Wiaux et al. 2006). Secondly, a signed-intensity analysis identifies three mean preferred directions in the southern galactic hemisphere with anomalously high or low temperature of local CMB features: a cold spot essentially identified with a known cold spot (Vielva et al. 2004), a second cold spot lying very close to the southern end of the CMB dipole axis, and a hot spot lying close to the southern end of the ecliptic poles axis. In both analyses, the anomalies are observed at wavelet scales corresponding to angular sizes around 10 degress on the celestial sphere, with global significance levels around 1%. Further investigation reveals that the alignment and signed-intensity anomalies are only very partially related. Instrumental noise, foreground emissions, as well as some form of other systematics, are strongly rejected as possible origins of the detections. An explanation might still be envisaged in terms of a global violation of the isotropy of the Universe, inducing an intrinsic statistical anisotropy of the CMB.