We investigate the hemispherical power asymmetry in the cosmic microwave background on small angular scales. We find an anomalously high asymmetry in the multipole range = 601−2048, with a naive statistical significance of 6.5σ. However, we show that this extreme anomaly is simply a coincidence of three other effects, relativistic power modulation, edge effects from the mask applied, and inter-scale correlations. After correcting for all of these effects, the significance level drops to ∼ 1σ, i.e., there is no anomalous intrinsic asymmetry in the small angular scales. Using this null result, we derive a constraint on a potential dipolar modulation amplitude, A(k) < 0.0045 on the ∼ 10 Mpc-scale, at 95% C.L. This new constraint must be satisfied by any theoretical model attempting to explain the hemispherical asymmetry at large angular scales.The statistical properties of the anisotropies in the temperature of the cosmic microwave background (CMB) possess a wealth of cosmological information. There are many potential methods to extract this information, each of which will provide statistical information about a particular aspect of cosmology. If the universe is statistically homogeneous and isotropic, and the primordial temperature anisotropies follow a Gaussian distribution, then the angular power spectrum is sufficient to describe all the statistical properties of these anisotropies. Therefore, in such a universe, a measurement of the angular power spectrum would also provide all the cosmological information available within the CMB temperature anisotropies.The angular power spectrum of the measured CMB temperature anisotropies fits its theoretical prediction from the statistically Gaussian, homogeneous and isotropic, Λ cold dark matter (ΛCDM) standard model, remarkably well [1]. From the angular power spectrum alone, no strong evidence is found for the existence of, e.g., additional matter or radiation species, isocurvature in the primordial fluctuations, or a primordial spectrum of curvature fluctuations that is not described by a power-law. However, some anomalies have been found using other statistical observables, i.e. features in the observed sky that have a low probability of occurring in the ΛCDM model. These anomalies are predominantly seen on the largest angular scales. An overview of anomalies seen in the WMAP data is presented in [2,3]. Most of the anomalies seen in the WMAP data have been confirmed with the new Planck data [4].One such anomaly is the 'hemispherical power asymmetry': Eriksen et al [5] and Hansen et al [6] found that the angular power spectrum of the CMB temperature anisotropies, from the 1-year WMAP data, appears itself to be anisotropic. In particular it was found that, in the low multipole range = 2 − 40, the hemisphere centred at Galactic coordinates (l, b) = (237 • , −20 • ) has significantly more power than the one opposite on the sky. A possible connection between this hemispherical asymmetry and an alignment between the quadrupole and octopole was pointed out in [7]. It has als...
