A study of the link between cosmic rays and clouds with a cloud chamber at the CERN PS

TL;DR

This paper discusses the CLOUD project at CERN, which aims to experimentally investigate the potential link between cosmic rays and cloud formation, to better understand climate variability and the influence of solar activity.

Contribution

It introduces a novel laboratory experiment using a cloud chamber and particle beam at CERN to test the causal connection between cosmic rays and cloud formation.

Findings

Experimental setup for controlled cosmic ray and cloud interaction studies

Potential identification of microphysical mechanisms linking cosmic rays to clouds

Framework for integrating laboratory results into climate models

Abstract

Recent satellite data have revealed a surprising correlation between galactic cosmic ray (GCR) intensity and the fraction of the Earth covered by clouds. If this correlation were to be established by a causal mechanism, it could provide a crucial step in understanding the long-sought mechanism connecting solar and climate variability. The Earth's climate seems to be remarkably sensitive to solar activity, but variations of the Sun's electromagnetic radiation appear to be too small to account for the observed climate variability. However, since the GCR intensity is strongly modulated by the solar wind, a GCR-cloud link may provide a sufficient amplifying mechanism. Moreover if this connection were to be confirmed, it could have profound consequences for our understanding of the solar contributions to the current global warming. The CLOUD (Cosmics Leaving OUtdoor Droplets) project proposes to test experimentally the existence a link between cosmic rays and cloud formation, and to understand the microphysical mechanism. CLOUD plans to perform detailed laboratory measurements in a particle beam at CERN, where all the parameters can be precisely controlled and measured. The beam will pass through an expansion cloud chamber and a reactor chamber where the atmosphere is to be duplicated by moist air charged with selected aerosols and trace condensable vapours. An array of external detectors and mass spectrometers is used to analyse the physical and chemical characteristics of the aerosols and trace gases during beam exposure. Where beam effects are found, the experiment will seek to evaluate their significance in the atmosphere by incorporating them into aerosol and cloud models.