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Compressive Coherent Structures at Ion Scales in the Slow Solar Wind

We present a study of magnetic field fluctuations, in a slow solar wind stream, close to ion scales, where an increase of the level of magnetic compressibility is observed. Here, the nature of these compressive fluctuations is found to be characterized by coherent structures. Although previous studies have shown that current sheets can be considered as the principal cause of intermittency at ion scales, here we show for the first time that, in the case of the slow solar wind, a large variety of coherent structures contributes to intermittency at proton scales, and current sheets are not the most common. Specifically, we find compressive ($δb_{\|} \gg δb_{\perp}$), linearly polarized structures in the form of magnetic holes, solitons and shock waves. Examples of Alfvénic structures ($δb_{\perp} > δb_{\|}$) are identified as current sheets and vortex-like structures. Some of these vortices have $ δb_{\perp} \gg δb_{\|}$, as in the case of Alfvén vortices, but the majority of them are characterized by $δb_{\perp} \gtrsim δb_{\|}$. Thanks to multi-point measurements by Cluster spacecraft, for about 100 structures, we could determine the normal, the propagation velocity and the spatial scale along this normal. Independently of the nature of the structures, the normal is always perpendicular to the local magnetic field, meaning that $k_{\perp} \gg k_{\parallel}$. The spatial scales of the studied structures are found to be between 2 and 8 times the proton gyroradius. Most of them are simply convected by the wind, but 25\% propagate in the plasma frame. Possible interpretations of the observed structures and the connection with plasma heating are discussed.