Non-diffusive pitch-angle scattering of a distribution of energetic particles by coherent whistler waves

Abstract

<p>A recent study and a companion talk [1] showed that an exact rearrangement of the relativistic particle equation of motion under a coherent circularly-polarized electromagnetic wave leads to an equation describing the motion of the &#8220;frequency mismatch&#8221; parameter &#958; under a pseudo-potential &#968;(&#958;). When the particle undergoes a so-called &#8220;two-valley motion&#8221; in &#958;-space, it experiences large changes in &#958; and thus its pitch-angle because &#958; is a function of the particle&#8217;s velocity parallel to the background magnetic field. This single-particle analysis is extended [2] to a distribution of relativistic particles. First, the condition for two-valley motion is derived with parameters relevant to magnetospheric contexts. Single-particle simulations verify that particles which satisfy this condition indeed undergo large pitch-angle fluctuations. Second, assuming a relativistic Maxwellian particle distribution, the fraction of particles that undergo two-valley motion is analytically derived and is numerically verified by Monte-Carlo simulations. A significant fraction (1% - 5%) of the distribution undergoes two-valley motion for typical magnetospheric parameters. For sufficiently fast interactions where a uniform background magnetic field and a constant wave frequency can be assumed, the widely-used second-order trapping theory [3] is shown to be an erroneous approximation of the present theory.</p><p>&#160;</p><p>[1] P. M. Bellan, Phys. Plasmas, 20 (4), Art. No. 042117 (2013)</p><p>[2] Y. D. Yoon and P. M. Bellan, JGR Space Physics, 125 (6), Art. No. e2020JA027796 (2020)</p><p>[3] D. Nunn, Planet. and Space Sci., 22 (3), 349-378 (1974)</p><p>&#160;</p>