Abstract:
Alfvénic fluctuations are widespread and crucial in various physical processes of space & astrophysical plasma. However, their
role in heating and work done remains unexplored. Here, we have used Wind spacecraft’s data situated at 1 AU distance to
examine 12 distinct Alfvénic regions using polytropic analysis. The study finds an average polytropic index value U = 2 64, which
is consistent with a super-adiabatic behaviour for plasma particles with three effective degrees of freedom ( 5 = 3). Moreover, this
study examines several scenarios for plasma particles with different degrees of freedom.We noted that the investigated Alfvénic
region could be adiabatic only for plasma particles with 5 = 1 26 degrees of freedom. In addition to this, for U = 2 64, the ratio
of work done to the total heat supply within the system is XF
X@ = 0 68, indicating that 68 per cent of the total supplied heat is
utilized to accomplish work by the system on the surrounding (expansion phenomena), and the remaining is used to increase the
internal energy of the system. As a result, we hypothesized that the Alfvénic plasma region is cooling more than the adiabatic
expectation, resulting in super-cooling phenomena. Thus, we propose that the discovered possible super-adiabatic process would
be critical in understanding the energy transfer from the Alfvénic zone to the surrounding plasma.
