FLAYERS IN THE PLANETS ATMOSPHERE

Odessa Astronomical Publications Pub Date : 2023-12-04 DOI:10.18524/1810-4215.2023.36.289978

D. Doikov, M. D. Doikov

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Abstract

Planets of the Solar System or exoplanets with atmospheres are complicated to investigate because of the absence of sufficiently intense energy fluxes reflected by their atmospheres. At a sufficiently high brightness of the neighboring star, the atmosphere of the exoplanet gives the absorption spectra of some molecules with a high dissociation potential. If the star's surface temperature is low enough and its activity is low, then the presence of thunderstorm activity in the planet's atmosphere can make it possible to identify it. We show the processes that lead to the formation of flare spectra in the γ- and optical ranges and ways to identify them. It is important to note that current discharges initiate intense nuclear transformations with the formation of proton-rich C11, N13, and O15 nuclei. The spectrum of such a medium is specific and different from the spectra formed by the neighboring star. The statistical irregularity of the frequency of thunderstorms and the variety of conditions in the atmospheres of planets makes it possible to study them due to their illumination in the optical part of the spectrum. It is shown that the integrated optical flow and the detailed γ-spectrum make it possible to trace the time evolution of the lightning head current cord and obtain quantitative values of the current strength. Such fluctuations of the current give changes in the magnetic field of the filament, comparable with the value and even greater than the intrinsic magnetic fields of the planets. To carry out the proposed research, M. Doikov developed a multichannel spectrograph consisting of a γ- and optical spectrometer, a highly sensitive magnetometer, and a radio wave recorder. Its design is discussed in his report. We also note here that the calculations make it possible to determine the statistical parameter of time signals, the operating modes of the equipment, and the selection of the necessary nodes for designing the final working layout of the multichannel spectrometer. The value of the choice of observation site is indicated. In mountainous areas, these are heights of the order of a kilometer. In this case, the devices are near lightning.

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行星大气层中的飞行器

太阳系行星或有大气层的系外行星的研究比较复杂，因为它们的大气层没有反射足够强的能量通量。在邻近恒星亮度足够高的情况下，系外行星的大气层会给出一些具有高解离势的分子的吸收光谱。如果恒星的表面温度足够低，其活动也较少，那么行星大气中存在的雷暴活动就有可能使我们识别出它。我们展示了在γ和光学范围内形成耀斑光谱的过程以及识别它们的方法。值得注意的是，电流放电会引发强烈的核转变，形成富含质子的 C11、N13 和 O15 核。这种介质的光谱是特殊的，与邻近恒星形成的光谱不同。雷暴频率的统计不规则性和行星大气中的各种条件使得研究它们成为可能，因为它们在光谱的光学部分被照亮。研究表明，通过综合光流和详细的 γ 光谱，可以追踪雷电头电流线的时间演变，并获得电流强度的定量值。电流的这种波动会引起灯丝磁场的变化，其值与行星的固有磁场相当，甚至更大。为了进行拟议的研究，M. 多伊科夫开发了一种多通道光谱仪，其中包括一个 γ 和光学光谱仪、一个高灵敏度磁力计和一个无线电波记录器。他在报告中讨论了这一装置的设计。我们在此还注意到，通过计算可以确定时间信号的统计参数、设备的工作模式，以及设计多道光谱仪最终工作布局所需的节点选择。观测地点选择的价值体现。在山区，这些高度约为一公里。在这种情况下，设备靠近雷电。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Odessa Astronomical Publications

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审稿时长

15 weeks