Chemical modeling of the complex organic molecules in the extended region around Sagittarius B2

arXiv: Astrophysics of Galaxies Pub Date : 2021-03-18 DOI:10.1051/0004-6361/202140411

Yao Wang, F. Du, D. Semenov, Hongchi Wang, Juan Li

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引用次数: 2

Abstract

The chemical differentiation of seven COMs in the extended region around Sgr B2 has been observed: CH$_2$OHCHO, CH$_3$OCHO, t-HCOOH, C$_2$H$_5$OH, and CH$_3$NH$_2$ were detected both in the extended region and near the hot cores Sgr B2(N) and Sgr B2(M), while CH$_3$OCH$_3$ and C$_2$H$_5$CN were only detected near the hot cores. The density and temperature in the extended region are relatively low. Different desorption mechanisms have been proposed to explain the observed COMs in cold regions but fail to explain the deficiency of CH$_3$OCH$_3$ and C$_2$H$_5$CN. We explored under what physical conditions the chemical simulations can fit the observations and explain the different spatial distribution of these species. We used the Monte Carlo method to perform a detailed parameter space study. We investigated how different mechanisms affect the results. All gas-grain chemical models based on static physics cannot fit the observations. The results based on evolving physical conditions can fit six COMs when $T\sim30-60$ K, but the best-fit temperature is still higher than the observed dust temperature of 20 K. The best agreement at $T\sim27$ K is achieved by considering a short-duration $\sim 10^2$ yr X-ray burst with $\zeta_{\mathrm{CR}}=1.3\times10^{-13}$ s$^{-1}$ when the temperature is 20 K. The reactive desorption is the key mechanism for producing these COMs and inducing the low abundances of CH$_3$OCH$_3$ and C$_2$H$_5$CN. The evolution of the extended region around Sgr~B2 may have begun with a cold, $T\le10$ K phase followed by a warm-up phase. When its temperature reached $T\sim20$ K, an X-ray flare from Sgr A* with a short duration of no more than 100 years was acquired, affecting strongly the Sgr B2 chemistry. The observed COMs retain their observed abundances only several hundred years after such a flare, which could imply that such short-term X-ray flares occur relatively often.

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人马座B2周围扩展区域复杂有机分子的化学建模

在Sgr B2附近的扩展区，发现了7个COMs的化学分化:CH $_2$ OHCHO、CH $_3$ OCHO、t-HCOOH、C $_2$ H $_5$ OH和CH $_3$ NH $_2$在扩展区和热核Sgr B2(N)和Sgr B2(M)附近均有发现，而CH $_3$ OCH $_3$和C $_2$ H $_5$ CN仅在热核附近有发现。延伸区域的密度和温度相对较低。人们提出了不同的解吸机制来解释在寒冷地区观测到的COMs，但未能解释CH $_3$ OCH $_3$和C $_2$ H $_5$ CN的缺乏。我们探索了在什么物理条件下化学模拟可以拟合观测结果，并解释了这些物种的不同空间分布。我们使用蒙特卡罗方法进行了详细的参数空间研究。我们研究了不同的机制如何影响结果。所有基于静态物理的气粒化学模型都不能与观测结果拟合。当温度为$T\sim30-60$ K时，基于物理条件变化的结果可以拟合6个COMs，但最佳拟合温度仍高于20 K的观测尘埃温度。当温度为20k时，通过考虑$\zeta_{\mathrm{CR}}=1.3\times10^{-13}$ s $^{-1}$的短时间$\sim 10^2$ yr x射线爆发，获得了$T\sim27$ K的最佳一致性。反应解吸是产生这些COMs并诱导低丰度CH $_3$ OCH $_3$和C $_2$ H $_5$ CN的关键机制。Sgr B2周围扩展区域的演化可能是从寒冷的$T\le10$ K阶段开始的，随后是热身阶段。当Sgr A*的温度达到$T\sim20$ K时，从Sgr A*获得了一个持续时间不超过100年的x射线耀斑，强烈影响了Sgr B2的化学性质。观测到的COMs在这种耀斑发生几百年后仍然保持着观测到的丰度，这可能意味着这种短期的x射线耀斑相对频繁地发生。

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arXiv: Astrophysics of Galaxies

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