从中国嫦娥二号和 LRO 分光辐射计观测到的月球热流

IF 1.4 4区物理与天体物理 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

AIP Advances Pub Date : 2024-09-05 DOI:10.1063/5.0221307

Dan Zhang, Cui Li

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引用次数: 0

摘要

根据嫦娥二号（CE-2）月球微波辐射计观测到的微波亮度温度和月球勘测轨道器（LRO）占卜者辐射计观测到的红外亮度温度，对北纬75°至南纬65°和西经60°至东经100°区域内的月球热流进行了检索。热导率与垂直温度梯度的乘积即为月球热流。垂直温度梯度由一个新的温度曲线计算得出，其未知参数是利用多层月球表面微波亮度温度模型从 CE-2 微波亮度温度中确定的。温度曲线的边界条件由 LRO 红外亮度温度确定。在检索过程中，选择阿波罗 15 号着陆点测得的热流作为校准参考点。在北纬 75° 至南纬 65° 和西经 60° 至东经 100° 区域内，检索到的月球热流介于 0.8 至 69.2 mW/m2 之间。根据检索结果，高原地区的月球热流高于海洋地区。月球上北纬75°至南纬65°和西经60°至东经100°区域内的最高热流位于东部高地，平均热流值为35.8 mW/m2，最低热流基本位于典型的海洋，如前星洋（Oceans Procellarum）、英布利姆海（Mare Imbrium）和半月海（Mare Serenitatis），平均热流值为18.5 mW/m2。

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Lunar heat flow from the observation of Chinese Chang’E 2 and LRO diviner radiometers

Lunar heat flow within 75°N to 65°S and 60°W to 100°E regions is retrieved from microwave brightness temperature observed by Chang’E-2 (CE-2) Lunar Microwave Radiometers and infrared brightness temperature observed by Lunar Reconnaissance Orbiter (LRO) Diviner Radiometers. The product of the regolith’s thermal conductivity and vertical temperature gradient yields the lunar heat flow. The vertical temperature gradient is calculated by a new temperature profile, the unknown parameters of which are determined from CE-2 microwave brightness temperature using a multi-layered lunar surface microwave brightness temperature model. The boundary condition of the temperature profile is determined by the LRO infrared brightness temperature. The measured heat flow at the Apollo 15 landing site is chosen as a calibration reference point in the retrieval process. The retrieved lunar heat flow within 75°N to 65°S and 60°W to 100°E regions ranged from 0.8 to 69.2 mW/m2. According to the retrieved results, lunar heat flow in the highlands is higher than the maria. The highest heat flux within 75°N to 65°S and 60°W to 100°E regions on the Moon are located toward the eastern highlands with an averaged heat flow value of 35.8 mW/m2, and the lowest heat flux is basically located in the typical maria such as Oceans Procellarum, Mare Imbrium, and Mare Serenitatis with an averaged heat flow value of 18.5 mW/m2.

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来源期刊

AIP Advances NANOSCIENCE & NANOTECHNOLOGY-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

2.80

自引率

6.20%

发文量

1233

审稿时长

2-4 weeks

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