Dielectric Properties of Lunar Subsurface Materials

Zehua Dong; Guangyou Fang; Di Zhao; Bin Zhou; Yunze Gao; Yicai Ji

doi:10.1029/2020GL089264

Dielectric Properties of Lunar Subsurface Materials

Zehua Dong, Guangyou Fang^*, Di Zhao, Bin Zhou, Yunze Gao, Yicai Ji

^*Corresponding author for this work

School of Information and Electronics

Research output: Contribution to journal › Article › peer-review

27 Citations (Scopus)

Abstract

The dielectric permittivity is one of the most significant properties of lunar material. For the past decades, researchers have assumed or used an indirect density versus depth relation to constrain the subsurface permittivity on the Moon. On 3 January 2019, Chang'E-4 (CE-4) rover-borne lunar penetrating radar (LPR) successfully landed on the Von Kármán crater on the Moon's farside. CE-4 LPR is the first surface radar on the Moon's farside for exploring regolith thickness and geological structure. Numerous parabolic-shaped diffractions (PSD), which indicate subsurface objects, are identified in LPR data. We estimate the permittivity of the first ~50 m at the landing region using these PSDs based on a hyperbolic fitting method. A best-fit permittivity/density versus depth relation is obtained, and this relation could be used at different areas on the Moon.

Original language	English
Article number	e2020GL089264
Journal	Geophysical Research Letters
Volume	47
Issue number	22
DOIs	https://doi.org/10.1029/2020GL089264
Publication status	Published - 28 Nov 2020

Keywords

Chang'E-4 (CE-4)
dielectric permittivity
lunar penetrating radar (LPR)
lunar regolith
the Moon

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10.1029/2020GL089264

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abstract = "The dielectric permittivity is one of the most significant properties of lunar material. For the past decades, researchers have assumed or used an indirect density versus depth relation to constrain the subsurface permittivity on the Moon. On 3 January 2019, Chang'E-4 (CE-4) rover-borne lunar penetrating radar (LPR) successfully landed on the Von K{\'a}rm{\'a}n crater on the Moon's farside. CE-4 LPR is the first surface radar on the Moon's farside for exploring regolith thickness and geological structure. Numerous parabolic-shaped diffractions (PSD), which indicate subsurface objects, are identified in LPR data. We estimate the permittivity of the first ~50 m at the landing region using these PSDs based on a hyperbolic fitting method. A best-fit permittivity/density versus depth relation is obtained, and this relation could be used at different areas on the Moon.",

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T1 - Dielectric Properties of Lunar Subsurface Materials

AU - Dong, Zehua

AU - Fang, Guangyou

AU - Zhao, Di

AU - Zhou, Bin

AU - Gao, Yunze

AU - Ji, Yicai

PY - 2020/11/28

Y1 - 2020/11/28

N2 - The dielectric permittivity is one of the most significant properties of lunar material. For the past decades, researchers have assumed or used an indirect density versus depth relation to constrain the subsurface permittivity on the Moon. On 3 January 2019, Chang'E-4 (CE-4) rover-borne lunar penetrating radar (LPR) successfully landed on the Von Kármán crater on the Moon's farside. CE-4 LPR is the first surface radar on the Moon's farside for exploring regolith thickness and geological structure. Numerous parabolic-shaped diffractions (PSD), which indicate subsurface objects, are identified in LPR data. We estimate the permittivity of the first ~50 m at the landing region using these PSDs based on a hyperbolic fitting method. A best-fit permittivity/density versus depth relation is obtained, and this relation could be used at different areas on the Moon.

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KW - Chang'E-4 (CE-4)

KW - dielectric permittivity

KW - lunar penetrating radar (LPR)

KW - lunar regolith

KW - the Moon

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Dielectric Properties of Lunar Subsurface Materials

Abstract

Keywords

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