Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant

MENG Zhiguo; CHEN Shengbo; DU Xiaojuan

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Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant

MENG Zhiguo, CHEN Shengbo, DU Xiaojuan

文章导航 > Chinese Geographical Science > 2011 > 21(1): 94-101

MENG Zhiguo, CHEN Shengbo, DU Xiaojuan. Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant[J]. 中国地理科学, 2011, 21(1): 94-101.

引用本文:

MENG Zhiguo, CHEN Shengbo, DU Xiaojuan. Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant[J]. 中国地理科学, 2011, 21(1): 94-101.

MENG Zhiguo, CHEN Shengbo, DU Xiaojuan. Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant[J]. Chinese Geographical Science, 2011, 21(1): 94-101.

Citation:

MENG Zhiguo, CHEN Shengbo, DU Xiaojuan. Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant[J]. Chinese Geographical Science, 2011, 21(1): 94-101.

Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant

1.
College of GeoExploration Science and Technology, Jilin University, Changchun 130026, China;

详细信息

通讯作者:
CHEN Shengbo

Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant

1.
College of GeoExploration Science and Technology, Jilin University, Changchun 130026, China;

Funds: National Natural Science Foundation of China;National Natural Science Foundation of China;Doctoral Fund of Ministry of Education of China;the basic project operating fund of Jilin university

More Information

Corresponding author: CHEN Shengbo

摘要: The dielectric constant of the surface material may be found from the reflection and transmission coefficients, and plays an important role in the lunar regolith study. In order to study the dielectric properties of the lunar regolith, the lunar regolith simulant is made according to the making procedure of the CAS-1 simulant. Then the dielectric constants of the lunar regolith simulant are measured with 85070E Aiglent microwave network analyzer over the range of 0.2-20 GHz and the temperature in 25.1, 17.7, 13.1, 11.5, 9.6, 8.0, 4.1, - 0.3, - 4.7, - 9.5, - 18.7, - 27.7, - 32.6℃, respectively. The Odelevsky model is employed to remove the influence from the water in the air on the final effective dielectric constant. The result indicates that frequency and temperature have clearly influences on the dielectric constants of the lunar regolith simulant. The real parts of the dielectric constant increase fast over the range of 0.2-3 GHz, but the real parts decrease slowly over the range of 4-20 GHz in total. The opposite phenomenon occurs to the imaginary part. The influences of the frequency and temperature on the brightness temperature are also estimated based on the radiative transfer equation. The result shows that the variation of frequency and temperature results in great changes to the microwave brightness temperature of the lunar regolith.
- Lunar regolith simulant, dielectric constant, temperature, frequency
Abstract: The dielectric constant of the surface material may be found from the reflection and transmission coefficients, and plays an important role in the lunar regolith study. In order to study the dielectric properties of the lunar regolith, the lunar regolith simulant is made according to the making procedure of the CAS-1 simulant. Then the dielectric constants of the lunar regolith simulant are measured with 85070E Aiglent microwave network analyzer over the range of 0.2-20 GHz and the temperature in 25.1, 17.7, 13.1, 11.5, 9.6, 8.0, 4.1, - 0.3, - 4.7, - 9.5, - 18.7, - 27.7, - 32.6℃, respectively. The Odelevsky model is employed to remove the influence from the water in the air on the final effective dielectric constant. The result indicates that frequency and temperature have clearly influences on the dielectric constants of the lunar regolith simulant. The real parts of the dielectric constant increase fast over the range of 0.2-3 GHz, but the real parts decrease slowly over the range of 4-20 GHz in total. The opposite phenomenon occurs to the imaginary part. The influences of the frequency and temperature on the brightness temperature are also estimated based on the radiative transfer equation. The result shows that the variation of frequency and temperature results in great changes to the microwave brightness temperature of the lunar regolith.
- Lunar regolith simulant, dielectric constant, temperature, frequency

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Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant

1. College of GeoExploration Science and Technology, Jilin University, Changchun 130026, China;

基金项目: National Natural Science Foundation of China;National Natural Science Foundation of China;Doctoral Fund of Ministry of Education of China;the basic project operating fund of Jilin university

通讯作者: CHEN Shengbo

收稿日期: 2010-04-14
修回日期: 2010-09-20
刊出日期: 2011-01-15

关键词:

Lunar regolith simulant, dielectric constant, temperature, frequency

摘要: The dielectric constant of the surface material may be found from the reflection and transmission coefficients, and plays an important role in the lunar regolith study. In order to study the dielectric properties of the lunar regolith, the lunar regolith simulant is made according to the making procedure of the CAS-1 simulant. Then the dielectric constants of the lunar regolith simulant are measured with 85070E Aiglent microwave network analyzer over the range of 0.2-20 GHz and the temperature in 25.1, 17.7, 13.1, 11.5, 9.6, 8.0, 4.1, - 0.3, - 4.7, - 9.5, - 18.7, - 27.7, - 32.6℃, respectively. The Odelevsky model is employed to remove the influence from the water in the air on the final effective dielectric constant. The result indicates that frequency and temperature have clearly influences on the dielectric constants of the lunar regolith simulant. The real parts of the dielectric constant increase fast over the range of 0.2-3 GHz, but the real parts decrease slowly over the range of 4-20 GHz in total. The opposite phenomenon occurs to the imaginary part. The influences of the frequency and temperature on the brightness temperature are also estimated based on the radiative transfer equation. The result shows that the variation of frequency and temperature results in great changes to the microwave brightness temperature of the lunar regolith.

English Abstract

Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant

1. College of GeoExploration Science and Technology, Jilin University, Changchun 130026, China;

Corresponding author: CHEN Shengbo

Received Date: 2010-04-14
Rev Recd Date: 2010-09-20
Publish Date: 2011-01-15

Keywords:

Lunar regolith simulant, dielectric constant, temperature, frequency

Abstract: The dielectric constant of the surface material may be found from the reflection and transmission coefficients, and plays an important role in the lunar regolith study. In order to study the dielectric properties of the lunar regolith, the lunar regolith simulant is made according to the making procedure of the CAS-1 simulant. Then the dielectric constants of the lunar regolith simulant are measured with 85070E Aiglent microwave network analyzer over the range of 0.2-20 GHz and the temperature in 25.1, 17.7, 13.1, 11.5, 9.6, 8.0, 4.1, - 0.3, - 4.7, - 9.5, - 18.7, - 27.7, - 32.6℃, respectively. The Odelevsky model is employed to remove the influence from the water in the air on the final effective dielectric constant. The result indicates that frequency and temperature have clearly influences on the dielectric constants of the lunar regolith simulant. The real parts of the dielectric constant increase fast over the range of 0.2-3 GHz, but the real parts decrease slowly over the range of 4-20 GHz in total. The opposite phenomenon occurs to the imaginary part. The influences of the frequency and temperature on the brightness temperature are also estimated based on the radiative transfer equation. The result shows that the variation of frequency and temperature results in great changes to the microwave brightness temperature of the lunar regolith.

MENG Zhiguo, CHEN Shengbo, DU Xiaojuan. Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant[J]. 中国地理科学, 2011, 21(1): 94-101.

引用本文:

MENG Zhiguo, CHEN Shengbo, DU Xiaojuan. Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant[J]. 中国地理科学, 2011, 21(1): 94-101.

MENG Zhiguo, CHEN Shengbo, DU Xiaojuan. Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant[J]. Chinese Geographical Science, 2011, 21(1): 94-101.

Citation:

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Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant

通讯作者: CHEN Shengbo

Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant

Corresponding author: CHEN Shengbo

计量

出版历程

Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant

1. College of GeoExploration Science and Technology, Jilin University, Changchun 130026, China;

通讯作者: CHEN Shengbo

English Abstract

Influence of temperature and frequency on microwave dielectric properties of the lunar regolith simulant

1. College of GeoExploration Science and Technology, Jilin University, Changchun 130026, China;

Corresponding author: CHEN Shengbo

全文HTML

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通讯作者:
CHEN Shengbo