Tag: Chinese Lunar Exploration Program

#CNSA #ChinaNationalSpaceAdministration #国家航天局 |#BeltAndRoadinitiative #CLEP #June2022 | #VonKarmanCrater #LunarMission #Change4 #Yutu2 #ChineseAcademyOfSciences Research Reveals the Constraints of the Chang’e-4 Infrared Imaging Spectroscopic Ground Validation Experiment on the Material Composition of the Lunar SPA Surface…

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As of Month of April 2022, The CNSA –China National Space Administration CLEP- China Lunar Exploration Program  Belt and Road Initiative Lunar Mission……Chang’e-4 with Yutu two the Lunar rover still working exploring more than moved more than 1142.39 meters on the other side of the moon on the 103 Kilometers Diameter Von Karman Crater in which is least than two length by length fifty five Kilometers Hong Kong –Macau- Zhuhai Bridges …. Working Exploring the Crater on the other side of the Moon Chang’e Luna….

On 27th June 2022 the Chinese Academy of Sciences Research Reveals the Constraints of the Chang’e-4 Infrared Imaging Spectroscopic Ground Validation Experiment on the Material Composition of the Lunar SPA Surface

The Infrared Imaging Spectrometer (VNIS) on the Yutu No. 2 Lunar Rover has measured infrared imaging spectral data at multiple locations along the rover’s walking route. VNIS is the main method used to study the composition of lunar soil and lunar surface rocks in the landing area and to trace their origin. The research of the Institute of Geology and Earth Sciences, Chinese Academy of Sciences revealed the constraints on the composition of the lunar SPA surface by the Chang’e-4 infrared imaging spectroscopy ground verification experiment.

The Yutu-2 rover has been working on the lunar surface for more than 40 months, and the infrared imaging spectrometer (VNIS) it carried has measured infrared imaging spectral data at multiple locations along the rover’s walking route. VNIS is the main method used to study the composition of lunar soil and lunar surface rocks in the landing area and to trace their origin. However, factors such as space weathering, particle size and multiple scattering, the spectral response of the instrument, and observation conditions all affect the spectral characteristics and lead to large uncertainties in the mineral composition calculated from the lunar surface spectral data.

  In order to quantitatively evaluate the reliability of different VNIS data processing methods, Chang Rui, a doctoral student in the Key Laboratory of Earth and Planetary Physics, Institute of Geology and Geophysics, Chinese Academy of Sciences, under the guidance of his supervisor researcher Yang Wei and associate researcher Lin Honglei, selected a mineral composition with Spectroscopic ground verification experiments were performed on the Suchang-gabbro with similar lunar highland rocks (Fig. 1). The rock (CR-1) studied by the ground verification experiment has an actual mineral pattern content of 12.9% olivine, 35.0% pyroxene and 52.2% plagioclase, as measured by scanning electron microscopy. In order to more accurately calculate the spectral results of CR-1, the researchers ground and sorted the olivine, low-calcium pyroxene, high-calcium pyroxene and plagioclase from the rock samples in CR-1. -4, ASD) to measure the visible-near-infrared spectral results of each single mineral (Fig. 2a), and each single mineral has its own spectral absorption characteristics. The spectrum of CR-1 measured by the VNIS identifier showed distinct absorption features at the 971 (±1) nm and 1957 (±8) nm bands (Fig. 2b). This absorption feature is similar to the rock absorption feature detected by VNIS on the Yutu-2 rover on the third day of the month. The Hapke model of the VNIS spectrum of CR-1 calculated the mineral pattern content of the sample to be 7.5% olivine, 39.3% pyroxene and 53.2% plagioclase, which were consistent with the true results within the error range.

  According to the data processing method in this study combined with the photometric correction of the Chang’e-4 lunar surface data by Yang et al. (2020), the more accurate mineral model content of the rocks detected by the Yutu-2 rover on the third day should be 11.7 % olivine, 42.8% pyroxene and 45.5% plagioclase. The rover found another lunar surface rock on the 26th day with spectral absorption characteristics similar to those found on the 3rd day, with mineral pattern contents of 3.2% olivine, 24.6% pyroxene, and 72.2% plagioclase. The two lunar surface rocks belong to the sutraite category in the “Anorthosite-Norite-Troctolite” (ANT) system (Fig. 3) (Heiken G, 1991), which means that the Chang’e-4 landing area lunar The rock formations under the soil are mainly ANT rocks. The rocks detected by the Yutu-2 rover on the 26th day contained more plagioclase and were closer to the mineral composition of the average lunar crust.

  To sum up, the lunar surface of the Chang’e-4 landing area has su-long and plagio-like rocks, which represent the material formed by the rapid crystallization in the impact melting pool and the composition of the average lunar crust, respectively. On the one hand, an impact event excavated material from the underlying layers of lunar soil to the lunar surface. These excavated materials have the characteristics of crystalline plutonic rocks in the molten pool of the South Pole Aitken Basin (SPA). On the other hand, the initial lunar crustal material formed before the SPA big impact event can also be retained in the SPA.

  The related research results were published in Remote Sensing . The research work has been funded by the Strategic Pilot Science and Technology Project of the Chinese Academy of Sciences, the Key Deployment Project of the Chinese Academy of Sciences, the Innovation Interdisciplinary Team of the Chinese Academy of Sciences, the Civil Aerospace Pre-research Project of the National Space Administration, and the Key Deployment Project of the Institute of Geology and Geophysics of the Chinese Academy of Sciences.

Figure 1. (a) The image of the lunar surface rock detected by Chang’e-4 on the third month; (b) the spectral detection status of the lunar surface rock (the yellow circle represents the near-infrared spectral detection field); (c) the ground verification of this study The rock used in the experiment (CR-1)

Figure 2. (a) Visible-NIR spectra of single minerals in CR-1; (b) VNIS spectra of rocks and CR-1 measured on the third day of Chang’e-4

Fig. 3. Mineral composition distribution of olivine-pyroxene-plagioclase in lunar surface rocks measured by Chang’e-4 (Heiken G, 1991). The lunar sample sampling points are marked in the figure, for example: A-11 is Apollo 11, L-16 is Luna 16, (H) and (M) represent high ground and lunar soil, respectively

Images and visuals are from their Respectives source Chinese Academy of Sciences .. 52 Sanlihe Rd., Xicheng District, Beijing, China (100864)- People’s Republic of China.

#CNSA #ChinaNationalSpaceAdministration #国家航天局 |#BeltAndRoadinitiative #CLEPS #September 2020 | #VonKarmanCrater #LunarMission#嫦娥 #Change4 #玉兔#Yutu2 #JadeRabbit making another fun learning Luna exploration 5471.20 Meters more #LunaExploration Summary of more than 630-day scientific with more lunar driving…..

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As of 24th September Thursday 2020, The CNSA –China National Space Administration Belt and Road Initiative Lunar Mission on the One Hundred Kilometer diameter Von Karman Crater    Chang’e 4 lander and the “Yutu 2” lunar rover the Chang’e-4 lander and the “Yutu-2” lunar rover… Chang’e 4 lander and “Yutu 2” lunar rover awakened autonomously and entered the 22nd day of work] Today, the Chang’e 4 lander and “Yutu 2” lunar rover, which have been working on the back of the moon for 630 days…..  In following.. The Chang’e-4 lander and the “Yutu-2” lunar rover will finish the 22nd month day work at 7:30 on September 24 and 23:18 on the 23rd, and complete the moon night mode setting according to ground instructions, and enter moon night sleep. Up to now, Chang’e-4 has spent 630 Earth days on the back of the moon and travelled 547.17 meters cumulatively.

Based on the 21st month day panoramic camera stitched images, DOM images and other data, the “Yutu 2” lunar rover mainly travels during the 22nd month day, successively in the impact crater and reflection about 1.3km northwest of the landing site Areas with higher rates were detected.

Researchers have made use of data such as panoramic camera ring-shot detection, infrared imaging spectrometer calibration detection, and simultaneous detection of lunar radar during driving, and obtained a number of scientific results, which were recently published in the International Journal of Nature Astronomy.

The scientific team conducted in-depth research on the radar detection data and obtained important discoveries about the lunar soil and shallow structures in the landing zone. Based on the characteristics of low-frequency radar signals, as shown in Figure 1, the shallow structure of the landing area is divided into three basic units, from top to bottom there are strong reflection units (unit 1), weak reflection units (unit 2), and medium reflection units. Unit (Unit 3). Combining basic constraints such as regional geology and the spatial distribution of large-scale impact craters, the results of the geological interpretation are as follows: Unit 1 (total thickness of about 130m) is the accumulation of sputtering materials near multiple impact craters (including Finsen, Alder, and von Carmen). Impact craters such as L and L’) and the basalt breccia layer at the bottom; unit 2 (total thickness about 110 m) is a basalt layer with multiple eruptions; unit 3 (thickness not less than 200 m) is Leibniz in the north of the landing zone Spatter from impact craters. The high-frequency radar signal further gives the fine structure of the upper part of the unit 1, as shown in Figure 2, which is characterized by the presence of a 12m thick lunar soil layer on the top, which basically does not contain large rocks, and the bottom is a strip of 22m thick Sputters, they are all projectiles from the Finsen impact crater, with a total thickness of 34m.

Fig.1 The detection profile and interpretation result of the low-frequency channel of the lunar radarFig.1 The detection profile and interpretation result of the low-frequency channel of the lunar radar

    The lunar radar carried by the “Yutu-2” lunar rover can obtain the geological section below the driving path and reveal the layered structure of the underground. Because the lunar radar is directly based on the lunar surface for detection, the reflected signal detected by it has large energy and clear characteristics, and the effect is far better than that of spaceborne radars more than 100km away from the lunar surface. Moreover, due to the use of a frequency much higher than 5MHz of the spaceborne radar, its resolution advantage is also very obvious. The main frequencies of the two channels of the lunar radar are 60MHz and 500MHz, the spatial resolution is 10m and 0.3m, and the detection depth is about 50m and 500m. The high-frequency channel is used to detect the high-resolution structure of the shallow lunar soil and its underlying sputter, and the low-frequency channel is used to detect the layered structure of the deep sputter and basalt.

Figure 2 The detection profile and interpretation result of the high-frequency channel of the lunar radar

The shallow structural profile obtained by the lunar radar shows that the lunar material detected by “Yutu 2” comes from the Finsen impact crater, not from the filling basalt of the von Karman impact crater itself; at the same time, the radar profile also reveals the landing area has experienced multiple impacts, sputtering accumulation and multiple basalt magma eruptions filling. These new discoveries are of great significance for understanding the evolution of the Moon’s South Pole-Aiken Basin, and have an important guiding role for the subsequent exploration and study of the composition and structure of the Moon’s internal material.

嫦娥四号着陆器和“玉兔二号”月球车分别于9月24日7时30分、23日23时18分结束第22月昼工作,按地面指令完成月夜模式设置,进入月夜休眠。截至目前,嫦娥四号已在月球背面度过630个地球日,累积行驶547.17米。

基于第21月昼全景相机拼接影像、DOM影像等数据情况,“玉兔二号”月球车在第22月昼期间主要以行驶为主,先后在距离着陆点西北方向约1.3km的撞击坑和反射率较高的区域进行了探测。

科研人员利用全景相机环拍探测、红外成像光谱仪定标探测、测月雷达行驶过程中同步探测等数据,取得多项科学成果,近期发表在Nature Astronomy国际期刊上。

科学团队对雷达探测数据开展了深入研究,获得了着陆区月壤和浅层结构的重要发现。基于低频雷达信号特征,如图1所示,将着陆区的浅层结构划分为三大基本单元,由上往下依次为强反射单元(单元1)、弱反射单元(单元2)和中等反射单元(单元3)。结合区域地质和大型撞击坑的空间分布等基本约束,地质解译结果如下:单元1(总厚度约130m)为临近多个撞击坑的溅射物堆积(包括芬森、阿尔德、冯·卡门L和L’等撞击坑)和底部的玄武岩角砾层;单元2(总厚度约110 m)为多次喷发的玄武岩层;单元3(厚度不小于200 m)为着陆区北部莱布尼兹撞击坑的溅射物。高频雷达信号进一步给出单元1上部的精细结构,如图2所示,其特征为顶部存在厚达12m的月壤层,基本不含大石块,其下为厚达22m的条带状溅射物,它们均是来自芬森撞击坑的抛射物,总厚度达34m。

图1 测月雷达低频通道的探测剖面及解译结果图1 测月雷达低频通道的探测剖面及解译结果

    “玉兔二号”月球车搭载的测月雷达能够获取行驶路径下方的地质剖面,揭示地下的分层结构。由于测月雷达直接基于月面进行探测,因此,其探测到的反射信号能量大,特征清晰,效果远优于距月面100km以上的星载雷达探测。而且,由于采用远高于星载雷达5MHz的主频,其分辨率优势也十分明显。测月雷达两个通道的主频分别为60MHz和500MHz,空间分辨分别为10m和0.3m,探测深度分别约50m和500m。高频通道用于探测浅部月壤及其下伏溅射物的高分辨结构,低频通道用于探测深部溅射物和玄武岩等分层结构。

图2 测月雷达高频通道的探测剖面及解译结果图2 测月雷达高频通道的探测剖面及解译结果

测月雷达所获取的浅层结构剖面表明“玉兔二号”所探测的月面物质来自于芬森撞击坑,而不是来自冯·卡门撞击坑自身的充填玄武岩;同时,该雷达剖面还揭示了着陆区经历多期次的撞击溅射堆积和多期次玄武岩浆喷发充填。这些新发现对于认识月球南极-艾肯盆地的演化具有非常重要的意义,对于月球内部物质组成和结构的后续探测与研究有重要指导作用。

 

Images and Visuals are from Weibo… 

#CNSA #ChinaNationalSpaceAdministration #国家航天局 |#BeltAndRoadinitiative #CLEPS #September 2020 | #VonKarmanCrater #LunarMission#嫦娥 #Change4 #玉兔#Yutu2 #JadeRabbit making another Luna exploration 520 Meters more #LunaExploration Summary of more than 618-day scientific with more lunar driving…..

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As of 11th September 2020, The CNSA –China National Space Administration Belt and Road Initiative Lunar Mission on the One Hundred Kilometre diameter Von Karman Crater    Chang’e 4 lander and the “Yutu 2” lunar rover the Chang’e-4 lander and the “Yutu-2” lunar rover… Chang’e 4 lander and “Yutu 2” lunar rover awakened autonomously and entered the 22nd day of work] Today, the Chang’e 4 lander and “Yutu 2” lunar rover, which have been working on the back of the moon for 618 days…..

Once again Wake up independently by light, at 5:15 on September 12th and 11:54 on September 11th 2020, ushering in the 22nd day of work…..Based on data such as panoramic camera stitching images and DOM images, the “Yutu-2” lunar rover will drive toward the basalt or impact crater area with high reflectivity during the 22nd day of the month. The current detection point is about 83m from the nearest impact crater, and there is a degenerated impact crater with a diameter of about 160m on the south side of the impact crater of the One Hundred Kilometre diameter Von Karman Crater…..

Has the exploration continues  there is a degenerated impact crater with a diameter of about 160m on the south side of the impact crater. Both locations are located to the northwest of the current detection point. The “Yutu-2” lunar rover will conduct scientific exploration of these two impact craters during the day of this month. At that time, the panoramic camera, infrared imaging spectrometer, and neutral atom detector will be turned on one after another and the moon-measuring radar will simultaneously carry out detection during driving. Related scientific results will be released in time….

 

【“嫦娥”“玉兔”自主唤醒,进入第22月昼工作期】已在月球背面工作618天的嫦娥四号着陆器和“玉兔二号”月球车,再次受光照自主唤醒,分别于9月12日5时15分和9月11日11时54分,迎来第22月昼工作期。“玉兔二号”在第22月昼期间将向玄武岩或反射率较高的撞击坑区域行驶,并对其中两个撞击坑开展科学探测。届时,全景相机、红外成像光谱仪、中性原子探测仪将陆续开机,行驶过程中测月雷达同步开展探测。相关科学成果将及时发布。(来源:中国探月工程)

Images and visuals are from Weibo