Andy J. López-Oquendo, Mark J. Loeffler and David E. Trilling
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These spectral changes are likely driven by the excess iron found in the altered surface region although other factors, such as the observed structural changes, may also contribute. Additionally, while the 0.27 μm band appears relatively stable under laser irradiation, a broad feature at 0.6 μm rapidly disappears with laser irradiation, suggesting that space weathering may inhibit the detection of any feature in this spectral region, including the 0.7 μm band, which has typically been used an indicator of hydration. Comparing our laboratory results with optical spectrophotometry observations of C-complex asteroids, we find that the majority of objects are spectrally red and possess colors that are similar to our irradiated material rather than our fresh samples. Furthermore, we also find that “younger” and “older” C-complex families have similar colors, suggesting that the space-weathering process is near equal or faster than the time it takes to refresh the surfaces of these airless bodies.","PeriodicalId":34524,"journal":{"name":"The Planetary Science Journal","volume":"129 1","pages":""},"PeriodicalIF":3.8000,"publicationDate":"2024-05-20","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Laser Irradiation of Carbonaceous Chondrite Simulants: Space-weathering Implications for C-complex Asteroids\",\"authors\":\"Andy J. López-Oquendo, Mark J. Loeffler and David E. Trilling\",\"doi\":\"10.3847/psj/ad4028\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Surfaces of carbonaceous asteroids (C-complex) have shown diverse, contrasting spectral variations, which may be related to space weathering. 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Additionally, while the 0.27 μm band appears relatively stable under laser irradiation, a broad feature at 0.6 μm rapidly disappears with laser irradiation, suggesting that space weathering may inhibit the detection of any feature in this spectral region, including the 0.7 μm band, which has typically been used an indicator of hydration. Comparing our laboratory results with optical spectrophotometry observations of C-complex asteroids, we find that the majority of objects are spectrally red and possess colors that are similar to our irradiated material rather than our fresh samples. 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引用次数: 0
摘要
碳质小行星(C-complex)的表面显示出多种多样、对比强烈的光谱变化,这可能与空间风化有关。我们在真空环境下对碳质小行星和碳质小行星模拟材料进行了激光辐照实验,以模拟微陨石撞击引起的光谱变化。我们使用原位紫外-可见光和近红外反射光谱分析脉冲激光辐照引起的光谱变化,并使用扫描电子显微镜和 X 射线光电子能谱寻找微观结构和成分变化。激光辐照会导致光谱斜率增加(变红)和反照率降低(变黑),这些变化在紫外-可见光区域更为强烈。这些光谱变化很可能是由改变表面区域发现的过量铁引起的,尽管其他因素,如观测到的结构变化,也可能起作用。此外,虽然 0.27 μm 波段在激光照射下显得相对稳定,但 0.6 μm 波段的宽特征在激光照射下迅速消失,这表明空间风化可能会抑制对该光谱区域任何特征的探测,包括 0.7 μm 波段,该波段通常被用作水化指标。将我们的实验室结果与 C 复合小行星的光学分光光度观测结果进行比较,我们发现大多数天体的光谱都是红色的,其颜色类似于我们的辐照物质,而不是我们的新鲜样本。此外,我们还发现 "年轻 "和 "年长 "的 C-复合族具有相似的颜色,这表明空间风化过程与这些无空气天体表面刷新所需的时间几乎相等或更快。
Laser Irradiation of Carbonaceous Chondrite Simulants: Space-weathering Implications for C-complex Asteroids
Surfaces of carbonaceous asteroids (C-complex) have shown diverse, contrasting spectral variations, which may be related to space weathering. We performed laser irradiation experiments on CI and CM simulant material under vacuum to mimic the spectral alteration induced by micrometeorite impacts. We used in situ ultraviolet-visible and near-infrared reflectance spectroscopy to analyze spectral alterations in response to pulsed laser irradiation, as well as scanning electron microscopy and X-ray photoelectron spectroscopy to search for microstructural and compositional changes. Laser irradiation causes an increase in spectral slope (reddening) and a decrease in the albedo (darkening), and these changes are stronger in the ultraviolet-visible region. These spectral changes are likely driven by the excess iron found in the altered surface region although other factors, such as the observed structural changes, may also contribute. Additionally, while the 0.27 μm band appears relatively stable under laser irradiation, a broad feature at 0.6 μm rapidly disappears with laser irradiation, suggesting that space weathering may inhibit the detection of any feature in this spectral region, including the 0.7 μm band, which has typically been used an indicator of hydration. Comparing our laboratory results with optical spectrophotometry observations of C-complex asteroids, we find that the majority of objects are spectrally red and possess colors that are similar to our irradiated material rather than our fresh samples. Furthermore, we also find that “younger” and “older” C-complex families have similar colors, suggesting that the space-weathering process is near equal or faster than the time it takes to refresh the surfaces of these airless bodies.