Space weathering of silicates simulated by successive laser irradiation: In situ reflectance measurements of Fo90, Fo99+, and SiO2

Loeffler, M. J.; Dukes, C. A.; Christoffersen, R.; Baragiola, R. A.

doi:10.1111/maps.12581

Cited by 36 publications

(44 citation statements)

References 54 publications

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“…On the contrary, the nanophase metal particles are distributed nonuniformly on the surface of the olivine. They are concentrated at the edges of ripple‐shaped ridges (Figures e and f) which is consistent with Loeffler et al () studies. For the Gebel Kamil iron meteorite, the characteristics of melt and vapor deposits are similar to those of kamacite in Huaxi ordinary chondrite (Figures g and h).…”

Section: Results and Analysissupporting

confidence: 91%

“…Those of silicate minerals which are dozens of microns away from kamacite usually have a four‐layer structure (Figures b and c), in which many npFe, identified by the interplanar spacing, are observed in the outer three layers (Figures d and e). However, silicate minerals near kamacite show a two‐layer structure in which a vapor‐deposited layer covers the substrate (Figure f) which is consistent with Loeffler et al () studies. In this layer, npFe of several nanometers to hundreds of nanometers are also identified by their interplanar spacing (Figures g and h).…”

Section: Results and Analysissupporting

confidence: 89%

“…In our work, the obvious difference with previous studies such as Christoffersen et al (2016) is that the amorphous layer is divided into partially amorphous layer and completely amorphous layer which is similar to Loeffler et al (2016) studies. And the vapor-deposited layer only can be easily observed in some places, such as the olivine and pyroxene near kamacite, and this layer, when present, is enriched in npFe or Fe-Ni (Figure 8a), which is similar to Noble et al (2011Noble et al ( , 2016) studies (Figure 8b).…”

Section: Journal Of Geophysical Research: Planetssupporting

confidence: 49%

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Impact Characteristics of Different Rocks in a Pulsed Laser Irradiation Experiment: Simulation of Micrometeorite Bombardment on the Moon

Yao

et al. 2017

JGR Planets

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Without the protection of the atmosphere, the soils on lunar surfaces undergo a series of optical, physical, and chemical changes during micrometeorite bombardment. To simulate the micrometeorite bombardment process and analyze the impact characteristics, four types of rocks, including terrestrial basalt and anorthosite supposed to represent lunar rock, an H‐type chondrite (the Huaxi ordinary chondrite), and an iron meteorite (the Gebel Kamil iron meteorite) supposed to represent micrometeorite impactors, are irradiated by a nanosecond pulse laser in a high vacuum chamber. Based on laser irradiation experiments, the laser pits are found to be of different shapes and sizes which vary with the rock type. Many melt and vapor deposits are found on the mineral surfaces of all the samples, and nanophase iron (npFe) or Fe‐Ni alloy particles are typically distributed on the surfaces of ilmenite, kamacite, or other minerals near kamacite. By analyzing the focused ion beam ultrathin slices of laser pits with a transmission electron microscope, the results show that the subsurface structures can be divided into three classes and that npFe can be easily found in Fe‐bearing minerals. These differences in impact characteristics will help determine the source material of npFe and infer the type of micrometeorite impactors. During micrometeorite bombardment, in the mare regions, the npFe are probably produced simultaneously from lunar basalt and micrometeorites with iron‐rich minerals, while the npFe in the highlands regions mainly come from micrometeorites.

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Section: Results and Analysissupporting

confidence: 91%

Section: Results and Analysissupporting

confidence: 89%

Section: Journal Of Geophysical Research: Planetssupporting

confidence: 49%

See 1 more Smart Citation

Impact Characteristics of Different Rocks in a Pulsed Laser Irradiation Experiment: Simulation of Micrometeorite Bombardment on the Moon

Yao

et al. 2017

JGR Planets

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“…Thus, while experiments provide data on individual aspects of space weathering, they cannot replicate the complexity of natural materials and offer only qualitative points of comparison. Distinct sublayers were formed on an olivine sample altered in a 99‐pulse experiment (Loeffler et al, ) that resemble the layers in sample 71501‐ol in having both nominally npFe 0 ‐free layers somewhat depleted in Fe and other sublayers rich in 5–20 nm npFe 0 . Depletion of Fe is consistent with vapor phase fractionation of olivine (Fazio et al, ).…”

Section: Discussionmentioning

confidence: 99%

Coordinated Nanoscale Compositional and Oxidation State Measurements of Lunar Space‐Weathered Material

Burgess

Stroud

2018

JGR Planets

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Space weathering on airless bodies includes a number of processes, such as micrometeorite impacts and solar wind bombardment, which leads to a variety of microscale to nanoscale alteration features, including vapor deposited layers on grain and rock surfaces and creation of nanophase opaque inclusions. The nanophase inclusions cause reddening and darkening of the visible to near-infrared spectra of space weathered material, features associated with increasing space exposure of many airless body regoliths. On the Moon, most nanophase inclusions are metallic iron (npFe 0 ), but recent work using aberration-corrected scanning transmission electron microscopy and electron energy loss spectroscopy has provided evidence of oxidized nanoparticles in space weathered lunar soil grains. We examined three different lunar soils in order to confirm the finding of oxidized nanophase inclusions and to provide detailed elemental and mineralogical information about the surrounding material. Our data show that substrate and rim composition are key factors in determining whether highly localized oxidation occurs; for example, nanophase inclusions in rims on low Fe substrates are more prone to oxidation. Detailed understanding of the phases and features present in these samples is necessary for the correct interpretation of remotely sensed data as well as extrapolation from processes on the lunar surface to those on other airless bodies.Plain Language Summary The Moon and asteroids are being constantly altered by interactions with the space environment, a process known as space weathering. These interactions, such as with solar wind ions and micrometeoroids, can be studied by examining samples from the Moon and analyzing the nanoscale features present in surface coatings or rims on small lunar dust grains. Using techniques such as energy dispersive X-ray spectroscopy and electron energy loss spectroscopy in the scanning transmission electron microscope, we are able to image and measure the composition and oxidation state of the nanoscale inclusions and layers in these rims. These data provide evidence of complex material interactions, such as formation of metallic iron inclusions at a variety of sizes contained within specific sublayers, and oxidation to magnetite of some of those inclusions. From this information, we can better interpret spacecraft and telescopic data of the Moon and asteroids that can be significantly influenced by space weathering and the presence of nanoscale inclusions. We can also compare these data to samples that have been experimentally space weathered in the laboratory using pulsed laser or ion irradiation in order to gain a better understanding of the conditions necessary to create observed features.

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“…In fact, multiple laboratories have recently or will very soon become operational in order to test ice surface chemistry under varying radiative conditions (Ioppolo et al 2013;Allodi et al 2013;Paardekooper et al 2014), chemistry on bare carbonaceous or silicate surfaces (e.g. Loeffler et al 2016, and references therein), and radical-driven gas phase kinetics (C. Endres 2015, private communication). As the measurements from these experiments become available, they can be included in models.…”

Section: (Not Yet) Understanding Interstellar Chemistrymentioning

confidence: 99%

Astrochemistry in the Age of Broadband Radio Astronomy

Corby

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This dissertation explores the challenges and advancements introduced by the arrival of new-generation radio telescopes for understanding the physical and chemical structure of the Interstellar Medium (ISM). New-generation broadband radio instruments, and particularly broadband interferometers, provide the opportunity to obtain a comprehensive view 6 The Inhomogeneous Structure of Translucent Clouds Observed by Radio Interferomety 6.

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Space weathering of silicates simulated by successive laser irradiation: In situ reflectance measurements of Fo₉₀, Fo₉₉₊, and SiO₂

Cited by 36 publications

References 54 publications

Impact Characteristics of Different Rocks in a Pulsed Laser Irradiation Experiment: Simulation of Micrometeorite Bombardment on the Moon

Impact Characteristics of Different Rocks in a Pulsed Laser Irradiation Experiment: Simulation of Micrometeorite Bombardment on the Moon

Coordinated Nanoscale Compositional and Oxidation State Measurements of Lunar Space‐Weathered Material

Astrochemistry in the Age of Broadband Radio Astronomy

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