Your search keyword '"Matthew R. M. Izawa"' showing total 11 results

1. Titanite Mineralization of Microbial Bioalteration Textures in Jurassic Volcanic Glass, Coast Range Ophiolite, California

Author

Matthew R. M. Izawa, Neil R. Banerjee, John W. Shervais, Roberta L. Flemming, Callum J. Hetherington, Karlis Muehlenbachs, Cynthia Schultz, Debarati Das, and Barry B. Hanan

Subjects

ichnofossil, bioalteration, astrobiology, basaltic glass, titanite, Science

Abstract

Volcanic glasses are rarely preserved in the rock record, and the quality of preservation generally declines with increasing age. Records preserved in ancient basaltic glasses therefore provide important links between processes operating in the distant past, and those that are active on the Earth today. Microbial colonization has been linked to the formation of characteristic structures in basaltic glass, including tubules and granule-filled tubules, which are thought to be produced by microbially mediated glass dissolution. Structures of similar occurrence and morphology but filled almost entirely with fine-grained titanite have been documented in some ancient metabasalts. It has been suggested that the ancient titanite-mineralized structures are mineralized equivalents of hollow tubules in modern glassy basaltic rocks, but a direct link has not been firmly established. We report the discovery of tubular bioalteration structures in fresh and minimally altered basaltic glasses of middle Jurassic (164 Ma) age from the Stonyford Volcanic Complex (SFVC), Coast Range Ophiolite, California. Tubular structures hosted in unaltered basaltic glass are typically hollow, whilst those in zones of zeolitic alteration are mineralized by titanite. Tubules are continuous across zeolite-glass interfaces, which mark an abrupt change from titanite-filled to hollow tubules, demonstrating that titanite growth occurs preferentially within pre-existing tubular structures. Titanite mineralization in the SFVC represent a link between tubular structures in modern basaltic glass and titanite-mineralized features of similar morphology and spatial distribution in ancient metabasalts. Our observations support a link between textures in modern glassy basaltic rocks and some of the oldest-known putative ichnofossils.

Published

2019

2. Organic Matter Preservation and Incipient Mineralization of Microtubules in 120 Ma Basaltic Glass

Author

Matthew R. M. Izawa, James J. Dynes, Neil R. Banerjee, Roberta L. Flemming, Lachlan C. W. MacLean, Callum J. Hetherington, Sergei Matveev, and Gordon Southam

Subjects

ichnofossils, biomolecule, basaltic glass, synchrotron XANES, Ontong Java Plateau, Science

Abstract

Hollow tubular structures in subaqueously-emplaced basaltic glass may represent trace fossils caused by microbially-mediated glass dissolution. Mineralized structures of similar morphology and spatial distribution in ancient, metamorphosed basaltic rocks have widely been interpreted as ichnofossils, possibly dating to ∼3.5 Ga or greater. Doubts have been raised, however, regarding the biogenicity of the original hollow tubules and granules in basaltic glass. In particular, although elevated levels of biologically-important elements such as C, S, N, and P as well as organic compounds have been detected in association with these structures, a direct detection of unambiguously biogenic organic molecules has not been accomplished. In this study, we describe the direct detection of proteins associated with tubular textures in basaltic glass using synchrotron X-ray spectromicroscopy. Protein-rich organic matter is shown to be associated with the margins of hollow and partly-mineralized tubules. Furthermore, a variety of tubule-infilling secondary minerals, including Ti-rich oxide phases, were observed filling and preserving the microtextures, demonstrating a mechanism whereby cellular materials may be preserved through geologic time.

Published

2019

3. Biogeochemical Cycling of Silver in Acidic, Weathering Environments

Author

Jeremiah Shuster, Frank Reith, Matthew R. M. Izawa, Roberta L. Flemming, Neil R. Banerjee, and Gordon Southam

Subjects

silver biogeochemical cycling, argentojarosite, iron-oxidizing bacteria/archaea, gossan, terrace iron formations, Mineralogy, QE351-399.2

Abstract

Under acidic, weathering conditions, silver (Ag) is considered to be highly mobile and can be dispersed within near-surface environments. In this study, a range of regolith materials were sampled from three abandoned open pit mines located in the Iberian Pyrite Belt, Spain. Samples were analyzed for Ag mineralogy, content, and distribution using micro-analytical techniques and high-resolution electron microscopy. While Ag concentrations were variable within these materials, elevated Ag concentrations occurred in gossans. The detection of Ag within younger regolith materials, i.e., terrace iron formations and mine soils, indicated that Ag cycling was a continuous process. Microbial microfossils were observed within crevices of gossan and their presence highlights the preservation of mineralized cells and the potential for biogeochemical processes contributing to metal mobility in the rock record. An acidophilic, iron-oxidizing microbial consortium was enriched from terrace iron formations. When the microbial consortium was exposed to dissolved Ag, more than 90% of Ag precipitated out of solution as argentojarosite. In terms of biogeochemical Ag cycling, this demonstrates that Ag re-precipitation processes may occur rapidly in comparison to Ag dissolution processes. The kinetics of Ag mobility was estimated for each type of regolith material. Gossans represented 0.6–146.7 years of biogeochemical Ag cycling while terrace iron formation and mine soils represented 1.9–42.7 years and 0.7–1.6 years of Ag biogeochemical cycling, respectively. Biogeochemical processes were interpreted from the chemical and structural characterization of regolith material and demonstrated that Ag can be highly dispersed throughout an acidic, weathering environment.

Published

2017

4. Complex Water Ice Mixtures on NII Nereid: Constraints from NIR Reflectance

Author

Benjamin N. L. Sharkey, Walter M. Harris, Vishnu Reddy, Matthew R. M. Izawa, and Juan A. Sanchez

Subjects

Murchison meteorite, Physics, Earth and Planetary Astrophysics (astro-ph.EP), Solar System, Continuum (design consultancy), Uranus, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, Spectral line, Geophysics, Space and Planetary Science, Neptune, Absorption band, Chondrite, Earth and Planetary Sciences (miscellaneous), Astrophysics::Earth and Planetary Astrophysics, Astrophysics - Earth and Planetary Astrophysics

Abstract

Nereid, Neptune's third largest satellite, lies in an irregular orbit and is the only outer satellite in the system (apart from Triton) that can be spectroscopically characterized with the current generation of Earth-based telescopes. We report our results on spectral characterization of Nereid using its reflectance spectrum from 0.8-2.4 $\mu m$, providing the first measurements over the range of 0.8-1.4 $\mu m$. We detect spectral absorption features of crystalline water ice in close agreement with previous measurements. We show that model fits of simple intimate mixtures including water ice do not provide simultaneous matches to absorption band depths at 1.5 and 2.0 $\mu m$ when accounting for the spectral continuum. Possible solutions include invoking a more complex continuum, including both crystalline and amorphous water ice, and allowing for sub-micron sized grains. We show that mixtures including magnetite and the CM2 chondrite Murchison provide a flexible framework for interpreting spectral variation of bodies with neutral-sloped spectra like that of Nereid. Magnetite in particular provides a good match to the spectral continuum without requiring the presence of Tholin-like organics. We note that carbonaceous chondrites and their components may be useful analogs for the non-ice components of outer solar system bodies, consistent with recent findings by Fraser et al. (2019). Comparison to spectra of large TNOs and satellites of Uranus show that Nereid's low albedo, deep water bands, and neutral color is distinct from many other icy objects, but such comparisons are limited by incomplete understanding of spectral variability among $\sim$100km-sized icy bodies., Comment: 11 pages, 2 tables, 7 figures, accepted in PSJ

Published

2021

5. Same family, different neighborhoods: Visible near-infrared (0.7–2.45 μm) spectral distinctions of D-type asteroids at different heliocentric distances

Author

Matthew R. M. Izawa, Paul S. Hardersen, Matt Nowinski, and Gordon M. Gartrelle

Subjects

Physics, Solar System, education.field_of_study, 010504 meteorology & atmospheric sciences, Population, Astronomy and Astrophysics, Astrophysics, 01 natural sciences, Spectral line, VNIR, Jupiter, Space and Planetary Science, Asteroid, Trojan, 0103 physical sciences, Principal component analysis, education, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

D-type asteroids represent a complex mystery related to the accretional history, composition, and dynamical migration of Outer Solar System objects. These spectrally featureless bodies have revealed few clues while raising many questions over four decades. D-types are dark, difficult to observe and perhaps contain unaltered primordial material. D-type asteroids are abundant in the outer belt, dominant in the Jupiter Trojans, and rare in the inner belt as well as near Earth space. Material spectrally similar to D-types is pervasive on other outer solar system bodies as well. The appearance of dark, spectrally red material in multiple classes of small bodies suggests some unknown geochemical and/or evolutionary connection(s) may exist between them. Our investigation focused on the visible near-infrared (VNIR) (0.7–2.45 μm) spectral distinctions of D-types based on heliocentric location. Twenty-five newly acquired spectra from NASA's Infrared Telescope Facility (IRTF) plus sixty-one IRTF VNIR spectra from the literature were combined into a single database and extensively analyzed with multiple orbital, observational, and spectral variables included in the examination. Twelve of the newly acquired spectra had not been imaged previously at IRTF. Pearson's correlation, simple and multiple regression, slope analysis, Monte Carlo modeling, as well as Principal Component Analysis (PCA) determined D-types show increased reddening with decreasing distance, with the segment from 1.5–2.45 μm, driving the overall trend for the full slope. Principal components show strong connection to the 0.7–1.35 μm slope and inclination of D-type Jupiter Trojans. Principal component combinations, magnitudes, and positive/negative direction relate strongly to both observed and derived differences in the D-type L4 and L5 Trojan population. The L5 population is less evolved spectrally and dynamically than L4 counterparts perhaps due to lower dynamical instabilities inside the L4 cloud.

Published

2021

6. Round up the unusual suspects: Near-Earth Asteroid 17274 (2000 LC16) a plausible D-type parent body of the Tagish Lake meteorite

Author

Paul S. Hardersen, Matthew R. M. Izawa, Matt Nowinski, and Gordon M. Gartrelle

Subjects

Near-Earth object, 010504 meteorology & atmospheric sciences, Meteoroid, Astronomy and Astrophysics, 01 natural sciences, Parent body, Astrobiology, Meteorite, Space and Planetary Science, Chondrite, Asteroid, 0103 physical sciences, Asteroid belt, Amor asteroid, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Asteroids are the origin point for most meteorites impacting Earth. Terrestrial meteorite samples provide evidence of what actually occurred in the early solar system at the formation location of the meteorite, and when it occurred. The ability to connect a meteorite sample to an asteroid parent body provides its starting location as a meteoroid. To date, only a handful of chondritic meteorite types have been credibly connected to an asteroid parent. For the past two decades, D-type asteroids, a dark, spectrally reddish, and featureless taxonomic type have been speculated to be the parent body of the tiny family of ungrouped chondrites. These include the Tagish Lake Meteorite (TLM), a ~ 4 m meteorite “fall” in Canada's Yukon territory recovered in 2000. The quest to identify the TLM parent has been a baffling one as D-type asteroids are dominant among the Jovian Trojans, rare in main asteroid belt, and extremely rare in the inner asteroid belt as well as Near-Earth space. This study employed Near Infrared (NIR) spectra (0.7–2.45 μm) of 86 D-types and a variety of analysis techniques including visual analysis, slope analysis, curve fitting, Frechet analysis, dynamical analysis and Shkuratov radiative transfer theory to search for the TLM parent body. Sixteen TLM samples from the NASA Reflectance Experiment Laboratory (RELAB) plus five additional mineralogically well-constrained samples measured using X-ray diffraction (XRD) and Rietveld refinement were compared to D-type asteroid spectra. Our results indicate, out of several promising candidates, Near-Earth asteroid 17274 (2006 LC16), a ~ 3 km diameter Amor asteroid is a plausible parent body for TLM.

Published

2021

7. Compositional Constraints for Lucy Mission Trojan Asteroids via Near-Infrared Spectroscopy

Author

Benjamin N. L. Sharkey, Joshua P. Emery, Vishnu Reddy, Matthew R. M. Izawa, and Juan A. Sanchez

Subjects

Physics, Earth and Planetary Astrophysics (astro-ph.EP), Solar System, 010504 meteorology & atmospheric sciences, Near-infrared spectroscopy, Astronomy, FOS: Physical sciences, Astronomy and Astrophysics, Object (computer science), 01 natural sciences, Space and Planetary Science, Asteroid, Trojan, 0103 physical sciences, Space Science, Spectroscopy, 010303 astronomy & astrophysics, Astrophysics - Earth and Planetary Astrophysics, 0105 earth and related environmental sciences

Abstract

We report near-infrared (0.7-2.5 micron) reflectance spectra for each of the six target asteroids of the forthcoming NASA Discovery-class mission Lucy. Five Jupiter Trojans (the binary (617) Patroclus system, (3548) Eurybates, (21900) Orus, (11351) Leucus, and (15094) Polymele) are well-characterized, with measurable spectral differences. We also report a survey-quality spectrum for main belt asteroid (52246) Donaldjohanson. We measured a continuum of spectral slopes including "red" (Orus, Leucus), "less red" (Eurybates, Patroclus-Menoetius) and intermediate (Polymele), indicating a range of compositional end-members or geological histories. We perform radiative transfer modeling of several possible surface compositions. We find that the mild-sloped spectra and low albedo of Patroclus and Eurybates imply similar compositions. Eurybates (~7 wt.% water ice) and Patroclus (~4 wt.% water ice) are consistent with a hydrated surface. Models for Orus and Leucus are consistent with each other and require a significantly more reddening agent (e.g. iron-rich silicates or tholin-like organics). Polymele has a linear spectrum like Patroclus, but a higher albedo more closely aligned with Orus/Leucus, defying simple grouping. Solar system formation models generally predict that the Jovian Trojans accreted in the outer solar system. Our observations and analysis are generally consistent with this expectation, although not uniquely so., Comment: Accepted by AJ. 10 Figures, 5 Tables

Published

2019

8. Salt – A critical material to consider when exploring the solar system

Author

Pierre Vernazza, W. A. McCutcheon, Penelope L. King, Jeff A. Berger, Matthew R. M. Izawa, Laboratoire d'Astrophysique de Marseille (LAM), Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Aix Marseille Université (AMU)-Centre National d'Études Spatiales [Toulouse] (CNES), and Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Solar System, Materials science, 010504 meteorology & atmospheric sciences, engineering.material, 01 natural sciences, Astrobiology, Chondrite, 0103 physical sciences, 010303 astronomy & astrophysics, Mid-infrared spectroscopy, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences, Spectral signature, Astronomy and Astrophysics, Mars Exploration Program, Regolith, Asteroids, Meteorite, [SDU]Sciences of the Universe [physics], 13. Climate action, Space and Planetary Science, Asteroid, Enstatite, engineering, Salts, Chondrites

Abstract

Salt-rich deposits may be more widespread on planetary surfaces than is generally appreciated. Remote observations, laboratory studies of meteorites, and cosmochemical constraints all point towards widespread occurrences of salts (including halides, sulfates, and (bi)carbonates) on asteroids, icy bodies, Mars, and elsewhere. We have investigated the mid-infrared (1.8–25 μm) reflectance spectral properties of mixtures of chondritic (ordinary, enstatite and carbonaceous) meteorites with potassium bromide; a mid-infrared transmissive salt like all halides. Our results demonstrate that halide-chondrite mixtures provide spectral signatures that either reveal the presence of transmissive materials or provide evidence for highly porous regolith. Previously, the nature of the surfaces of the asteroids 624 Hektor and 21 Lutetia was inferred using a limited range of spectra from halide-chondrite mixtures. Here, we provide an extensive dataset of halide-chondrite mixtures to encompass a wider set of possible surface compositions.

Published

2021

9. Illuminating the dark side of the asteroid population: Visible near-infrared (0.7–2.45 μm) surface mineralogy modeling of D-type asteroids using Shkuratov theory

Author

Matt Nowinski, Gordon M. Gartrelle, Paul S. Hardersen, and Matthew R. M. Izawa

Subjects

Solar System, education.field_of_study, Olivine, 010504 meteorology & atmospheric sciences, Population, Astronomy and Astrophysics, Tholin, engineering.material, 01 natural sciences, Astrobiology, Meteorite, Space and Planetary Science, Asteroid, 0103 physical sciences, engineering, Radiative transfer, Asteroid belt, education, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

D-type asteroids are a prime example of the many dark, low-albedo asteroids which do not reflect sufficient light to reveal detectable mineral absorptions. While D-type asteroids are relatively rare in the inner solar system and the main asteroid belt, they are dominant among the Jovian Trojans. In this study, we have applied Shkuratov radiative transfer modeling to laboratory spectra of meteorites for which mineral abundances have been measured using X-ray diffraction (XRD) and Rietveld refinement. The general agreement of radiative transfer and XRD estimates of mineral abundances demonstrates the applicability of the radiative transfer approach to featureless, low-albedo spectra. Shkuratov modeling was then applied to new spectral observations of D-type asteroids, along with numerous previously published spectra. The surface mineral abundances of 81 D-type objects, including NASA's Lucy Mission target (21900) Orus, were modeled using assemblages that are plausible based on meteorite analogues. Modeling results reveal D-types are composed of: low-iron olivine; magnesium saponite-dominant phyllosilicates; opaques such as pyrrhotite and tholin; as well as traces of water-ice and other constituents. Subtle compositional differences in model mineralogies exist between Trojan and non-Trojan D-types as well as between L4 and L5 Trojans suggesting differing formational as well as evolutional conditions have affected these bodies.

Published

2021

10. Mineralogical Criteria for the Parent Asteroid of the “Carbonaceous” Achondrite NWA 6704.

Author

Allison M. McGraw, Vishnu Reddy, Matthew R. M. Izawa, Juan A. Sanchez, Lucille Le Corre, Edward A. Cloutis, Daniel M. Applin, and Neil Pearson

Published

2020

11. SURFACE ALBEDO AND SPECTRAL VARIABILITY OF CERES.

Author

Jian-Yang Li (李荐扬), Vishnu Reddy, Andreas Nathues, Lucille Le Corre, Matthew R. M. Izawa, Edward A. Cloutis, Mark V. Sykes, Uri Carsenty, Julie C. Castillo-Rogez, Martin Hoffmann, Ralf Jaumann, Katrin Krohn, Stefano Mottola, Thomas H. Prettyman, Michael Schaefer, Paul Schenk, Stefan E. Schröder, David A. Williams, David E. Smith, and Maria T. Zuber

Published

2016