TY - JOUR
T1 - Compositional distributions and evolutionary processes for the near-Earth object population
T2 - Results from the MIT-Hawaii Near-Earth Object Spectroscopic Survey (MITHNEOS)
AU - Binzel, R. P.
AU - DeMeo, F. E.
AU - Turtelboom, E. V.
AU - Bus, S. J.
AU - Tokunaga, A.
AU - Burbine, T. H.
AU - Lantz, C.
AU - Polishook, D.
AU - Carry, B.
AU - Morbidelli, A.
AU - Birlan, M.
AU - Vernazza, P.
AU - Burt, B. J.
AU - Moskovitz, N.
AU - Slivan, S. M.
AU - Thomas, C. A.
AU - Rivkin, A. S.
AU - Hicks, M. D.
AU - Dunn, T.
AU - Reddy, V.
AU - Sanchez, J. A.
AU - Granvik, M.
AU - Kohout, T.
N1 - Funding Information:
Part of the data utilized in this publication were obtained and made available by the MIT-UH-IRTF Joint Campaign for NEO Reconnaissance. The IRTF is operated by the University of Hawaii under Cooperative Agreement no. NCC 5-538 with the National Aeronautics and Space Administration, Office of Space Science, Planetary Astronomy Program. This project was made possible by the outstanding support from the IRTF staff and telescope operators. This paper includes data gathered with the 6.5 m Magellan telescopes located at Las Campanas Observatory, Chile. MIT researchers performing this work were supported by NASA grant 09-NEOO009-0001, and by the National Science Foundation under Grants nos. 0506716 and 0907766. D. Polishook received postdoctoral support at MIT under an AXA Research Fellowship. M. Granvik acknowledges funding from the Academy of Finland (grant 299543). Taxonomic type results presented in this work were determined, in whole or in part, using a Bus-DeMeo Taxonomy Classification Web tool by Stephen M. Slivan, developed at MIT with the support of National Science Foundation Grant 0506716 and NASA Grant NAG5-12355. Over the many years of this project we have benefited from insightful discussions from many colleagues who have further motivated and focused our observational program and science objectives. These individuals include Bill Bottke, Andy Cheng, Beth Clark, Marco Delbo, Alan W. Harris, Alan W. Harris; in that order, Alison Klesman, Amy Mainzer, Joe Masiero, Lucy McFadden, Jessica Sunshine, David Nesvorný, and many more.
Funding Information:
Part of the data utilized in this publication were obtained and made available by the MIT-UH-IRTF Joint Campaign for NEO Reconnaissance. The IRTF is operated by the University of Hawaii under Cooperative Agreement no. NCC 5-538 with the National Aeronautics and Space Administration, Office of Space Science, Planetary Astronomy Program. This project was made possible by the outstanding support from the IRTF staff and telescope operators. This paper includes data gathered with the 6.5 m Magellan telescopes located at Las Campanas Observatory, Chile. MIT researchers performing this work were supported by NASA grant 09-NEOO009-0001 , and by the National Science Foundation under Grants nos. 0506716 and 0907766 . D. Polishook received postdoctoral support at MIT under an AXA Research Fellowship. M. Granvik acknowledges funding from the Academy of Finland (grant 299543 ). Taxonomic type results presented in this work were determined, in whole or in part, using a Bus-DeMeo Taxonomy Classification Web tool by Stephen M. Slivan, developed at MIT with the support of National Science Foundation Grant 0506716 and NASA Grant NAG5-12355 . Over the many years of this project we have benefited from insightful discussions from many colleagues who have further motivated and focused our observational program and science objectives. These individuals include Bill Bottke, Andy Cheng, Beth Clark, Marco Delbo, Alan W. Harris, Alan W. Harris; in that order, Alison Klesman, Amy Mainzer, Joe Masiero, Lucy McFadden, Jessica Sunshine, David Nesvorný, and many more.
Publisher Copyright:
© 2018 Elsevier Inc.
PY - 2019/5/15
Y1 - 2019/5/15
N2 - Advancing technology in near-infrared instrumentation and dedicated planetary telescope facilities have enabled nearly two decades of reconnoitering the spectral properties for near-Earth objects (NEOs). We report measured spectral properties for more than 1000 NEOs, representing >5% of the currently discovered population. Thermal flux detected below 2.5 µm allows us to make albedo estimates for nearly 50 objects, including two comets. Additional spectral data are reported for more than 350 Mars-crossing asteroids. Most of these measurements were achieved through a collaboration between researchers at the Massachusetts Institute of Technology and the University of Hawaii, with full cooperation of the NASA Infrared Telescope Facility (IRTF) on Mauna Kea. We call this project the MIT-Hawaii Near-Earth Object Spectroscopic Survey (MITHNEOS; myth-neos). While MITHNEOS has continuously released all spectral data for immediate use by the scientific community, our objectives for this paper are to: (1) detail the methods and limits of the survey data, (2) formally present a compilation of results including their taxonomic classification within a single internally consistent framework, (3) perform a preliminary analysis on the overall population characteristics with a concentration toward deducing key physical processes and identifying their source region for escaping the main belt. Augmenting our newly published measurements are the previously published results from the broad NEO community, including many results graciously shared by colleagues prior to formal publication. With this collective data set, we find the near-Earth population matches the diversity of the main-belt, with all main-belt taxonomic classes represented in our sample. Potentially hazardous asteroids (PHAs) as well as the subset of mission accessible asteroids (ΔV ≤ 7 km/s) both appear to be a representative mix of the overall NEO population, consistent with strong dynamical mixing for the population that interacts most closely with Earth. Mars crossers, however, are less diverse and appear to more closely match the inner belt population from where they have more recently diffused. The fractional distributions of major taxonomic classes (60% S, 20% C, 20% other) appear remarkably constant over two orders of magnitude in size (10 km to 100 m), which is eight orders of magnitude in mass, though we note unaccounted bias effects enter into our statistics below about 500 m. Given the range of surface ages, including possible refreshment by planetary encounters, we are able to identify a very specific space weathering vector tracing the transition from Q- to Sq- to S-types that follows the natural dispersion for asteroid spectra mapped into principal component space. We also are able to interpret a shock darkening vector that may account for some objects having featureless spectra. Space weathering effects for C-types are complex; these results are described separately by Lantz, Binzel, DeMeo. (2018, Icarus 302, 10–17). Independent correlation of dynamical models with taxonomic classes map the escape zones for NEOs to main-belt regions consistent with well established heliocentric compositional gradients. We push beyond taxonomy to interpret our visible plus near-infrared spectra in terms of the olivine and pyroxene mineralogy consistent with the H, L, and LL classes of ordinary chondrites meteorites. Correlating meteorite interpretations with dynamical escape region models shows a preference for LL chondrites to arrive from the ν6 resonance and H chondrites to have a preferential signature from the mid-belt region (3:1 resonance). L chondrites show some preference toward the outer belt, but not at a significant level. We define a Space Weathering Parameter as a continuous variable and find evidence for step-wise changes in space weathering properties across different planet crossing zones in the inner solar system. Overall we hypothesize the relative roles of planetary encounters, YORP spin-up, and thermal cycling across the inner solar system.
AB - Advancing technology in near-infrared instrumentation and dedicated planetary telescope facilities have enabled nearly two decades of reconnoitering the spectral properties for near-Earth objects (NEOs). We report measured spectral properties for more than 1000 NEOs, representing >5% of the currently discovered population. Thermal flux detected below 2.5 µm allows us to make albedo estimates for nearly 50 objects, including two comets. Additional spectral data are reported for more than 350 Mars-crossing asteroids. Most of these measurements were achieved through a collaboration between researchers at the Massachusetts Institute of Technology and the University of Hawaii, with full cooperation of the NASA Infrared Telescope Facility (IRTF) on Mauna Kea. We call this project the MIT-Hawaii Near-Earth Object Spectroscopic Survey (MITHNEOS; myth-neos). While MITHNEOS has continuously released all spectral data for immediate use by the scientific community, our objectives for this paper are to: (1) detail the methods and limits of the survey data, (2) formally present a compilation of results including their taxonomic classification within a single internally consistent framework, (3) perform a preliminary analysis on the overall population characteristics with a concentration toward deducing key physical processes and identifying their source region for escaping the main belt. Augmenting our newly published measurements are the previously published results from the broad NEO community, including many results graciously shared by colleagues prior to formal publication. With this collective data set, we find the near-Earth population matches the diversity of the main-belt, with all main-belt taxonomic classes represented in our sample. Potentially hazardous asteroids (PHAs) as well as the subset of mission accessible asteroids (ΔV ≤ 7 km/s) both appear to be a representative mix of the overall NEO population, consistent with strong dynamical mixing for the population that interacts most closely with Earth. Mars crossers, however, are less diverse and appear to more closely match the inner belt population from where they have more recently diffused. The fractional distributions of major taxonomic classes (60% S, 20% C, 20% other) appear remarkably constant over two orders of magnitude in size (10 km to 100 m), which is eight orders of magnitude in mass, though we note unaccounted bias effects enter into our statistics below about 500 m. Given the range of surface ages, including possible refreshment by planetary encounters, we are able to identify a very specific space weathering vector tracing the transition from Q- to Sq- to S-types that follows the natural dispersion for asteroid spectra mapped into principal component space. We also are able to interpret a shock darkening vector that may account for some objects having featureless spectra. Space weathering effects for C-types are complex; these results are described separately by Lantz, Binzel, DeMeo. (2018, Icarus 302, 10–17). Independent correlation of dynamical models with taxonomic classes map the escape zones for NEOs to main-belt regions consistent with well established heliocentric compositional gradients. We push beyond taxonomy to interpret our visible plus near-infrared spectra in terms of the olivine and pyroxene mineralogy consistent with the H, L, and LL classes of ordinary chondrites meteorites. Correlating meteorite interpretations with dynamical escape region models shows a preference for LL chondrites to arrive from the ν6 resonance and H chondrites to have a preferential signature from the mid-belt region (3:1 resonance). L chondrites show some preference toward the outer belt, but not at a significant level. We define a Space Weathering Parameter as a continuous variable and find evidence for step-wise changes in space weathering properties across different planet crossing zones in the inner solar system. Overall we hypothesize the relative roles of planetary encounters, YORP spin-up, and thermal cycling across the inner solar system.
UR - http://www.scopus.com/inward/record.url?scp=85063063365&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85063063365&partnerID=8YFLogxK
U2 - 10.1016/j.icarus.2018.12.035
DO - 10.1016/j.icarus.2018.12.035
M3 - Article
AN - SCOPUS:85063063365
SN - 0019-1035
VL - 324
SP - 41
EP - 76
JO - Icarus
JF - Icarus
ER -