Your search keyword '"Lauretta, Dante S"' showing total 26 results

1. Bennu Shape Model Validation Methods and Results

Author

Lauretta, Dante S, Seabrook, Jeff A, Daly, Michael G, Barnouin, Olivier S, Velez, Dianna, Rush, Brian, Mastrodemos, Nikolaos, Kennedy, Brian M, Bellerose, Julie, and Lubey, Daniel P

Abstract

The OSIRIS-REx Independent Shape Modeling Team, staffed by the Jet Propulsion Laboratory (JPL), has used stereophotoclinometry (SPC) to produce a three-dimensional shape model of Bennu. The SPC process is informed by (but is separate from) orbit determination, so it is important to ensure that the resulting shape model is consistent with all available spacecraft tracking data. Specifically, checking the shape model’s consistency with LIDAR measurements can illuminate any discrepancies, because LIDAR measurements are highly correlated with the shape model. This study focuses on the JPL experience with these LIDAR measurements and the greater context of the shape model validation process.

Published

2020

2. Bennu Shape Model Validation Methods and Results

Author

Lubey, Daniel P, Bellerose, Julie, Kennedy, Brian M, Mastrodemos, Nikolaos, Rush, Brian, Velez, Dianna, Barnouin, Olivier S, Daly, Michael G, Seabrook, Jeff A, and Lauretta, Dante S

Published

2020

3. Osiris-Rex Shape Model Performance During the Navigation Campaign

Author

Leonard, Jason M, Geeraert, Jeroen L, Page, Brian R, French, Andrew S, Ashman, Benjamin W, Antreasian, Peter G, Adam, Coralie, Lessac-Chenen, Erik, Mcarthy, Leilah, Nelson, Derek, Pelgrift, John, Sahr, Eric, Liounis, Andrew, Palmer, Eric, Weirich, John R, Kennedy, Brian M, Mastrodemos, Nickolaos, Bellerose, Julie, Lubey, Daniel, Rush, Brian, Velez, Dianna, Moreau, Michael C, Barnouin, Olivier, and Lauretta, Dante S

Published

2020

4. Osiris-Rex Shape Model Performance During the Navigation Campaign

Author

Leonard, Jason M, Geeraert, Jeroen L, Page, Brian R, French, Andrew S, Ashman, Benjamin W, Antreasian, Peter G, Adam, Coralie, Lessac-Chenen, Erik, Mcarthy, Leilah, Nelson, Derek, Pelgrift, John, Sahr, Eric, Liounis, Andrew, Palmer, Eric, Weirich, John R, Kennedy, Brian M, Mastrodemos, Nickolaos, Bellerose, Julie, Lubey, Daniel, Rush, Brian, Velez, Dianna, Moreau, Michael C, Barnouin, Olivier, and Lauretta, Dante S

Abstract

The Navigation Campaign of the OSIRIS-REx mission began when the first image of Bennu was recorded by the PolyCam high-resolution imager on Au-gust 17, 2018. In the ensuing months, two teams began building shape models based on imagery taken during the Approach and Preliminary survey phases to be used for the transition to landmark navigation in the Orbital A phase. The orbit determination team began analyzing and characterizing the performance and errors associated with each shape model delivery working closely to iterate on the next shape model delivery. By the end of Orbital A, shape models produced by the Altimetry Working Group and JPL exceeded pre-launch performance re-quirements. This paper provides a summary of the analysis performed during operations.

Published

2020

5. Revisiting OSIRIS-REx Touch-And-Go (TAG) Performance Given the Realities of Asteroid Bennu

Author

Berry, Kevin, Getzandanner, Kenneth, Moreau, Michael C, Antreasian, Peter G, Polit, Anjani T, Enos, Heather L, Lauretta, Dante S, and Nolan, Michael

Subjects

Space Sciences (General)

Abstract

The Origins, Spectral Interpretation, Resource Identification, and Security–Regolith Explorer (OSIRIS-REx) mission is a NASA New Frontiers mission that launched in 2016 and rendezvoused with the near-Earth asteroid (101955) Bennu in late 2018. Upon arrival, the surface of Bennu was found to be much rockier than expected. The original Touch-and-Go (TAG) requirement for sample collection was to deliver the spacecraft to a site with a 25-meter radius; however, the largest hazard-free sites are no larger than 8 meters in radius. To accommodate the dearth of safe sample collection sites, the project reevaluated all aspects of flight system performance pertaining to TAG in order to account for the demonstrated performance of the spacecraft and navigation prediction accuracies. More-over, the project has base lined on board natural feature tracking instead of lidar for providing the on board navigation state update during the TAG sequence. This paper summarizes the improvements in error source estimation, enhancements in on board trajectory correction, and results of recent Monte Carlo simulation to en-able sample collection with the given constraints. TAG delivery and on board navigation performance are presented for the final four candidate TAG sites.

Published

2020

6. OSIRIS-REx Precision Orbit Determination

Author

Leonard, Jason M, Geeraert, Jeroen L, Antreasian, Peter G, Jackman, Coralie D, Wibben, Daniel, French, Andrew, Page, Brian, Moreau, Michael C, and Lauretta, Dante S

Subjects

Space Transportation And Safety

Published

2019

7. Serendipitous Geodesy from Bennu's Short-Lived Moonlets

Author

Mazarico, Erwan, Goossens, Sander, Rowlands, David D, Getzandanner, Kenneth M, Liounis, Andrew J, Leonard, Jason M, Swenson, Jason C, Highsmith, Dolan E, Moreau, Michael C, Sabaka, Terence J, Lyzhoft, Joshua R, Ashman, Benjamin W, Small, Jeff, Hergenrother, Carl, McMahon, Jay, Chesley, Steven R, Scheeres, Daniel J, and Lauretta, Dante S

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Origins, Spectral Interpretation, Resource Identification, and Security-Regolith Explorer (OSIRIS-REx; or OREx) spacecraft arrived at its target, near-Earth asteroid (101955) Bennu, on December 3, 2018. The OSIRIS-REx spacecraft has since collected a wealth of scientific information in order to select a suitable site for sampling. Shortly after insertion into orbit on December 31, 2018, particles were identified in starfield images taken by the navigation camera (NavCam 1). Several groups within the OSlRlS-REx team analyzed the particle data in an effort to better understand this newfound activity of Bennu and to investigate the potential sensitivity of the particles to Bennu's geophysical parameters. A number of particles were identified through automatic and manual methods in multiple images, which could be turned into short sequences of optical tracking observations. Here, we discuss the precision orbit determination (OD) effort focused on these particles at NASA GSFC, which involved members of the Independent Navigation Team (INT) in particular. The particle data are combined with other OSIRIS-REx tracking data (radiometric from OSN and optical landmark data) using the NASA GSFC GEODYN orbit determination and geodetic parameter estimation software. We present the results of our study, particularly those pertaining to the gravity field of Bennu. We describe the force modeling improvements made to GEODYN specifically for this work, e.g., with a raytracing-based modeling of solar radiation pressure. The short-lived, low-flying moonlets enable us to determine a gravity field model up to a relatively high degree and order: at least degree 6 without constraints, and up to degree 10 when applying Kaula-like regularization. We can backward- and forward-integrate the trajectory of these particles to the ejection and landing sites on Bennu. We assess the recovered field by its impact on the OSIRIS-REx trajectory reconstruction and prediction quality in the various mission phases (e.g., Orbital A, Detailed Survey, and Orbital B).

Published

2019

8. Transition from Centroid-Based to Landmark-Based Optical Navigation During OSIRIS-REx Navigation Campaign at Asteroid Bennu

Author

Adam, Coralie D, McCarthy, Leilah K, Sahr, Eric M, Nelson, Derek S, Pelgrift, John Y, Lessac-Chenen, Erik J, Leonard, Jason M, Antreasian, Peter G, Palmer, Eric E, Weirich, John R, Gaskell, Robert W, Barnouin, Olivier S, Moreau, Michael C, and Lauretta, Dante S

Subjects

Space Communications, Spacecraft Communications, Command And Tracking, Lunar And Planetary Science And Exploration

Published

2019

9. Template Matching Used for Small Body Optical Navigation with Poorly Detailed Objects

Author

Lyzhoft, Joshua R, Liounis, Andrew J, and Lauretta, Dante S

Subjects

Computer Programming And Software, Instrumentation And Photography

Abstract

Object and template matching becomes difficult when an image lacks detail. This is particularly worrisome when typical matching techniques, cross-correlation, log-polar mapping, and key point matching fail. Work herein describes a formulation that identifies objects of interest, estimates the affine transformation between a template object and scene using Principal Component Analysis (PCA), and provides a fit value for the objects and template incorporating Hu's Moments. The algorithm presented is tested on synthetic images and images obtained from the OSIRIS-REx mission while the spacecraft was approaching its target, Bennu. Results for the current formulation show that, with the presence of large-scale variations and rotation, the fitting scheme performs well when compared with other techniques.

Published

2019

10. The Image Constraint Measurement Type for Orbit Determination & Geophysical Parameter Estimation

Author

Getzandanner, Kenneth M, Leonard, Jason, Liounis, Andrew, Mazarico, Erwan, Rowlands, David, Adam, Coralie, Antreasian, Peter, Ashman, Benjamin, and Lauretta, Dante S

Subjects

Earth Resources And Remote Sensing

Published

2019

11. Independent Optical Navigation Processing for the Osiris-Rex Mission Using the Goddard Image Analysis and Navigation Tool

Author

Liounis, Andrew, Swenson, Jason, Small, Jeffrey, Lyzhoft, Josh, Ashman, Benjamin, Getzandanner, Kenneth, Highsmith, Dolan, Moreau, Michael, Adam, Coralie, Antreasian, Peter, and Lauretta, Dante S

Subjects

Spacecraft Instrumentation And Astrionics

Abstract

The OSIRIS-REx mission to the asteroid(101955) Bennu heavily relies on optical navigation to provide relative state information between the asteroid and the spacecraft. These measurements enable determination of the spacecraft's orbit to the tight requirements needed to meet the science goals of the mission. In this document we describe the algorithms and techniques used by the Goddard independent verification and validation navigation effort to extract these measurements from the images taken by the spacecraft during the mission.We also demonstrate the capabilities of the techniques by showing the high accuracy of the results when used in an orbit determination solution.

Published

2019

12. A Novel Surface Feature Navigation Algorithm Using Ray Tracing

Author

Gnam, Chris, Liounis, Andrew, Ashman, Benjamin, Getzandanner, Kenneth, Lyzhoft, Joshua, Small, Jeffrey, Highsmith, Dolan, Adam, Coralie, Leonard, Jason, Antreasian, Peter, and Lauretta, Dante S

Subjects

Space Communications, Spacecraft Communications, Command And Tracking

Abstract

We demonstrate a novel single-bounce ray tracing approach to landmark identification for surface feature-based relative navigation. A priori knowledge of the camera pose and known topographic maps for each landmark are used to render the potentially visible landmarks via ray tracing into the image frame. These templates are registered with a search region around the predicted location for each landmark in the image, to locate its observed center. This procedure is applied to images from the OSIRIS-REx Orbital A and Orbital B mission phases, and the results are compared with those obtained via previous landmark identification methods.

Published

2019

13. Successful Use of Microporous Polytetrafluoroethylene Flexible Thin Sheets in NASA's OSIRIS-REx Mission

Author

Choi, Michael K, Bos, Brent J, Tveekrem, June L, D'aubigny, Christian, Rizk, Bashar, and Lauretta, Dante S

Subjects

Spacecraft Design, Testing And Performance

Abstract

Microporous black polytetrafluoroethylene (PTFE) flexible thin sheets are successfully flown as solar diffusers on NASA's Origins, Spectral Interpretation, Resource Identification, and Security-Regolith Explorer (OSIRIS-REx) spacecraft. They serve as multilayer insulation (MLI) blanket outer covers for the arm of the Touch And Go Sample Acquisition Mechanism (TAGSAM), the sunshade of the OSIRIS-REx Camera Suite (OCAMS) PolyCam imager, and the motor riser of the OCAMS SamCam imager. Additionally, microporous white PTFE flexible thin sheets are successfully flown as a MLI blanket outer cover with a low ratio of absorptance to emittance for the Regolith X-ray Imaging Spectrometer (REXIS). For ground testing, microporous black and white PTFE flexible thin sheets were successfully used as optical targets of the Touch And Go Camera System (TAGCAMS) NavCam imagers in the flight system thermal vacuum test.

Published

2019

14. OSIRIS-REx Orbit Determination Performance During the Navigation Campaign

Author

Leonard, Jason M, Geeraert, Jeroen L, Page, Brian R, French, Andrew S, Antreasian, Peter G, Adam, Coralie D, Wibben, Daniel R, Moreau, Michael C, and Lauretta, Dante S

Subjects

Space Processing

Abstract

The OSIRIS-REx mission Navigation Campaign consists of three sub-phases: Approach,Preliminary Survey, and Orbital A. Approach was designed for initial characterization ofBennu while matching Bennu's heliocentric velocity. Preliminary Survey provided the firstspacecraft-based estimate of Bennu's mass. This phase consisted of five target flybys witha close approach distance of about 7 km. Orbital A was a two-month phase devoted to theNavigation Team learning the close proximity operations dynamics and environment aroundBennu and transitioning from center-finding optical navigation to landmark feature-basednavigation. This paper provides a detailed summary of the orbit determination performancethroughout the Navigation Campaign.

Published

2019

15. OSIRIS-REx Encounters Bennu: Initial Assessment from the Approach Phase

Author

Lauretta, Dante S, Barnouin, Olivier S, Becker, Kris, Bennett, Carina A, Bierhaus, Beau, Boynton, William V, Burke, Keara N, Christensen, Philip R, Clark, Beth, Jr, Harold C. Connolly, Crombie, Mary, Daly, Michael G, DellaGiustina, Daniella N, Dworkin, Jason P, Emery, Joshua P, Enos, Heather L, Golish, Dathon R, Hamilton, Victoria E, Hergenrother, Carl, Corre, Lucille Le, Lim, Lucy F, Michel, Patrick, Nolan, Michael C, Pajola, Maurizio, Perry, Mark E, Reuter, Dennis, Rizk, Bashar, Scheeres, Daniel Jay, Schwartz, Stephen R, Simon, Amy A, and Walsh, Kevin John

Subjects

Astronomy

Abstract

The OSIRIS-REx spacecraft launched on September 8, 2016, on a seven-year journey to return samples from asteroid (101955) Bennu. This presentation summarizes the scientific results from the Approach and Preliminary Survey phases. Bennu observations are set to begin on August 17, 2018,when the asteroid is bright enough for detection by the PolyCam. PolyCam and MapCam collect data to survey the asteroid environment for any hazards and characterize the asteroid point-source photometric properties. Resolved images acquired during final approach, starting in late October 2018, allow the creation of a shape model using stereophotoclinometry (SPC), needed by both the navigation team and science planners. The OVIRS and OTES spectrometers characterize the point- source spectral properties over a full rotation period, providing a first look at any features and thermophysical properties. TAGSAM is released from the launch container and deployed into the sampling configuration then returned to the stow position.Preliminary Survey follows the Approach Phase in early December 2018. This phase consists of a series of hyperbolic trajectories that cross over the North and South poles and the equator of Bennu at a close-approach distance of 7 km. Images from these Preliminary Survey passes provide data to complete the 75-cm resolution SPC global shape model and solve for the rotation state. Once the shape model is complete, the asteroid coordinate system is defined for co-registration of all data products. These higher-resolution images also constrain the photometric properties and allow for an initial assessment of the geology. In Preliminary Survey the team also obtains the first OLA data, providing a measure of the surface topography. OVIRS and OTES collect data as "ride-along" instruments, with the spacecraft pointing driven by imaging constraints. These data provide a first look at the spectral variation across the surface of Bennu. Radio science measurements, combined with altimetry and imagery, determine Bennu's mass, a prerequisite to placing the spacecraft into orbit in late December 2018. Together, data from the Approach and Preliminary Survey phases set the stage for the extensive mapping planned for 2019. These dates are the baseline plan. Any contingency or unexpected discovery may change this mission profile.

Published

2018

16. In-Flight Calibration and Performance of the OSIRIS-REx Visible and IR Spectrometer (OVIRS)

Author

Simon, Amy A, Reuter, Dennis C, Gorius, Nicolas, Lunsford, Allen W, Cosentino, Richard, Wind, Galina, and Lauretta, Dante S

Subjects

Instrumentation And Photography

Abstract

Performance of the Origins, Spectral Interpretation, Resource Identification, Security-Regolith Explorer (OSIRIS-REx) Visible and InfraRed Spectrometer (OVIRS) instrument was validated, showing that it met all science requirements during extensive thermal vacuum ground testing. Preliminary instrument radiometric calibration coefficients and wavelength mapping were also determined before instrument delivery and launch using NIST-traceable sources. One year after launch, Earth flyby data were used to refine the wavelength map by comparing OVIRS spectra with atmospheric models. Near-simultaneous data from other Earth-orbiting satellites were used to cross-calibrate the OVIRS absolute radiometric response, particularly at visible wavelengths. Trending data from internal calibration sources and the Sun show that instrument radiometric performance has been stable to better than 1% in the 18 months since launch.

Published

2018

17. Application of Machine-Learning Algorithms for On-Board Asteroid Shape Model Determination

Author

Lauretta, Dante S

Subjects

Computer Programming And Software

Abstract

The Application of Machine-learning Algorithms for On-board Asteroid Shape Model Determination project will develop an innovative system for spacecraft navigation to expand the capability of small spacecraft to meet the critical challenges associated with small-body exploration. Such challenges include accurate navigation in a microgravity environment and precision targeting of particular locations on an asteroid surface for sample collection. This on-board system will cut the computational "umbilical" back to Earth-currently necessary for the generation of a global shape model that requires thousands of images with sufficient resolution and adequate variation of incidence and emission angles, processed manually by a team of experts on Earth for several months. Small satellites have limited bandwidth and are unable to downlink the data volume required for this processing, restricting their ability to perform deep-space asteroid exploration.

Published

2018

18. Osiris-REx Spacecraft Current Status and Forward Plans

Author

Messenger, Scott, Lauretta, Dante S, and Connolly, Harold C., Jr

Subjects

Lunar And Planetary Science And Exploration, Spacecraft Instrumentation And Astrionics

Abstract

The NASA New Frontiers OSIRIS-REx spacecraft executed a flawless launch on September 8, 2016 to begin its 23-month journey to near-Earth asteroid (101955). The primary objective of the OSIRIS-REx mission is to collect and return to Earth a pristine sample of regolith from the asteroid surface. The sampling event will occur after a two-year period of remote sensing that will ensure a high probability of successful sampling of a region on the asteroid surface having high science value and within well-defined geological context. The OSIRIS-REx instrument payload includes three high-resolution cameras (OCAMS), a visible and near-infrared spectrometer (OVIRS), a thermal imaging spectrometer (OTES), an X-ray imaging spectrometer (REXIS), and a laser altimeter (OLA). As the spacecraft follows its nominal outbound-cruise trajectory, the propulsion, power, communications, and science instruments have undergone basic functional tests, with no major issues. Outbound cruise science investigations include a search for Earth Trojan asteroids as the spacecraft approaches the Sun-Earth L4 Lagrangian point in February 2017. Additional instrument checkouts and calibrations will be carried out during the Earth gravity assist maneuver in September 2017. During the Earth-moon flyby, visual and spectral images will be acquired to validate instrument command sequences planned for Bennu remote sensing. The asteroid Bennu remote sensing campaign will yield high resolution maps of the temperature and thermal inertia, distributions of major minerals and concentrations of organic matter across the asteroid surface. A high resolution 3d shape model including local surface slopes and a high-resolution gravity field will also be determined. Together, these data will be used to generate four separate maps that will be used to select the sampling site(s). The Safety map will identify hazardous and safe operational regions on the asteroid surface. The Deliverability map will quantify the accuracy with which the navigation team can deliver the spacecraft to and from specific sites on the asteroid surface. The Sampleability map quantifies the regolith properties, providing an estimation of how much material would be sampled at different points on the surface. The final Science Value map synthesizes the chemical, mineralogical, and geological, observations to identify the areas of the asteroid surface with the highest science value. Here, priority is given to organic, water-rich regions that have been minimally altered by surface processes. Asteroid surface samples will be acquired with a touch-and-go sample acquisition system (TAGSAM) that uses high purity pressurized N2 gas to mobilize regolith into a stainless steel canister. Although the mission requirement is to collect at least 60 g of material, tests of the TAGSAM routinely exceeded 300 g of simulant in micro-gravity tests. After acquiring the sample, the spacecraft will depart Bennu in 2021 to begin its return journey, with the sample return capsule landing at the Utah Test and Training Range on September 23, 2023. The OSIRIS-REx science team will carry out a series of detailed chemical, mineralogical, isotopic, and spectral studies that will be used to determine the origin and history of Bennu and to relate high spatial resolution sample studies to the global geological context from remote sensing. The outline of the sample analysis plan is described in a companion abstract.

Published

2017

19. OSIRIS-REx Asterod Sample Return Mission

Author

Nakamura-Messinger, Keiki, Connolly, Harold C. Jr, Messenger, Scott, and Lauretta, Dante S

Subjects

Exobiology, Lunar And Planetary Science And Exploration

Abstract

OSIRIS-REx is NASA's third New Frontiers Program mission, following New Horizons that completed a flyby of Pluto in 2015 and the Juno mission to Jupiter that has just begun science operations. The OSIRIS-REx mission's primary objective is to collect pristine surface samples of a carbonaceous asteroid and return to Earth for analysis. Carbonaceous asteroids and comets are 'primitive' bodies that preserved remnants of the Solar System starting materials and through their study scientists can learn about the origin and the earliest evolution of the Solar System. The OSIRIS-REx spacecraft was successfully launched on September 8, 2016, beginning its seven year journey to asteroid 101955 Bennu. The robotic arm will collect 60-2000 grams of material from the surface of Bennu and will return to Earth in 2023 for worldwide distribution by the Astromaterials Curation Facility at NASA Johnson Space Center. The name OSIRIS-REx embodies the mission objectives (1) Origins: Return and analyze a sample of a carbonaceous asteroid, (2) Spectral Interpretation: Provide ground-truth for remote observation of asteroids, (3) Resource Identification: Determine the mineral and chemical makeup of a near-Earth asteroid (4) Security: Measure the non-gravitational that changes asteroidal orbits and (5) Regolith Explorer: Determine the properties of the material covering an asteroid surface. Asteroid Bennu may preserve remnants of stardust, interstellar materials and the first solids to form in the Solar System and the molecular precursors to the origin of life and the Earth's oceans. Bennu is a potentially hazardous asteroid, with an approximately 1 in 2700 chance of impacting the Earth late in the 22nd century. OSIRIS-REx collects from Bennu will help formulate the types of operations and identify mission activities that astronauts will perform during their expeditions. Such information is crucial in preparing for humanity's next steps beyond low Earthy orbit and on to deep space destinations.

Published

2017

20. The ISIS Mission Concept: An Impactor for Surface and Interior Science

Author

Chesley, Steven R, Elliot, John O, Abell, Paul A, Asphaug, Erik, Bhaskaran, Shyam, Lam, Try, and Lauretta, Dante S

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Impactor for Surface and Interior Science (ISIS) mission concept is a kinetic asteroid impactor mission to the target of NASA's OSIRIS-REx (Origins-Spectral Interpretation-Resource Identification-Security-Regolith Explorer) asteroid sample return mission. The ISIS mission concept calls for the ISIS spacecraft, an independent and autonomous smart impactor, to guide itself to a hyper-velocity impact with 1999 RQ36 while the OSIRIS-REx spacecraft observes the collision. Later the OSIRIS-REx spacecraft descends to reconnoiter the impact site and measure the momentum imparted to the asteroid through the impact before departing on its journey back to Earth. In this paper we discuss the planetary science, human exploration and impact mitigation drivers for mission, and we describe the current mission concept and flight system design.

Published

2013

21. The ISIS mission concept : an impactor for surface and interior science

Author

Chesley, Steven R, Elliot, John O, Abell, Paul A, Asphaug, Erik, Bhaskaran, Shyam, Lam, Try, and Lauretta, Dante S

Published

2013

22. Asteroid (101955) 1999 RQ36: Spectroscopy from 0.4 to 2.4 Micrometer and Meteorite Analogs

Author

Clark, Beth Ellen, Binzel, Richard P, Howell, Ellen S, Cloutis, Edward A, Ockert-Bell, Maureen, Christensen, Phil, Barucci, Maria Antonietta, DeMeo, Francesca, Lauretta, Dante S, Connolly, Harold, Jr, Soderberg, Alicia, Hergenrother, Carl, Lim, Lucy, Emery, Josh, and Mueller, Michael

Subjects

Lunar And Planetary Science And Exploration

Abstract

We present reflectance spectra from 0.4 to 2.4 ?m of Asteroid (101955) 1999 RQ36, the target of the OSIRIS-REx spacecraft mission. The visible spectral data were obtained at the McDonald Observatory 2.1-m telescope with the ES2 spectrograph. The infrared spectral data were obtained at the NASA Infrared Telescope Facility using the SpeX instrument. The average visible spectrum is combined with the average near-infrared wavelength spectrum to form a composite spectrum. We use three methods to constrain the compositional information in the composite spectrum of Asteroid (101955) 1999 RQ36 (hereafter RQ36). First, we perform a least-squares search for meteorite spectral analogs using 15,000 spectra from the RELAB database. Three most likely meteorite analogs are proposed based on the least-squares search. Next, six spectral parameters are measured for RQ36 and their values are compared with the ranges in parameter values of the carbonaceous chondrite meteorite classes. A most likely meteorite analog group is proposed based on the depth of overlap in parameter values. The results of the least-squares search and the parametric comparisons point to CIs and/or CMs as the most likely meteorite analogs for RQ36, and COs and CHs as the least likely. RQ36 has a spectrally blue continuum slope that is also observed in carbonaceous chondrites containing magnetite. We speculate that RQ36 is composed of a CM1 -like material. Finally, we compare RQ36 to other B-type asteroids measured by Clark et al. (Clark, B.E. et al. [2010]. J. Geophys. Res. 115, E06005). The results of this comparison are inconclusive. RQ36 is comparable to Themis spectral properties in terms of its albedo, visible spectrum, and near-infrared spectrum from 1.1 to 1.45 micrometers. However, RQ36 is more similar to Pallas in terms of its near-infrared spectrum from 1.6 to 2.3 micrometers. Thus it is possible that B-type asteroids form a spectral continuum and that RQ36 is a transitional object, spectrally intermediate between the two end-members. This is particularly interesting because Asteroid 24 Themis was recently discovered to have H2O ice on the surface (Rivkin, A., Emery, J. [2010]. Nature 464, 1322 1323; Campins, H. et al. [2010a]. Nature 464, 1320 1321).

Published

2011

23. A Radical Pathway for Organic Phosphorylation during Schreibersite Corrosion with Implications for the Origin of Life

Author

Pasek, Matthew A, Dworkin, Jason P, and Lauretta, Dante S

Subjects

Inorganic, Organic And Physical Chemistry

Abstract

Phosphorylated compounds (e.g. DNA, RNA, phospholipids, and many coenzymes) are critical to biochemistry. Thus, their origin is of prime interest to origin of life studies. The corrosion of the meteoritic mineral schreibersite ((Fe,Ni)3P) may have significantly contributed to the origin of phosphorylated biomolecules. Corrosion of synthetic schreibersite in a variety of solutions was analyzed by nuclear magnetic resonance spectroscopy, mass spectrometry, and electron paramagnetic resonance spectroscopy. These methods suggest a radical reaction pathway for the corrosion of schreibersite to form phosphite radicals (raised dot PO3 sup 2-)) aqueous solution. These radicals can form activated polyphosphates and can phosphorylate organic compounds such as acetate (3% yield). Phosphonates (O3P-C) are found in the organic P inventory of the carbonaceous meteorite Murchison. While phosphonates are rare in biochemistry, the ubiquity of corroding iron meteorites on the early Earth could have provided an accessible source of organophosphorous for the origin of life allowing the invention of the organophosphates in modern biology as a product of early evolution.

Published

2007

24. Supernova olivine from cometary dust

Author

Messenger, Scott, Keller, Lindsay P, and Lauretta, Dante S

Subjects

Lunar And Planetary Science And Exploration

Abstract

An interplanetary dust particle contains a submicrometer crystalline silicate aggregate of probable supernova origin. The grain has a pronounced enrichment in 18O/16O (13 times the solar value) and depletions in 17O/16O (one-third solar) and 29Si/28Si (<0.8 times solar), indicative of formation from a type II supernova. The aggregate contains olivine (forsterite 83) grains <100 nanometers in size, with microstructures that are consistent with minimal thermal alteration. This unusually iron-rich olivine grain could have formed by equilibrium condensation from cooling supernova ejecta if several different nucleosynthetic zones mixed in the proper proportions. The supernova grain is also partially encased in nitrogen-15-rich organic matter that likely formed in a presolar cold molecular cloud.

Published

2005

25. Opaque Mineral Assemblages at Chondrule Boundaries in the Vigarano CV Chondrite: Evidence for Gas-Solid Reactions Following Chondrule Formation

Author

Lauretta, Dante S

Subjects

Geophysics

Abstract

Recent studies of opaque minerals in primitive ordinary chondrites suggest that metal grains exposed at chondrule boundaries were corroded when volatile elements recondensed after the transient heating event responsible for chondrule formation. Metal grains at chondrule boundaries in the Bishunpur (LL3.1) chondrite are rimmed by troilite and fayalite. If these layers formed by gas solid reaction, then the composition of the corrosion products can provide information on the chondrule formation environment. Given the broad similarities among chondrules from different chondrite groups, similar scale layers should occur on chondrules in other primitive meteorite groups. Here I report on metal grains at chondrule boundaries in Vigarano (CV3).

Published

2004

26. An Experimental Investigation of Fe-Si Alloy Corrosion in the Solar Nebula

Author

Zega, Thomas J, Lauretta, Dante S, and Buseck, Peter R

Subjects

Lunar And Planetary Science And Exploration

Abstract

We have performed an experimental study of Fe-Si alloy corrosion under dust-rich nebular conditions. The reaction products are silica and fayalite. Additional information is contained in the original extended abstract.

Published

2001