Inner Workings: Networks of Cameras Are Tracking Meteorites With

Total Page:16

File Type:pdf, Size:1020Kb

Inner Workings: Networks of Cameras Are Tracking Meteorites With INNER WORKINGS INNER WORKINGS Networks of cameras are tracking meteorites with unprecedented precision Danielle Venton, Science Writer Around the globe, networks of camera lenses are which asteroids or near-earth region of space from trained upward. They scan the night skies, aiming to which the rocks emanate. Those participating in these catch streaks of bright light: meteorites as they fall to networks are photographing, tracking, and hunting Earth. Searching for these space rocks is not new. down meteorites. But the precision and resolution with which increasingly The DFN consists of 52 autonomous digital cam- expansive networks of Earth-bound cameras are track- eras placed in the hot, dry Nullarbor desert, with an- ing meteorites is starting to offer insights into both other dozen cameras scattered in multiple countries. where these bodies go and where they came from. Waterproof containers help the cameras survive the For astronomers, catching sight of a meteor is Australian outback; inbuilt fans keep the cameras cool more than a stroke of luck. It represents a potentially through the day. The project is a collaboration be- valuable research sample that has fallen to Earth. tween Imperial College London, Ondrejov Observa- “These are samples of heavenly bodies reaching us tory in the Czech Republic, Curtin University in Western decades before we might actually go there,” says Australia, and the Western Australian Museum. Phil Bland, planetary scientist at Curtin University To help achieve a high-resolution view of the skies, and director of the Desert Fireball Network (DFN) the network also enlists citizen scientists. According to in Australia. His network is one of several high-tech the project’s website, more than 26,000 people in attempts to track and gather meteorites in the 88 countries have downloaded the app “Fireballs in hopes of understanding their origins, frequency, the Sky.” Users point their phones to the place in the and composition. sky where they saw a fireball start, tap to start the trail, trace the path until the point in the sky where they saw Eyes on the Sky the fireball disappear, and tap again. Options allow Bland and others want to map out the paths of space users to “fine-tune” the appearance of the fireball, its rocks by determining precise orbits, and gleaning brightness, duration, shape, and color, and to note Networks of cameras are trained on the skies in hopes of gathering meteorite samples—from events such as the Perseid Meteor Shower shown here—that can help researchers understand the rocks’ origins, frequency, and composition. Image courtesy of NASA/JPL. 7472–7474 | PNAS | July 18, 2017 | vol. 114 | no. 29 www.pnas.org/cgi/doi/10.1073/pnas.1709062114 Downloaded by guest on September 27, 2021 Cameras such as this one (Left), located in Fowlers Gap in New South Wales Australia, help astronomers track and retrieve meteorites such as this one (Right), which researchers found in Kati Thanda–Lake Eyre in Australia. Image courtesy of Desert Fireball Network. whether they heard a sonic boom. The DFN team uses the camera network detected them in Cassiopeia. By the information to track where the rock may have early September, the meteors were radiating from come from and may have fallen to Earth. If a sighting is the constellation Camelopardalis. These showers are corroborated by multiple users, researchers check to captured in a stunning visualization on the SETI web- confirm the reports. If the DFN team receives enough site (see www.seti.org/warped-meteor-shower-hits-earth- information, they let users know where the rock they at-all-angles). sighted originated in the solar system. Already, the creation of meteor shower maps, built Other meteor-spotting networks opt for a different upon the observations from networks like CAMS and emphasis. Some, like Bland’s, are meant to spot and DFN, has helped astronomers make predictions about help scientists recover fallen meteorites. Others, such when meteor showers will occur. Tracking and fore- as the Cameras for Allsky Meteor Survey (CAMS), cu- casting meteor impacts helps ensure the safety of rated by Peter Jenniskens of the Search for Extrater- spacecraft and astronauts (3). restrial Intelligence (SETI) Institute and sponsored by That tracking can also, potentially, have real con- NASA, focus on searches for new meteor showers and sequences on the ground. In 2013, the Chelyabinsk trace them to their original orbits. The network’s meteor hit Russia, causing the hospitalization of more 263 cameras are positioned in California in the United than a thousand people (4). Jenniskens traveled to the States, as well as Belgium, the Netherlands, the site in the months after the impact to participate in a United Arab Emirates, and several other nations. Russian Academy of Science field study of the mete- Nearly 5-years-old, the CAMS network has pro- orite’s impact. When the meteor whizzed by, glass vided the first overview of which meteor streams hit didn’t just shatter, observers told him, it turned into the Earth throughout the year. The network has also spray. They didn’t just feel the ground shake, they discovered more than 100 new showers, with more were knocked off their feet. waiting to be confirmed (1). “It’s basically video sur- The fact that a rock only 20 meters in diameter veillance of the night sky,” says Jenniskens. “You film could cause so much damage was a shock to many the meteors that appear and you do that from two or astronomers. Generally, smaller rocks weren’tcon- more sites, triangulate the track, and determine from sidered a problem. Meteors of this size are pretty where the meteors are coming and at what speed.” common, Jenniskens says, and hit the planet fairly frequently, every 40 years or so. [Chelyabinsk could Space Rock, Data Packet have suffered more damage if the meteor had en- Big strides have been made in the field in recent years. tered at a steeper angle and had not fractured into “When I was an amateur [astronomer] 20 years ago, small pieces (5).] looking at the night sky, there was really no un- However, meteors can be far smaller than the one at derstanding of what was going on,” Jenniskens says, Chelyabinsk, or a breadbox, or a tube of lipstick, and recalling his use of pen and paper to plot the tracks still cause trouble, especially for anyone in space. At with star charts. Low-light video cameras have been a NASA’s Meteoroid Environments Office at the Marshall boon for observers, he says. Space Flight Center in Huntsville, Alabama, established Surprising findings from CAMS suggest that me- in 2004, the mission is more safety than science ori- teor showers can shift; the point in the sky that they ented. Its aim: to generate meteor shower forecasts for radiate from can change. The well-known Perseid the International Space Station and other spacecraft: shower, for example, radiates from the constellation of “So they know when to batten down the hatches,” says Perseus during the meteor showers’ mid-August peak office director Bill Cooke. The minute objects he is (2). But when the meteors first appear in early July, concerned with are more common that those meteorites Venton PNAS | July 18, 2017 | vol. 114 | no. 29 | 7473 Downloaded by guest on September 27, 2021 strewn across the atmosphere, and more likely to cause automated method for estimating the mass and origin of trouble for space station astronauts. bright fireballs detected with the digital cameras that are The NASA All Sky Fireball Network, started by the part of the Desert Fireball Observatories (8). Her method NASA Meteoroid Environment Office, consists of effectively updates the standard way of using equations 15 cameras, set up in schools, science centers, plan- of flight through the atmosphere to calculate mass as a etariums, and observatories. Most of the cameras are result of deceleration (with brightness used as a kind of in the Southern and Eastern United States. Six are in proxy for the fireball’s starting mass). the area surrounding Huntsville. Four are in the Traditionally, these interpretations would be based northern Ohio and Pennsylvania area. The rest are in on a series of photographic plates and calculated southern New Mexico and Arizona. by hand (9). Instead, her system continually updates The office also collaborates with the University the flight equations, using data captured by the of Western Ontario in Canada, which operates the cameras to estimate the fireball’s distance traveled, mass, and velocity. Finding the rock on the ground is then essentially a matter of triangulation. When they’re “We can use a probabilistic model to roll back those lucky the researchers can actually retrieve it. So far orbits further back in time so we can see where an they’ve recovered 4 rocks and know where to look for ” about another 15. The researchers are finding they have object originated from in the main belt. “ — about a 33% success rate, which Bland says is alot Phil Bland better than anyone has managed before,” although he sees plenty of potential for improvement. ’ Canadian Meteor Orbit Radar, now in its second iter- Estimating the rock s origin entails, in essence, “ ation. The Canadian Meteor Orbit Radar can see par- projecting into the past. We can use a probabilistic ticles down to a 10th of a millimeter and spots between model to roll back those orbits further back in time so 4,000 and 5,000 individual meteoroid orbits daily. we can see where an object originated from in the main belt,” says Bland. “Did it come from the inner- Fireball Cartographers most part of the belt? Did it come from a specific Direct sampling of comets and asteroids is likely to resonance, where it got thrown out into the inner solar happen in the coming years.
Recommended publications
  • NASA Ames Jim Arnold, Craig Burkhardt Et Al
    The re-entry of artificial meteoroid WT1190F AIAA SciTech 2016 1/5/2016 2008 TC3 Impact October 7, 2008 Mohammad Odeh International Astronomical Center, Abu Dhabi Peter Jenniskens SETI Institute Asteroid Threat Assessment Project (ATAP) - NASA Ames Jim Arnold, Craig Burkhardt et al. Michael Aftosmis - NASA Ames 2 Darrel Robertson - NASA Ames Next TC3 Consortium http://impact.seti.org Mission Statement: Steve Larson (Catalina Sky Survey) “Be prepared for the next 2008 TC3 John Tonry (ATLAS) impact” José Luis Galache (Minor Planet Center) Focus on two aspects: Steve Chesley (NASA JPL) 1. Airborne observations of the reentry Alan Fitzsimmons (Queen’s Univ. Belfast) 2. Rapid recovery of meteorites Eileen Ryan (Magdalena Ridge Obs.) Franck Marchis (SETI Institute) Ron Dantowitz (Clay Center Observatory) Jay Grinstead (NASA Ames Res. Cent.) Peter Jenniskens (SETI Institute - POC) You? 5 NASA/JPL “Sentry” early alert October 3, 2015: WT1190F Davide Farnocchia (NASA/JPL) Catalina Sky Survey: Richard Kowalski Steve Chesley (NASA/JPL) Marco Michelli (ESA NEOO CC) 6 WT1190F Found: October 3, 2015: one more passage Oct. 24 Traced back to: 2013, 2012, 2011, …, 2009 Re-entry: Friday November 13, 2015 10.61 km/s 20.6º angle Bill Gray 11 IAC + UAE Space Agency chartered commercial G450 Mohammad Odeh (IAC, Abu Dhabi) Support: UAE Space Agency Dexter Southfield /Embry-Riddle AU 14 ESA/University Stuttgart 15 SETI Institute 16 Dexter Southfield team Time UAE Camera Trans-Lunar Insertion Stage Leading candidate (1/13/2016): LUNAR PROSPECTOR T.L.I.S. Launch: January 7, 1998 UT Lunar Prospector itself was deliberately crashed on Moon July 31, 1999 Carbon fiber composite Spin hull thrusters Titanium case holds Amonium Thiokol Perchlorate fuel and Star Stage 3700S HTPB binder (both contain H) P.I.: Alan Binder Scott Hubbard 57-minutes later: Mission Director Separation of TLIS NASA Ames http://impact.seti.org 30 .
    [Show full text]
  • Radar-Enabled Recovery of the Sutter's Mill Meteorite, A
    RESEARCH ARTICLES the area (2). One meteorite fell at Sutter’sMill (SM), the gold discovery site that initiated the California Gold Rush. Two months after the fall, Radar-Enabled Recovery of the Sutter’s SM find numbers were assigned to the 77 me- teorites listed in table S3 (3), with a total mass of 943 g. The biggest meteorite is 205 g. Mill Meteorite, a Carbonaceous This is a tiny fraction of the pre-atmospheric mass, based on the kinetic energy derived from Chondrite Regolith Breccia infrasound records. Eyewitnesses reported hearing aloudboomfollowedbyadeeprumble.Infra- Peter Jenniskens,1,2* Marc D. Fries,3 Qing-Zhu Yin,4 Michael Zolensky,5 Alexander N. Krot,6 sound signals (table S2A) at stations I57US and 2 2 7 8 8,9 Scott A. Sandford, Derek Sears, Robert Beauford, Denton S. Ebel, Jon M. Friedrich, I56US of the International Monitoring System 6 4 4 10 Kazuhide Nagashima, Josh Wimpenny, Akane Yamakawa, Kunihiko Nishiizumi, (4), located ~770 and ~1080 km from the source, 11 12 10 13 Yasunori Hamajima, Marc W. Caffee, Kees C. Welten, Matthias Laubenstein, are consistent with stratospherically ducted ar- 14,15 14 14,15 16 Andrew M. Davis, Steven B. Simon, Philipp R. Heck, Edward D. Young, rivals (5). The combined average periods of all 17 18 18 19 20 Issaku E. Kohl, Mark H. Thiemens, Morgan H. Nunn, Takashi Mikouchi, Kenji Hagiya, phase-aligned stacked waveforms at each station 21 22 22 22 23 Kazumasa Ohsumi, Thomas A. Cahill, Jonathan A. Lawton, David Barnes, Andrew Steele, of 7.6 s correspond to a mean source energy of 24 4 24 2 25 Pierre Rochette, Kenneth L.
    [Show full text]
  • Career Pages of Astronomer Dr. Peter Jenniskens Peter Jenniskens, Ph.D
    10/8/2014 Career pages of astronomer Dr. Peter Jenniskens Peter Jenniskens, Ph.D. Meteor astronomer Carl Sagan Center, The SETI Institute. E-mail: Petrus.M.Jenniskens [at] nasa.gov, Tel: 1 (650) 810 0216; Fax: 1 (650) 962 9419 Last update: December 08, 2008; List of Publications Curriculum vitae Astronomer Dr. Peter Jenniskens [Portrait (3.2 Mbyte)] is a Research Scientist with the Carl Sagan Center at the SETI Institute and works on mission projects at NASA/Ames Research Center in Moffett Field, California, and on research topics that relate to interstellar and interplanetary matter. Research Interests: Meteor showers - Jenniskens is an expert on meteor showers, and is known for identifying the parent body of the Quadrantid shower: a minor planet called 2003 EH1. Main belt asteroid 1999 TY224 was named (42981) "Jenniskens". He is the Principal Investigator of ASIMA - the Asteroid Impact Analyzer, a proposed satellite mission (2014-2016) to measure the carbon content of meteors from space and study the diversity of comets and asteroids. He predicted the return of the unusual Aurigid shower from dust ejected around 4 AD by long-period comet Kiess on September 1, 2007, and was the Principal Investigator of the Aurigid Multi-Instrument Aircraft Campaign (Aurigid MAC), an airborne mission that deployed from NASA Ames to study this meteor outburst. This was followed by a study of dust ejected by comet 8P/Tuttle (Ursid MAC) in December 2007, and a mission in January 2008 to study the Quadrantid meteor shower for clues to its date of origin (Quadrantid MAC). Before that, Jenniskens was the Principal Investigator of NASA's first Astrobiology mission, Leonid MAC, an airborne campaign to explore the 1998 - 2002 Leonid storms and study meteoroids and their paths from extra-terrestrial to terrestrial matter.
    [Show full text]
  • The 1999 Leonid Multi.Instrument Aircraft Campaign - an Early Review
    THE 1999 LEONID MULTI.INSTRUMENT AIRCRAFT CAMPAIGN - AN EARLY REVIEW PETER JENNISKENS _, STEVEN J. BUTOW _, AND MARK FONDA NASA Ames Research Center, Mai_ Stop 239-4, Moffett Field, CA 94035-1000 I with SETI Institute E.mail: [email protected] (Received 10 July 2000; Accepted 15August 2000) Abstract. The Leonid meteor storm of 1999 was observed from two B707-type research aircraft by a team of 35 scientists of seven nationalities over the Mediterranean Sea on Nov. 18, 1999. The mission was sponsored by various science programs of NASA, and offered the best possible observing conditions, free of clouds and at a prime location for viewing the storm. The 1999 mission followed a similar effort in 1998, improving upon mission strategy and scope. As before, spectroscopic and imaging experiments targeted meteors and persistent trains, but also airglow, aurora, elves and sprites. The research aimed to address outstanding questions in Planetary Science, Astronomy, Astrobiology and upper atmospheric research, including Aeronomie. In addition, near real-time flux measurements contributed to a USAF sponsored program for space weather awareness. An overview of the first results is given, which are discussed in preparation for future missions. Keywords: Airborne astronomy, astrobiology, chemistry, comets, composition, elves, exobiology, instrumental techniques, Leonid MAC, Leonids 1999, lower thermosphere, meteoroids, meteor storm, meteors, mesosphere, orbital dynamics, satellite impact hazard, sprites 1. Introduction The widely anticipated return of the Leonid shower in November of 1999 offered our best chance yet to observe a meteor storm with modern techniques. Just prior to the last year's campaign, E.A.
    [Show full text]
  • 2008 TC3: the Small Asteroid with an Impact
    Meteoritics & Planetary Science 45, Nr 10–11, 1553–1556 (2010) doi: 10.1111/j.1945-5100.2010.01156.x Introduction 2008 TC3: The small asteroid with an impact The story is now familiar: On October 6, 2008, THE IMPACT OF 2008 TC3 ON METEORITICS & Richard Kowalski at the Catalina Sky Survey in PLANETARY SCIENCE Arizona spotted a small 3 m sized asteroid, now named 2008 TC3. It was soon discovered that, 20 h later, this And what an asteroid it was! The research asteroid was to impact Earth. Steve Chesley of presented here sheds new light on the smelting process NASA ⁄ JPL calculated an impact location in the Nubian recognized in the ureilites. The cooling rates calculated desert of northern Sudan. In the hours before impact, from the quenching of the smelting implied that a astronomers measured the light curve of the rare protoplanet broke in 10–100 m sized fragments tumbling asteroid and a reflectance spectrum, describing following a giant collision. Those fragments were later its shape and taxonomic type. This was the first time that ground down into the tiny pieces found in 2008 TC3, an asteroid was studied in space before hitting the Earth. presumably in subsequent collisions. The final fragments In the predawn hour of October 7, satellites gathered in loosely welded together assemblages of recorded the fireball west of Station 6, putting the main small millimeter and sub-millimeter sized fragments, )20 magnitude detonation at a high 37 km altitude. The with much pore space in between. Other fragments of impact happened around the time of morning prayer.
    [Show full text]
  • Primefocus Tri-Valley Stargazers January 2016
    PRIMEFOCUS Tri-Valley Stargazers January 2016 January Meeting The History and Science of Lick Observatory Dr. Paul Lynam Lick Observatory, wholly owned and operated by the University of California, was the first astronomical observatory purpose-built at alti- tude. It demonstrated the practicality of large- scale glass substrate reflecting telescopes for research. It was the fulcrum upon which the United States pivoted to dominance in obser- Meeting Info vational astronomy at the close of the 19th What: century and the dawn 20th. This presentation The History and Science of Lick offers a little known history of James Lick, what Observatory motivated him to establish Lick Observatory and the processes and people that lead to the Who: establishment of what was for decades the Dr. Paul Lynam world’s foremost astronomical observatory, When: located in the county of Santa Clara. Even prior January 15, 2016 to completion, Lick Observatory was making Doors open at 7:00 p.m. important discoveries, developing technolo- Meeting at 7:30 p.m. gies and setting standards. It continues to train Caption: 3-meter Shane Telescope Lecture at 8:00 p.m. generations of scientists and inspire the wider at Lick Observatory. Credit: Ken public --- a role it has fulfilled for over 100 Sperber Where: years. Lick remains at the forefront of scientific Unitarian Universalist and technological advances, annually enabling over 200 Californian astronomers Church in Livermore to undertake and publish front line, cutting-edge research. Lick continues to pio- 1893 N. Vasco Road neer and has much more work to do. Some outstanding contributions from Lick’s history and current work shall be highlighted, as well as some prospects for the future.
    [Show full text]
  • Inner Workings: Networks of Cameras Are Tracking Meteorites With
    INNER WORKINGS INNER WORKINGS Networks of cameras are tracking meteorites with unprecedented precision Danielle Venton, Science Writer Around the globe, networks of camera lenses are which asteroids or near-earth region of space from trained upward. They scan the night skies, aiming to which the rocks emanate. Those participating in these catch streaks of bright light: meteorites as they fall to networks are photographing, tracking, and hunting Earth. Searching for these space rocks is not new. down meteorites. But the precision and resolution with which increasingly The DFN consists of 52 autonomous digital cam- expansive networks of Earth-bound cameras are track- eras placed in the hot, dry Nullarbor desert, with an- ing meteorites is starting to offer insights into both other dozen cameras scattered in multiple countries. where these bodies go and where they came from. Waterproof containers help the cameras survive the For astronomers, catching sight of a meteor is Australian outback; inbuilt fans keep the cameras cool more than a stroke of luck. It represents a potentially through the day. The project is a collaboration be- valuable research sample that has fallen to Earth. tween Imperial College London, Ondrejov Observa- “These are samples of heavenly bodies reaching us tory in the Czech Republic, Curtin University in Western decades before we might actually go there,” says Australia, and the Western Australian Museum. Phil Bland, planetary scientist at Curtin University To help achieve a high-resolution view of the skies, and director of the Desert Fireball Network (DFN) the network also enlists citizen scientists. According to in Australia. His network is one of several high-tech the project’s website, more than 26,000 people in attempts to track and gather meteorites in the 88 countries have downloaded the app “Fireballs in hopes of understanding their origins, frequency, the Sky.” Users point their phones to the place in the and composition.
    [Show full text]
  • 7 X 11 Long.P65
    Cambridge University Press 978-0-521-85349-1 - Meteor Showers and their Parent Comets Peter Jenniskens Frontmatter More information Meteor Showers and Their Parent Comets It is only in the past ten years that advanced computing techniques and painstaking observations have enabled the successful prediction and observation of meteor storms. Spectacular displays of ‘‘shooting stars’’ are created when the Earth crosses a meteoroid stream, causing the meteoroids to light up into meteors as they enter our atmosphere. Meteor Showers and Their Parent Comets is a unique handbook for astronomers interested in observing meteor storms and outbursts. The author, a leading astro- nomer in the field and an active meteor storm chaser, explains how meteoroid streams originate from the decay of comets (and asteroids) and how they evolve into ever changing orbits by the gravitational pull of planets to cause meteor showers on Earth. He includes the findings of recent space missions that have visited comets and asteroids, the risk of meteoroid impacts on Earth, what showers to expect on other planets, and how meteor showers may have seeded the Earth with the ingredients that made life possible. All known meteor showers are identified, accompanied by fascinating details on the most important showers and their parent comets. The book predicts when exceptional meteor showers will occur over the next 50 years, making it a valuable resource for both amateur and professional astronomers. Astronomer P ETER J ENNISKENS completed his Ph.D. at Leiden University, the Netherlands, in 1992. He then worked as a National Research Council Associate at the Exobiology branch of the NASA Ames Research Center in Moffett Field, California, where he uncovered exotic properties of astrophysical ices, such as those in comets.
    [Show full text]
  • Annexe I : Description Des Services D’Observations Labellisés Liés À La Planétologie
    Annexe I : description des services d’observations labellisés liés à la planétologie Consultation BDD Service des éphémérides Type AA-ANO1 Coordination Intitulé OSU Directeur de l'OSU Responsable du SNO Email du responsable du SNO IMCCE Jacques LASKAR Jacques LASKAR [email protected] Partenaires Intitulé OSU Directeur de l'OSU Resp. du SNO dans l'OSU Email du resp. du SNO dans l'OSU Obs. Paris Claude CATALA OCA Thierry LANZ Agnès FIENGA [email protected] Description L'IMCCE a la responsabilité, sous l'égide du Bureau des longitudes, de produire et de diffuser les calendriers et éphémérides au niveau national. Cette fonction est assurée l'institut par son Service des éphémérides. Aussi celui-ci a) produit les publications et éditions annuelles tout comme les éphémérides en ligne, b) diffuse les éphémérides de divers corps du système solaire - naturels et artificiels, et de phénomènes célestes, c) assure la maintenance et la mise jour des bases de données, d) procure une expertise juridique aux tribunaux, e) procure des éphémérides et données la demande pour les services similaires (USA, Japon), les agences, les chercheurs, les laboratoires et les observatoires. Consultation BDD Gaia Type AA-ANO1, AA-ANO4 Coordination Intitulé OSU Directeur de l'OSU Responsable du SNO Email du responsable du SNO OCA Thierry LANZ François MIGNARD [email protected] Partenaires Intitulé OSU Directeur de l'OSU Resp. du SNO dans l'OSU Email du resp. du SNO dans l'OSU Obs. Paris Claude CATALA Frédéric ARENOU [email protected] IMCCE Jacques LASKAR Daniel HESTROFFER [email protected] OASU Marie Lise DUBERNET-TUCKEY Caroline SOUBIRAN [email protected] THETA Philippe ROUSSELOT Annie ROBIN [email protected] IAP Francis BERNARDEAU Brigitte ROCCA VOLMERANGE [email protected] ObAS Pierre-Alain DUC Jean-Louis HALBWACHS [email protected] Description Participation aux activités du Consortium DPAC (Data Processing and Analysis Consortium) pour la mission Gaia.
    [Show full text]
  • Radar-Enabled Recovery of the Sutter's Mill Meteorite, a Carbonaceous Chondrite Regolith Breccia RESEARCHARTICLES
    RESEARCH ARTICLES the area (2). One meteorite fell at Sutter’s Mill (SM), the gold discovery site that initiated the California Gold Rush. Two months after the fall, Radar-Enabled Recovery of the Sutter’s SM find numbers were assigned to the 77 me- teorites listed in table S3 (3), with a total mass of 943 g. The biggest meteorite is 205 g. Mill Meteorite, a Carbonaceous This is a tiny fraction of the pre-atmospheric mass, based on the kinetic energy derived from Chondrite Regolith Breccia infrasound records. Eyewitnesses reported hearing a loud boom followed by a deep rumble. Infra- 1,2 3 4 5 6 Peter Jenniskens, * Marc D. Fries, Qing-Zhu Yin, Michael Zolensky, Alexander N. Krot, sound signals (table S2A) at stations I57US and 2 2 7 8 8,9 Scott A. Sandford, Derek Sears, Robert Beauford, Denton S. Ebel, Jon M. Friedrich, I56US of the International Monitoring System 6 4 4 10 Kazuhide Nagashima, Josh Wimpenny, Akane Yamakawa, Kunihiko Nishiizumi, (4), located ~770 and ~1080 km from the source, 11 12 10 13 Yasunori Hamajima, Marc W. Caffee, Kees C. Welten, Matthias Laubenstein, are consistent with stratospherically ducted ar- 14,15 14 14,15 16 Andrew M. Davis, Steven B. Simon, Philipp R. Heck, Edward D. Young, rivals (5). The combined average periods of all 17 18 18 19 20 Issaku E. Kohl, Mark H. Thiemens, Morgan H. Nunn, Takashi Mikouchi, Kenji Hagiya, phase-aligned stacked waveforms at each station 21 22 22 22 23 Kazumasa Ohsumi, Thomas A. Cahill, Jonathan A. Lawton, David Barnes, Andrew Steele, of 7.6 s correspond to a mean source energy of 24 4 24 2 25 Pierre Rochette, Kenneth L.
    [Show full text]
  • Dr. PETER JENNISKENS 2019 Jenniskens, P., Popova, O. P
    Dr. PETER JENNISKENS 2019 Jenniskens, P., Popova, O. P., Glazachev, D. O., Podobnaya, E. D., Kartashova, A. P., 2019. Tunguska eyewitness accounts, injuries, and casualties. Icarus (in press) [#204]. Jenniskens, P., 2019. Review of asteroid-family and meteorite-type links. In: A century of asteroid families. J. Masseido, ed., IAU Transactions (in press) [#203]. Jenniskens, P., Utas J., Qing-zhu Yin, Matson R. D., Fries M., Howell J. A., Free D., Albers J., Devillepoix H., Bland P., Miller A., Verish R., Garvie L. A. J., Zolensky M. E., Ziegler K., Sanborn M. E., Verosub K. ., Rowland D. J., Ostrowski D. R., Bryson K., Laubenstein M, Zhou Q., Li, Q.-L., Li X.-H., Liu Y., Tang G.-Q., Welten K., Meier M. M. M., Plant A. A., Maden C., Busemann H., Granvik M., 2018. The Creston, California, meteorite fall and the origin of L chondrites. MAPS (in press) [#202]. Harp, G. R., Richards, J., Jenniskens, P., Shostak, S., Tarter, J. C., 2019. Radio SETI observations of the interstellar object 'OUMUAMUA. Acta Astronautica 155, 51–54 [#201]. 2018 Jenniskens, P., 2018. A shower look-up table to trace the dynamics of meteoroid streams and their sources. AAS DPA meeting #49, San Jose, id.102.04 (abstract). Kartashova, A. P., Popova, O. P., Glazachev, D. O., Jenniskens, P., Podobnaya, E. D., 2018. Eyewitness accounts and modeling results for Chelyabinsk Airburst. 81st. Annual Meeting of the Meteoritical Society, 22-27 July 2018 in Mosow, Russia, LPI Contr. No. 2067, 2018, id.6169. Goodrich, C. A., Fioretti, A., Zolensky, M., Shaddad, M., Hiroi, T., Kohl, I., Young, E., Kita, N., Sanborn, M., Yin, Q.-Z., Downes, H., Ross, D., Jenniskens, P., 2018.
    [Show full text]
  • The Creston, California, Meteorite Fall and the Origin of L Chondrites
    Meteoritics & Planetary Science 1–22 (2019) doi: 10.1111/maps.13235 The Creston, California, meteorite fall and the origin of L chondrites Peter JENNISKENS 1,2*, Jason UTAS 3, Qing-Zhu YIN 4, Robert D. MATSON5, Marc FRIES 6, J. Andreas HOWELL 7, Dwayne FREE 7, Jim ALBERS1, Hadrien DEVILLEPOIX 8, Phil BLAND 8, Aaron MILLER9, Robert VERISH10, Laurence A. J. GARVIE 11, Michael E. ZOLENSKY 6, Karen ZIEGLER 12, Matthew E. SANBORN 4, Kenneth L. VEROSUB4, Douglas J. ROWLAND 13, Daniel R. OSTROWSKI 2,14, Kathryn BRYSON 2,14, Matthias LAUBENSTEIN 15, Qin ZHOU 16, Qiu-Li LI 17, Xian-Hua LI 17, Yu LIU 17, Guo-Qiang TANG 17, Kees WELTEN 18, Marc W. CAFFEE19, Matthias M. M. MEIER 20, Amy A. PLANT 20, Colin MADEN 20, Henner BUSEMANN 20, Mikael GRANVIK 21,22 (The Creston Meteorite Consortium) 1SETI Institute, Carl Sagan Center, Mountain View, California 94043, USA 2NASA Ames Research Center, Moffett Field, California 94035, USA 3Institute of Geophysics and Planetary Physics, UCLA, Los Angeles, California 90095, USA 4Department of Earth and Planetary Sciences, University of California at Davis, Davis, California 95616, USA 5Leidos, Seal Beach, California 90740, USA 6Astromaterials Research and Exploration Science, NASA Johnson Space Center, Houston, Texas 77058, USA 7Spalding Allsky Camera Network, SkySentinel, LLC (SSL), Melbourne, Florida 32940, USA 8Faculty of Science & Engineering, Curtin University, Bentley, Perth, Western Australia 6102, Australia 9Ancient Earth Trading Co., Atascadero, California 93423, USA 10Meteorite Recovery Lab, Escondido, California 92046, USA 11Center for Meteorite Studies, School of Earth & Space Exploration, Arizona State University, Tempe, Arizona 85287, USA 12Institute of Meteoritics, University of New Mexico, Albuquerque, New Mexico 87131, USA 13Center for Molecular and Genomic Imaging, Department of Biomedical Engineering, UC Davis, Davis, California 95616, USA 14Bay Area Environmental Research Institute, 625 2nd St., Suite 209, Petaluma, California 94952,USA 15Ist.
    [Show full text]