What are the Astrobiological Constraints from What is Known about the Late Heavy Bombardment? What are the Astrobiological Constraints from What is Known.

Slides:



Advertisements
Similar presentations
Impact Cratering Dating Nathan Marsh. Relative Dating Simple but not as informative Measures the crater densities (craters per square kilometer) Generally.
Advertisements

Chapter 6 The Earth and Moon. Distance between Earth and Moon has been measured to accuracy of a few centimeters using lasers (at McDonald Observatory)
Late Heavy Bombardment Or, Kablooie!. The main piece of evidence for a lunar cataclysm comes from the radiometric ages of impact melt rocks that were.
An Inquiry about Evidence for the Late Heavy Bombardment Clark R. Chapman & David H. Grinspoon SwRI, Boulder CO 65th Meteoritical Society Meeting (2002)
© 2010 Pearson Education, Inc. Our Moon and other moons of the Solar System.
Formation of our Moon: The Giant Impact Hypothesis Michelle Kirchoff Southwest Research Institute Center for Lunar Origin and Evolution.
The SLAM Impact Experiment: Overview and Preliminary Thoughts Clark R. Chapman Southwest Research Institute Boulder CO SLAM Organizational Meeting SwRI.
Investigating the Near-Earth Object Population William Bottke Southwest Research Institute William Bottke Southwest Research Institute.
Dynamics of the young Solar system Kleomenis Tsiganis Dept. of Physics - A.U.Th. Collaborators: Alessandro Morbidelli (OCA) Hal Levison (SwRI) Rodney Gomes.
MINOR MEMBERS OF THE SOLAR SYSTEM: Asteroids. Images of three asteroids, taken during spacecraft flybys, shown to scale (Mathilde is 59 km wide and 47.
The `Nice’ Model Öpik approximation Planet migration in a planetesimal disk The Nice model Consequences of the Nice Model: Epoch of Late Heavy Bombardment,
The Universe. The Milky Way Galaxy, one of billions of other galaxies in the universe, contains about 400 billion stars and countless other objects. Why.
History of the Earth Chapter 1: Formation of the Earth From the Big Bang to Early Planets.
TERRESTRIAL PLANET FORMATION & THE FORMATION OF A WATER-RICH EARTH
Report from the Oort Cloud Simulations of the Formation of the Comet Reservoir Luke Dones Hal Levison Paul Weissman Martin Duncan.
Asteroids Astronomy 311 Professor Lee Carkner Lecture 15.
Jeff TaylorLunar Science1 Moonstruck: Illuminating Early Planetary History G. Jeffrey Taylor Hawai`i Institute of Geophysics and Planetology University.
 The solar system has 8 planets.  The solar system has 1dwarf planet named Pluto.
What are the odds of an asteroid or comet hitting the Earth? Has this happened in Earth’s past? What would happen to Earth’s civilization in the event.
Impacts with Space Objects. Moon shows many impact scars though most are prior to 3.8 billion years ago.
Remnants of Rock and Ice Asteroids Meteoroids (meteorites, meteor) Comets.
Mass Extinction ASTR 1420 Lecture 9 Sections : 4.6, 6.4, 11.3.
Lesson 8a Moons, Asteroids and Rings. Europa These interactions also keep Europa in a slight elliptical orbit as well. But since Europa is farther from.
Origin of the Solar System. Stars spew out 1/2 their mass as gas & dust as they die.
A coherent and comprehensive model of the evolution of the outer solar system Alessandro Morbidelli (OCA, Nice) Collaborators: R. Gomes, H. Levison, K.
Standard 1b. Students know the evidence from Earth and moon rocks indicates that the solar system was formed from a large nebular cloud of dust and gas.
Mass Distribution and Planet Formation in the Solar Nebula Steve Desch School of Earth and Space Exploration Arizona State University Lunar and Planetary.
THE LATE HEAVY BOMBARDMENT AND THE FORMATION OF THE SOLAR SYSTEM
Origin of the Solar System. Stars spew out 1/2 their mass as gas & dust as they die.
Pre-solar nebula Protoplanetary disk: condensation and accretion Solar wind (beginning of fusion) Collisions continue Planetary migration (orbits shifting)
THE SOLAR SYSTEM. Solar System Solar System- a star and all the objects orbiting it. Our solar system includes the Sun and all of the planets, dwarf planets,
Lecture 3 – Planetary Migration, the Moon, and the Late Heavy Bombardment Abiol 574.
Earth and Other Planets Chapter 16 Great Idea: Earth, one of the planets that orbit the Sun, formed 4.5 billion years ago from a great cloud of dust.
ASTR 1420 Lecture 9 Sections : 4.6, 6.4, 11.3
Late Heavy Bombardment: Evidence From Cratering Histories of the Moon, Planets, Satellites, and Asteroids Clark R. Chapman Southwest Research Institute,
Chapter 9 Remnants of Rock and Ice Asteroids, Comets, and Pluto.
Review 2 What was the solar nebula? What was it made of? How did gravitational collapse affect the Solar nebula? How does conservation of energy and angular.
Recent Developments in PLANETARY CRATERING Recent Developments in PLANETARY CRATERING Clark R. Chapman Southwest Research Institute Boulder, Colorado,
1.How do supernovas influence the formation of new solar systems? ANS: They provide the material and energy required to form a new Sun, and all the planets,
Announcements Brooks Observatory tours (March ) 7:30 - 8:30 p.m. – extra credit Weather permitting Will look at Saturn, Jupiter, Orion Nebula Bring.
WARM UP Can you list the planets in order?. Our Solar System.
The Earth and Other Planets
Asteroids Astronomy 311 Professor Lee Carkner Lecture 15.
Dynamics of comets and the origin of the solar system Origin of solar systems - 30/06/2009 Jean-Baptiste Vincent Max-Planck-Institut für Sonnensystemforschung.
The Sun & The Solar System. Structure of the Sun The Sun has layers which can be compared to the Earth’s core, mantle, crust, and atmosphere All of these.
WATER ON EARTH Alessandro Morbidelli CNRS, Observatoire de la Cote d’Azur, Nice.
Building the Planets. IV. Nebular Capture Nebular capture – growth of icy planetesimals by capturing larger amounts of hydrogen and helium. Led to the.
Astronomy 1010-H Planetary Astronomy Fall_2015 Day-27.
MOON J ASON L OPEZ. HOW WAS IT CREATED? There are many theories, but one theory says that a giant planetoid crashed with the Earth billions of years ago.
What’s new with the Lunar Cataclysm? Tim Swindle Lunar and Planetary Lab University of Arizona Background: Kaguya image of the central part of SPA.
LOOKING FOR LAKE MISSOULA!!. EARLIER MAJOR, CRATERING.
ORIGIN OF THE LATE HEAVY BOMBARDMENT OF THE TERRESTRIAL PLANETS
Astronomy 1010 Planetary Astronomy Fall_2015 Day-27.
New Views on the Lunar Late Heavy Bombardment
Cratering in the Solar System William Bottke Southwest Research Institute Boulder, Colorado.
Our Solar System Formed about five billion years ago from a giant cloud of gas and debris Gravity caused Earth and other planets to become layered according.
Thought Question What does the solar system look like as a whole? Why does the solar system look the way it does? Can we explain how the solar system.
Jeff Taylor Lunar cataclysm1 Lunar Bombardment History: Was There a Terminal Lunar “Cataclysm”? The concept The importance if it happened The evidence.
1 Earth and Other Planets 3 November 2015 Chapter 16 Great Idea: Earth, one of the planets that orbit the Sun, formed 4.5 billion years ago from a great.
Dynamical constraints on the nature of the Late Heavy Bombardment and models of its origin A.Morbidelli Observatoire de la Cote d’Azur, Nice, France.
Delivery of Volatiles to the Terrestrial Planets Hans Rickman Uppsala Astronomical Observatory Hans Rickman Uppsala Astronomical Observatory.
Making Our Solar System: Planetary Formation and Evolution
Late Heavy Bombardment
Solar system Sergei popov.
Solar System Stuff.
Impacts on Earth Barringer (Meteor) Crater, Arizona 50,000 years old.
Astronomy.
The Jovian Planets Huge worlds, heavily mantled in gas at the time of the formation of the Solar System.
Thought Question What does the solar system look like as a whole?
1.1.1a and 1.1.1b ORIGIN OF THE EARTH’S MOTION BASED ON THE ORIGIN OF THE GALAXY AND SOLAR SYSTEM.
Presentation transcript:

What are the Astrobiological Constraints from What is Known about the Late Heavy Bombardment? What are the Astrobiological Constraints from What is Known about the Late Heavy Bombardment? Clark R. Chapman Southwest Research Institute Boulder CO NAI General Meeting 2003 Tempe, Arizona 12 February 2003

Late Heavy Bombardment… or “terminal cataclysm” Proposed in 1973 by Tera et al. who noted a peak in radiometric ages of lunar samples ~ Ga Sharply declining basin-formation rate between Imbrium (3.85 Ga) and final basin, Orientale (3.82 Ga) Few rock ages, and no impact melt ages prior to 3.9 Ga (Nectaris age) Implies: short, Myr bombard- ment, but minimal basin formation between crustal formation and LHB After Wilhelms (1987) ? LHB

Debate over “Cataclysm” “Stonewall” effect (Hartmann 1975) destroys and pulverizes rocks prior to saturation Grinspoon’s (1989) two- dimensional models concur No impact melts prior to Nectaris (Ryder 1990) Lunar crust not pene- trated or pulverized (but constrains only top-heavy size distributions) No enrichment in meteoritic/projectile material (not robust) A Misconception vs.It Happened! Time Flux “Tail-end” of accretion Post-crust, pre-spike lull defines LHB (Mostly) uncontroversial sharp decline in bombardment rate from 3.90 Ga to 3.83 Ga Further confusion on LHB decay: >Basin formation decayed in 50 Myr >Rocks degassed over 200 Myr >Impact melts decayed over 1000 Myr [Chapman, Cohen & Grinspoon, 2002] ?

Non-Lunar Evidence for LHB Cratered uplands on Mars/Mercury (and even Galilean satellites!) inferred to be due to same LHB… but absolute chronology is poorly known or unknown. ALH84001 has a ~4 Ga resetting age… but that is “statistics of one”. Peaks in resetting ages noted for some types of meteorites (HEDs, ordinary chondrites)… but age distributions differ from lunar case.

Remnant Planetesimals: Comets, Asteroids, Trojans, etc. Sun We are here! Jupiter’s orbit Trojans NEOs Comets & OSS planetesimals Asteroid belt Accretion of planets from planetesimals necessarily results in diverse groups of circumstellar and circumplanetary small bodies, subject to temporary confinement among dynamical resonances

Proposed Dynamical Origins for LHB Outer solar system planetesimals from late-forming Uranus/Neptune (Wetherill 1975) Break-up of large asteroid (but big enough asteroids difficult to destroy) Extended tail-end of accretion; remnants from terrestrial planets region (Morbidelli 2001) Expulsion of a 5th terrestrial planet (Chambers & Lissauer 2002; Levison 2002) OSS planetesimals & asteroids perturbed by sudden expulsion of Uranus & Neptune from between Jupiter & Saturn (Levison et al. 2001) Late-stage post Moon-formation Earth/Moon-specific LHB (Ryder 1990) More generally: any dynamical readjustment of the planets in a planetary system that “shakes up” (e.g. by changing positions of resonances) remnant small-body populations…could occur late, even very late.

Qualitative Features of LHBs On Earth, 1 “Chicxulub” (K-T boundary event, 100 million MT) every 10,000 years. Each kills virtually every complex lifeform, most fossilizable species go extinct, radiation of many new species One basin-forming event (10 billion MT!) every 500,000 years. Each erodes atmosphere, transforms ecosphere, boils oceans Total LHB: ~100 basins, 1000s of K-T events. Life would be deva- stated at the end of the 100 Myr. What does it take to sterilize planet Earth??? K-T

Why Giant Impacts are Especially Lethal Environmental changes are nearly instantaneous! (Most lethal, global effects occur in a couple of hours to a month or so.) Very short compared with the lifetime of an individual; most competing mass- extinction theories invoke changes over 1000s to millions of years. Independent, compound global effects (firestorm, ozone layer destroyed, tsunami, earthquake, oceans poisoned, “impact winter” followed by global warming, etc.) atmosphere surface/ocean crust mantle Impacts dominate or destroy the atmos- phere, dramatically affect the surface and oceans, but their effects may not fully involve the crust and rarely the upper mantle.

LHB Issues for Solar System Astrobiology Lunar evidence on LHB is less well understood than commonly believed. It must be re-evaluated: it is our baseline! How widespread was this lunar LHB? Which small-body reservoirs/dynamical readjustments were responsible? Were other reservoirs/causes responsible for earlier bombardments, or for the cratered terrains and basins on other planets/satellites/asteroids? The future: Earth is likely to suffer another basin-forming impact (not soon!); what else could be in our future? How would early evolving life on Mars or Europa have been affected? Earth’s complex life in the future?

LHB Issues for Extra-Solar System Astrobiology It is plausible that similar, or even much more extreme, LHBs or VLHBs would affect planets in other systems. What planetary system configurations are most likely to result in small- body reservoirs and unstable dynamics that would cause LHBs? Are LHB/VLHB reservoirs astronomically observable (directly or indirectly)? What range of bombardments foster life (exchanging materials, spurring evolutionary change)? How frequent would giant impacts have to be to perpetually frustrate the origin or evolutionary progression of life? How big an LHB surely sterilizes a planet? How do LHBs compete with other cosmic dangers to life in different stellar/galactic environments?