Crater Counting Chronologies ● Planetary radius determines the duration over which radioactive decay can maintain geological activity. Crater density on.

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

Formation of Earth/Moon & Geologic Dating Review

Interior structure, origin and evolution of the Moon Key Features of the Moon: pages

LECTURE 14, OCTOBER 12, 2010 ASTR 101, SECTION 3 INSTRUCTOR, JACK BRANDT 1ASTR 101-3, FALL 2010.

Mercury & the Moon Mercury & the Moon. Mercury and the Moon: What can we learn? What do we know? What do we know? Why is it important? Why is it important?

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)

Crater Impact craters are the remains of collisions between an asteroid, comet, or meteorite and the Moon. These objects hit the Moon at a range of speeds,

The Earth and moon viewed from Mercury The Earth viewed from Saturn.

Formation of our Moon: The Giant Impact Hypothesis Michelle Kirchoff Southwest Research Institute Center for Lunar Origin and Evolution.

The young Moon was hit by a storm of asteroids. Here, an artist shows how a big impact on the young Moon might have looked. The asteroids broke apart when.

Volcanism in the Solar System Part 1: Inner Solar System Justin Filiberto Lunar and Planetary Institute.

Radiometric Dating and Half Life Over time a radioactive sample becomes less radioactive as unstable atoms decay to stable forms. The decay is a random.

Asteroids By: Ethan and Kacey. What are they? Chunks of rock that measure in size from few feet to several miles in diameter Rocky remains from the formation.

Mercury’s Craters How They Are And What They Are Lindsay Johannessen PTYS 495.

April 4, 2006Astronomy Chapter 8 Cratered Worlds: The Moon and Mercury The Moon is an object of lore and superstition. The Moon is our nearest neighbor,

8 February 2005AST 2010: Chapter 8 1 The Moon & Mercury.

Timeline of Martian VolcanismTimeline of Martian Volcanism A crater-count study on Mars dates.

Unraveling the History of the Moon

THE PRIMORDIAL EARTH Hadean and Archean Eons Solar System Includes: Sun Planets Moons Asteroids Comets.

Four Basic Geological Processes Impact cratering –Impacts by asteroids or comets Volcanism –Eruption of molten rock onto surface Tectonics –Disruption.

The Lunar Interior A Presentation by Kyle Stephens October 2, 2008.

Astronomy Picture of the Day. Mercury Mass = M Earth Radius = 0.38 R Earth  Surface Temp: K Moonlike: Surface craters, no atmosphere.

Class 3 : Craters in the solar system. Recap last class… Patterns in the solar system. Theory for solar system formation. How do we test this theory? Variety.

Our Solar System Dorian Janney After School Astronomy Clubs.

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.

The Terrestrial Planets

The Solar System.

Mercury Closest to the sun Covered in craters No atmosphere No moons

Survey of the Solar System

Lecture 3 – Planetary Migration, the Moon, and the Late Heavy Bombardment Abiol 574.

Impact crater Lab Some notes about cratering 1. Meteors Updated july 19, 2009.

Section 1: Earth’s Moon Preview Key Ideas Exploring the Moon

Our Solar System By Abigail Stivala.

Survey of the Solar System. Introduction The Solar System is occupied by a variety of objects, all maintaining order around the sun The Solar System is.

Internal Heating: Planets and Moons July 21, 2005 Presented to teachers in TRUST by Denton S. Ebel Assistant Curator, Meteorites Department of Earth and.

I. The Highlands  Surface feature that is light in color, high in elevation (mountainous), and heavily cratered.

Impact Mechanics and Morphology. Impact Craters Crater: From the Greek krater meaning bowl Drop a rock into some sand (v = a few m/sec) –Physically what.

The Moon Topographic map from Lunar Reconnaissance Orbiter.

1 Inner or Terrestrial Planets All the inner planets formed at the same time. Their composition is also very similar. They lack the huge atmospheres of.

Cratering in the Solar System Lab 8. Properties of Craters Craters formed by asteroids and comets able to penetrate the planet’s atmosphere An impactor.

1 Space Rocks Impacts of our smallest neighbors. 2 Asteroid Belt.

Christensen, Planetary Interiors and Surfaces, June What is the age of the solar system ? Did the various bodies in the solar system form at the.

Catastrophic Events in the Solar System There are records in the surface and interior of the planets and their satellites that indicate the occurrence.

ASTR-1010 Planetary Astronomy Day Announcements Smartworks Chapter 6: Due Today, March 22. Smartworks Chapter 7: Due Friday, March st Quarter.

The Solar System a1 Mercury Sun Venus Earth Mars Asteroids Jupiter Saturn Uranus Neptune Other objects Observe our solar system Four inner planets.

Sponge – What is a synchronous orbit?. Surface Features - Maria - oceans or seas. (Galileo thought they were oceans when he saw them through his.

Overview of Common Characteristics of the Terrestrial Planets (1)Have relatively high surface temperatures - Located close to the sun (2) Have high densities.

Planetary image interpretation and mapping Phil Stooke USGS map I-515.

Earth’s Moon How did our Moon form? and What’s been happening since?

Phases and Appearance. Ground Based Observations Moon has light and dark areas on it Light and dark not randomly distributed There are a few bright.

The Moon. Moon: Basic Facts Diameter: 3500 km (2100 miles) Average Distance: 380,000 km (240,000 miles) Distance range: 360,000 – 400,000 km Orbital eccentricity:.05.

Astronomy 1010 Planetary Astronomy Fall_2015 Day-27.

Cratering in the Solar System William Bottke Southwest Research Institute Boulder, Colorado.

1 The Earth's Moon The Earth's Moon, in many ways, is prototypical of a substantial fraction of the objects in the Solar System.  Like many other moons.

Chapter 6: Terrestrial Planets -The Moon. Earth’s interior is revealed by seismology, the study of earthquakes. Layers are revealed: A layered object:

Our Solar System By Ella Chilson  There are 4 inner planets in our solar system.  There is also 4 outer planets in our solar system.  There is also.

Organization  Our Solar System consists of: Comets orbiting the Sun Asteroids orbiting the Sun Planets orbiting the Sun ○ Moons orbiting the planets.

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.

The Principles of Planetary Geology By: Katie McCormick and Kyle Lennox.

The Moon. Formation Hypotheses Co-Accretion – Earth and Moon formed near each other at same time. Fission – Rapidly rotating Proto-Earth released material.

EARLY HISTORY OF THE TERRESTRIAL PLANETS

Chapter 7 Volcanoes.

Late Heavy Bombardment

Lecture 12: Planetary Geology

Lecture: Planetology Continued (cratering) Part II: Solar System

Timeline of Martian Volcanism

Radiometrc Dating and Aging our Solar System

Sponge – What is a synchronous orbit?

Lecture 12: Planetary Geology

The Moon Topographic map from Lunar Reconnaissance Orbiter.

Presentation transcript:

Crater Counting Chronologies ● Planetary radius determines the duration over which radioactive decay can maintain geological activity. Crater density on a surface is a proxy for “age” presuming you know the local impact rate as a function of time.

Highlands vs. Maria / “Old” vs. “Young” “age” = time since last resurfacing

Lunar Elevations Blue = low Red = high

Cratering Isochrons ● The degree to which a surface is cratered depends on... – you tell me...

Cratering Isochrons ● The degree to which a surface is cratered depends on... – you tell me... In the end we identified impactor kinetic energy vs. crater size as the “microphysics” - so we worked out 1/2mv^2 for a typical asteroid and encounter velocities based on various escape velocities, getting up to 80 km/s for a head on collision between Earth and a comet with resulting kinetic energy of 10^22 J for a 1 km radius object. On the macro scale we talked about two things - size spectrum of a collisionally evolved population – few big chunks and lots of powder. - evolution of the net rate over time – cleaning up of the solar system.

A Natural Evolution of Cratering Rate

Crater Size vs. Energy

Cratering Mechanics

Cratering Mechanics

Ejecta

Secondary Craters

Complex Craters

Multi-ring Basins Mare Orientale – Earth's Moon Valhalla Basin – Jupiter's Moon Callisto

Saturation

Crater Counts vs. Size vs. Surface “Age” ● Craters accumulate over time on a “fresh” surface. ● Eventually the crater density saturates ● Large impacts can also produce large numbers of secondary craters. Lunar Highlands Lunar Maria

Scaling to other Worlds (isn't easy) ● We have the advantage of being able to radiometrically date lunar samples – thus providing an absolute age scale for the lunar crater isochrons. ● We don't know how the cratering rate varies throughout the solar system, so other cratering chronologies are relative.

Scaling to other Worlds (isn't easy) ● We have the advantage of being able to radiometrically date lunar samples – thus providing an absolute age scale for the lunar crater isochrons. ● We don't know how the cratering rate varies throughout the solar system, so other cratering chronologies are relative.

Scaling to other Worlds (isn't easy) ● We have the advantage of being able to radiometrically date lunar samples – thus providing an absolute age scale for the lunar crater isochrons. ● We don't know how the cratering rate varies throughout the solar system, so other cratering chronologies are relative.

Vesta Crater Counts

Timeline of Martian Volcanism A crater-count study on Mars dates the calderas on 20 major volcanoes. High-resolution images from the Context Camera (CTX), onboard NASA’s Mars Reconnaissance Orbiter, allow a larger range of crater sizes than were ever used before. The timing of the last major summit eruptions correlates well with the crystallization ages (~ million years) of the youngest basaltic Martian meteorites.

Timeline of Martian Volcanism – Olympus Mons Six calderas on Olympus Mons show ages ranging from about million years.

Timeline of Martian Volcanism – Elysium Mons Three calderas on Elysium Mons show ages around 3 billion years.

Timeline of Martian Volcanism and Meteorites After Apollinaris Mons shut off, major volcanism ended throughout the highlands and Syrtis Major, then in the smaller Elysium volcanoes, and finally in the largest of the Tharsis volcanoes. Martian meteorites a few 100 million years old likely came from the younger flows of the Tharsis Montes.

Evolution and Origin of the Size Distribution of Asteroids

Evolution of the Size Distribution of Asteroids

Late Heavy Bombardment and the “Lunar Cataclysm” Lunar Impact Basin Chronology

Results of the “Nice” Model Uranus Neptune