<div dir="ltr"><div class="gmail_quote"><div dir="ltr"><div>Seth Jacobson is visiting Harvard all week and giving a talk at CfA on Wednesday:<br></div><div><br></div><div>SSP Seminar</div><div><div><br></div><div style>Dr. Seth Jacobson</div>
<div>University of Bayreuth / Nice Observatory<br></div><div><br></div><div>Wednesday November 13 at 2pm at CfA in the Pratt Conference Room</div><div>(<a href="http://www.cfa.harvard.edu/ssp/events.html" target="_blank">http://www.cfa.harvard.edu/ssp/events.html</a>)</div>
<div><br></div><div>Title: "Terrestrial planet formation in the age of the truncated disk."</div><div><br></div><div>Abstract:</div><div>After reviewing the standard model of terrestrial planet formation, both its successes and failures. I will introduce the recently proposed solution to the small Mars mass problem, the truncated disk. The Grand Tack model exploits the gas-driven migration of giant planets observed in extra-solar planet systems to motivate this truncation. In this model the first inward and then outward migration of Jupiter and Saturn creates a truncated disk of embryos and planetesimals, of which the subsequent evolution broadly reproduces the orbital and mass distributions of the terrestrial planets including a small Mars. <br>
</div><div><br></div><div>New results will be presented that explore a large number of N-body simulations that model a variety of different oligarchic growth regime initial conditions. From this dataset, we discover a correlation between the time of the last giant impact and the late accreted mass. >From highly siderophile element constraints on the late accreted mass, we are able to estimate the time of the last giant (Moon forming) impact. These terrestrial disks still produce good analog terrestrial planet mass-orbit distributions, but now have a large distribution of different accretion histories. We find a portion of parameter space that is able to match Solar System constraints such as the date of the Moon forming impact, the mass of late accretion, and the rapid growth of Mars. </div>
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