Wine and Cheese Spring 2024: Difference between revisions
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=12 February= | =12 February= | ||
==Andy Harris (UMd)== | ==Andy Harris (UMd)== | ||
''' | '''The Central Molecular Zone of the Galaxy in C+ from upGREAT/SOFIA'''<br> | ||
The Galactic center, deep at the bottom of the Galaxy's gravitational potential well, is a region of complex dynamics and regions of massive star formation. Observing it through the disk of the Galaxy, the pileup of emission from line-of-sight structures makes discrimination by excitation and velocity resolution essential. | |||
I will discuss fully-sampled spatial and velocity-resolved 158um [C II] SOFIA-upGREAT spectroscopic imaging of the center's 200pc wide Central Molecular Zone. These new data provide a high-resolution view that helps us understand center's structure, star formation, and gas flows into the Galactic center and onto the central black hole Sgr A*. They also serve as guides to interpreting far-infrared fine structure emission from other galactic nuclei. | |||
I will focus on two regions in the CMZ: Sgr A and B. Toward Sgr A, [C II] explores the possible interaction between the Sgr A(East) SNR and the Circum-nuclear Disk (CND) around the central black hole. At larger scales, the data provide insights into the origin of the Sgr A Thermal Arched Filaments. Toward Sgr B, [C II] imaging firmly establishes that the region extends as a coherent structure spanning some 34 pc along the Galactic plane. The extreme star formation cores of Sgr B2 contribute negligible amounts of [C II] intensity, a local example of the "C+ deficit" toward ULIRGs. The velocity structure across Sgr B constrains mechanisms for gas flow from the Galactic disk into the central regions. As a tracer of star formation in galactic nuclei, [C II] preferentially traces extended star formation rather than the most compact cores. | |||
=19 February= | =19 February= |
Revision as of 14:35, 9 February 2024
This page records the schedule, titles and abstracts of the JHU/STScI CAS Astrophysics Wine & Cheese Series in Fall 2022.
Wine and Cheese sessions with one speaker will have a 50 minute talk with 10 minutes for questions. Sessions with two speakers will have two 25 minute talks, each with 5 minutes for questions. Sessions in the Graduate Student Series will have three 15 minute talks, each with 5 minutes for questions.
Back to W&C Schedule
29 February
Michael Fall (JHU)
Galaxy Scaling Relations: What They Reveal About Galaxy Formation
Despite the apparent complexity of galaxies, some of their most basic properties (mass M, binding energy E, angular momentum J, etc) obey simple power-law scaling relations. Such relations provide a useful but generally under-exploited window into galaxy formation. This talk focuses on the relations between circular velocity V (a proxy for specific energy e = E/M) and mass M and between specific angular momentum j = J/M and mass M. The observed forms of these scaling relations for the stellar components of galaxies are closely related to those of their dark matter halos, which in turn are inherited from the primordial spectrum of cosmic density perturbations. This talk presents some new observations, new interpretations, and comparisons with recent cosmological hydrodynamical simulations of galaxy formation. The analysis presented here offers insights into the physical origins of several basic properties of galaxies, including their sizes, morphologies (disk vs spheroid) and feedback drivers (stars vs active galactic nuclei).
05 February
Robert Wilson (GSFC)
TRExS. Transits in the Roman galactic EXoplanet Survey
As one of its three Core Community Surveys, the Nancy Grace Roman Space Telescope (Roman, expected to launch in late 2026) will monitor 100s of millions of stars toward the center of the Milky Way, providing a powerful set of high-cadence, time-series data. Among the scientific investigations made possible by this dataset includes the detection of over 60,000 to 200,000 exoplanets via transit. The allure of this transiting exoplanet sample is threefold: First, in the statistical power offered by the order of magnitude increase in the number of known exoplanets, providing strict constraints on the demographics of intrinsically rare systems. Second, in the depth and distances of the surveyed stars, which represent nearly every major stellar population in the Galaxy. And third, in the near-infrared bandpass and color information which will enable the direct detection of 1000s of transiting exoplanet atmospheres and provide population-level constraints into their cloudiness and atmospheric circulation. In this talk, I will discuss Roman's scientific potential for transiting exoplanets, challenges in compiling the anticipated catalog of transiting exoplanet detections, and the actions that we in the TRExS collaboration are taking to harness Roman’s capabilities and enable a broad range of transiting exoplanet science in the Galactic Bulge.
K.D. Kuntz (JHU/GSFC)
The Line Emission Mapper (LEM): An X-ray Probe
The Line Emission Mapper (LEM) is a recently submitted Probe proposal for a large-grasp X-ray imaging spectrometer with a 30' FOV and an energy resolution of 0.9 eV at the center of the FOV, and <2 eV for the remainder of the FOV. With such resolution we will be able to do velocity mapping of SNR, galaxies, and clusters of galaxies, separate the WHIM emission from the Galactic halo emission using their velocities, and resolve the forest of lines in soft thermal spectra. LEM will open up vast new opportunities across astrophysics, from planetary physics to cosmology.
12 February
Andy Harris (UMd)
The Central Molecular Zone of the Galaxy in C+ from upGREAT/SOFIA
The Galactic center, deep at the bottom of the Galaxy's gravitational potential well, is a region of complex dynamics and regions of massive star formation. Observing it through the disk of the Galaxy, the pileup of emission from line-of-sight structures makes discrimination by excitation and velocity resolution essential.
I will discuss fully-sampled spatial and velocity-resolved 158um [C II] SOFIA-upGREAT spectroscopic imaging of the center's 200pc wide Central Molecular Zone. These new data provide a high-resolution view that helps us understand center's structure, star formation, and gas flows into the Galactic center and onto the central black hole Sgr A*. They also serve as guides to interpreting far-infrared fine structure emission from other galactic nuclei.
I will focus on two regions in the CMZ: Sgr A and B. Toward Sgr A, [C II] explores the possible interaction between the Sgr A(East) SNR and the Circum-nuclear Disk (CND) around the central black hole. At larger scales, the data provide insights into the origin of the Sgr A Thermal Arched Filaments. Toward Sgr B, [C II] imaging firmly establishes that the region extends as a coherent structure spanning some 34 pc along the Galactic plane. The extreme star formation cores of Sgr B2 contribute negligible amounts of [C II] intensity, a local example of the "C+ deficit" toward ULIRGs. The velocity structure across Sgr B constrains mechanisms for gas flow from the Galactic disk into the central regions. As a tracer of star formation in galactic nuclei, [C II] preferentially traces extended star formation rather than the most compact cores.
19 February
TBD (TBD)
TBD
Abstract
TBD (TBD)
TBD
Abstract
26 February
TBD (TBD)
TBD
Abstract