Spitzer Space Telescope Research
Program for Teachers and Students



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OBSERVING PROPOSALS

Star Formation in Lynds Dark Nebulae
+ Round 3

Spitzer Light Curve of Z Cha
+ Round 3

IRAC Monitoring of NGC 4051 for Interday Variability
+ Round 3

Star Formation in High Redshift Clusters with Spitzer
+ Round 2

Young Stars in IC 2118
+ Round 1
+ Round 2

Observing Iron Stars with Spitzer
+ Round 1

Intergalactic Star Formation in Tidal Dwarf Galaxies of M81
+ Round 1

AGN Spectral Energy Distributions of GLAST Telescope Network Program Objects
+ Round 1
+ Round 2
+ Student Project

The Supermassive Black Hole in Arp102B
+ Round 1

Detecting Brown Dwarfs in Interacting Cataclysmic Binaries
+ Round 1
+ Round 2



 

The Supermassive Black Hole in Arp102B

Arp102B is a radio-loud, Seyfert 1 galaxy located in the constellation Hercules with a B-band magnitude of 15.2 mag. It has a redshift z = 0.024, giving it a recessional velocity of 7250 km/s and a distance of about 99.1Mpc. At its core is a low luminosity AGN with a black hole estimated to be ~108 solar masses. Although there have be en many radio, X-ray, UV, optical, and ground-based IR studies of the Arp102B nucleus , they have not converged to produce a single, unified model for the nucleus. For example, Chen and Halpern (1989) used a geometrically thin, optically thick accretion disk model to fit double-peaked Balmer lines in the spectrum of Arp102B. Sulentic (1998) suggested that a bicone model would better fit the Fe K alpha lines in the x-ray spectrum. Korista summarizes the current state of our understanding as follows: "Despite significant progress, some fundamental issues relating to the geometry of the broad line emitting gas remain unsolved. We do not know whether in general the broad line region is composed of discrete clouds, winds, disks, or bloated stellar atmospheres or a combination of these." (Strateva et al., 2003) We believe that quality spectral data covering the IR spectrum may be the key to resolving these differences and could lead to a unified model for this type of AGN. Therefore, we propose to use Spitzer's IRS instrument to obtain LH, SH, SL1 and SL2 spectral data of Arp102's supermassive blackhole. With this data, we can measure the mass of the black hole, analyze the geometry, composition, and physical properties of the dust structure surrounding the black hole and reach conclusions about the energy production mechanism(s) in the nucleus.

Lead Teacher:

    Harlan V. Devore
    Cape Fear High School
    Fayetteville, NC

Participating Teachers:

    Lauren K. Chapple
    Traverse City East Junior High School
    Traverse City, MI

    Howard T. Chun
    Cranston High School East
    Cranston, RI

Support Scientist:

    Dr. Ranga-Ram Chary
    Spitzer Science Center
    Pasadena, CA

Proposal News

Work Summary:
      November 2005
      October 2005
      September 2005
      August 2005
      June 2005
      May 2005
      April 2005 - pdf file
      March 2005 - pdf file

Data Reduction & Analysis
      Report from Harlan Devore
      Report from Lauren Chapple
      Report from Howard Chun

Proposal - pdf file

AOR - pdf file

Proposed Observation Time

IRS Staring to obtain LH, SH, SL1 and SL2 spectral data of Arp102's supermassive blackhole.

With this data, we can measure the mass of the black hole, analyze the geometry, composition, and physical properties of the dust structure surrounding the black hole and reach conclusions about the energy production mechanism(s) in the nucleus.

TOTAL_DURATION: 1683.9 sec.

Visibility: No Problems

Status: Observed and Archived