Secondary Logo

Journal Logo

Institutional members access full text with Ovid®

Measurement of the Background Gamma Dose Rates in Houston, Texas

A Descriptive Summary of an Undergraduate Research Mentored Project Performed by Students Underrepresented in the Health Physics Profession

Ozain-Porterie, Anastasia M.1; Quach, Tommy2; Harvey, Mark C.1


In the paper titled “Measurement of the Background Gamma Dose Rates in Houston, Texas: A Descriptive Summary of an Undergraduate Research Mentored Project Performed by Students Underrepresented in the Health Physics Profession,” by Anastasia M. Ozain-Porterie, Tommy Quach and Mark C. Harvey, which appeared in the December 2018 issue, the corresponding author is incorrect. The correct corresponding author is Mark C. Harvey. Additionally, eqn (2) is incorrect. The correct form of eqn (2) should read:

Finally, the Fig. 2 caption should properly read: “Plot of the raw spectra measured at the Gulfgate location in Houston with the Canberra InSpector TM 1000 showing the 40 K peak. The hatched area under the 40 K peak shows the left and right FWHM tolerance boundaries that were required in the spectral analysis.”

Health Physics. 116(5):746, May 2019.

doi: 10.1097/HP.0000000000000906

Natural background radiations include cosmic, terrestrial, and medical sources. Cosmic radiation is mostly shielded by the magnetic field of the Earth; however, those that penetrate can produce nuclear interactions within the Earth’s atmosphere yielding cosmic ray showers. Terrestrial and medical sources of radioactivity are typically identified through radionuclide-specific decay signatures. Medical sources of radiation mainly result from diagnostic x rays, which attenuate into the environment. These x rays also contribute slightly to background radiation. The purpose of this study was to have students involved with the Texas Southern University (TSU) health physics program measure and report background gamma dose rates in Houston, Texas, using the Canberra InSpectorTM 1000 Digital Hand-Held Multichannel Analyzer. The results were compared with the average gamma dose rate on Earth. Of note, TSU is one of the largest historically black colleges and universities (HBCUs) in the nation and currently boasts the only undergraduate health physics program in Houston. Targeted locations were selected within the I‐610 loop of Houston covering an area of approximately 100 km2. Measurements were performed at nine locations and verified by GPS latitude and longitude coordinates. The dose rate was measured over a 100 m2 area at each location, while spectral analysis was simultaneously performed for natural gamma-emitters. Our results suggest the dose rate averaged over all geographical locations in this study was 0.114 ± 0.001 μSv h−1 and thus, consistent with most literature. The only radionuclide identified in the spectra in all measurements was 40K due to the limited energy resolution of the InSpectorTM 1000.

1Department of Physics, Texas Southern University, Houston, TX 77004;

2 Department of Biology, Texas Southern University, Houston, TX 77004.

The authors declare no conflicts of interest.

In May 2018, Anastasia Ozain-Porterie will be awarded her B.S. degree in physics from Texas Southern University. The specialized degree emphasizes a concentration in health physics. Ms. Ozain-Porterie has interned at Texas A&M University (Summer 2015) and The University of Texas Health Science Center at Houston (Summer 2017) through scholarship support from the U.S. Nuclear Regulatory Commission. Anastasia Ozain-Porterie is currently employed as an environmental permitting specialist in the Radioactive Materials Division of the Texas Commission on Environmental Quality in Austin, TX.

© 2018 by the Health Physics Society