Determination of petroleum pipe scale solubility in simulated lung fluid

Cezeaux, Jason Roderick,

January 1900

Thesis (M. S.)--Texas A&M University, 2004. / "Major Subject: Health Physics" Title from author supplied metadata (automated record created on Sep. 21, 2005.) Vita. Abstract. Includes bibliographical references.

Major Health Physics

Design and construction of a compact multi-chamber tissue equivalent proportional counter

Taplin, Temeka, 1978-

January 1900

Thesis (M. S.)--Texas A&M University, 2005. / "Major Subject: Health Physics" Title from author supplied metadata (automated record created on Apr. 14, 2006.) Vita. Abstract. Includes bibliographical references.

Major Health Physics

Dental dose and image quality surveys using optically stimulated luminescence

Handley, Stephen Michael, 1980-

January 1900

Thesis (M. S.)--Texas A&M University, 2005. / "Major Subject: Health Physics" Title from author supplied metadata (automated record created on Apr. 14, 2006.) Vita. Abstract. Includes bibliographical references.

Major Health Physics

The theoretical development of a new high speed solution for Monte Carlo radiation transport computations

Pasciak, Alexander Samuel,

January 1900

Thesis (M. S.)--Texas A&M University, 2005. / "Major Subject: Health Physics" Title from author supplied metadata (automated record created on Apr. 27, 2007.) Vita. Abstract. Includes bibliographical references.

Major Health Physics

External detection and measurement of inhaled radionuclides using thermoluminescent dosimeters

Prause, Christopher Alvin,

January 1900

Thesis (M. S.)--Texas A&M University, 2006. / "Major Subject: Health Physics" Title from author supplied metadata (automated record created on Apr. 27, 2007.) Vita. Abstract. Includes bibliographical references.

Major Health Physics

Beta dose distribution for randomly packed microspheres

Urashkin, Alexander,

January 1900

Thesis (M. S.)--Texas A&M University, 2006. / "Major Subject: Health Physics" Title from author supplied metadata (automated record created on Apr. 27, 2007.) Vita. Abstract. Includes bibliographical references.

Major Health Physics

Medical physics calculations with MCNP: a primer

Lazarine, Alexis D

30 October 2006

The rising desire for individualized medical physics models has sparked a transition from the use of tangible phantoms toward the employment of computational software for medical physics applications. One such computational software for radiation transport modeling is the Monte Carlo N-Particle (MCNP) radiation transport code. However, no comprehensive document has been written to introduce the use of the MCNP code for simulating medical physics applications. This document, a primer, addresses this need by leading the medical physics user through the basic use of MCNP and its particular application to the medical physics field. This primer is designed to teach by example, with the aim that each example will illustrate a practical use of particular features in MCNP that are useful in medical physics applications. These examples along with the instructions for reproducing them are the results of this thesis research. These results include simulations of: dose from Tc-99m diagnostic therapy, calculation of Medical Internal Radiation Dose (MIRD) specific absorbed fraction (SAF) values using the ORNL MIRD phantom, x-ray phototherapy effectiveness, prostate brachytherapy lifetime dose calculations, and a radiograph of the head using the Zubal head phantom. Also included are a set of appendices that include useful reference data, code syntax, and a database of input decks including the examples in the primer. The sections in conjunction with the appendices should provide a foundation of knowledge regarding the MCNP commands and their uses as well as enable users to utilize the MCNP manual effectively for situations not specifically addressed by the primer.

MCNP

medical physics

monte carlo

health physics

Uptake and Exposure Measurements in Health Physics Technicians Associated with 131I-MIBG Patient Therapy

Collier, Jason L.

07 June 2016

No description available.

Mechanical Engineering

in vivo measurement

131i-MIBG

health physics technician

Radon (Rn-222) and thoron (Rn-220) emanation fractions from three separate formations of oil field pipe scale

Fruchtnicht, Erich Harold

15 November 2004

Over the course of normal oil well operations, pipes used downhole in the oil and petroleum industry tend to accumulate a mineral deposit on their interior, which restricts the flow of oil. This deposit, termed scale, will eventually occlude the interior diameter of the pipe making removal from service and descaling a cost effective option. The pipes are sent to cleaning yards where they remain until descaling can be performed. This storage period can potentially create a health concern not only because of the external radiation exposure but also because of the radon gas emissions, both of which are due to the radioactive minerals contained in the scale. It was believed that the structure of the scale is formed tightly enough to prevent much of the radon from becoming airborne. The goal of this research was to determine the emanation fractions for the rattled scale samples from three formations. A high purity germanium detector was used to measure the activities of the parents and progeny of radon, and electret ion chambers were used to measure the concentration of radon emanated from the scale. The emanation fractions of between 4.9x10-5 and 1.08x10-3 for radon were a factor of approximately 100 smaller than previous research results. For thoron, the fractions were and 5.72x10-8 and 4.92x10-7 for thoron with no previous research to compare. However, information that pertains to the temperature dependence of emanation was included in this research and was not available for previous, similar research. Therefore, differences in the environment (e.g., temperature, humidity, etc.) in which the previous experiments were conducted, as well as differences in the scale formation types used, could account for the discrepancy. In addition, measuring the emanation fractions of the rattled scale was a method of determining whether surface to volume ratio dependence existed. After acquiring the emanation fractions, insufficient evidence of any surface to volume ratio dependence could be found.

radiation

health physics

radon

thoron

emanation fractions

emanation

radioactive

pipe scale

scale

petroleum

oil field

Radon (Rn-222) and thoron (Rn-220) emanation fractions from three separate formations of oil field pipe scale

Fruchtnicht, Erich Harold

15 November 2004

Over the course of normal oil well operations, pipes used downhole in the oil and petroleum industry tend to accumulate a mineral deposit on their interior, which restricts the flow of oil. This deposit, termed scale, will eventually occlude the interior diameter of the pipe making removal from service and descaling a cost effective option. The pipes are sent to cleaning yards where they remain until descaling can be performed. This storage period can potentially create a health concern not only because of the external radiation exposure but also because of the radon gas emissions, both of which are due to the radioactive minerals contained in the scale. It was believed that the structure of the scale is formed tightly enough to prevent much of the radon from becoming airborne. The goal of this research was to determine the emanation fractions for the rattled scale samples from three formations. A high purity germanium detector was used to measure the activities of the parents and progeny of radon, and electret ion chambers were used to measure the concentration of radon emanated from the scale. The emanation fractions of between 4.9x10-5 and 1.08x10-3 for radon were a factor of approximately 100 smaller than previous research results. For thoron, the fractions were and 5.72x10-8 and 4.92x10-7 for thoron with no previous research to compare. However, information that pertains to the temperature dependence of emanation was included in this research and was not available for previous, similar research. Therefore, differences in the environment (e.g., temperature, humidity, etc.) in which the previous experiments were conducted, as well as differences in the scale formation types used, could account for the discrepancy. In addition, measuring the emanation fractions of the rattled scale was a method of determining whether surface to volume ratio dependence existed. After acquiring the emanation fractions, insufficient evidence of any surface to volume ratio dependence could be found.

radiation

health physics

radon

thoron

emanation fractions

emanation

radioactive

pipe scale

scale

petroleum

oil field