[ RadSafe ] Decades-old challenge has researchers seeking new materials for radiation detection

ROY HERREN royherren2005 at yahoo.com
Sat Feb 16 15:29:34 CST 2008

Public release date: 16-Feb-2008

Contact: Andrea Turner
andrea.turner at pnl.gov
DOE/Pacific Northwest National Laboratory 
  You can't teach old materials new tricks  Decades-old challenge has researchers seeking new materials for radiation detection            
  A graphic timeline of key radiation detection material discoveries.
  Click here for more information.   
    BOSTON – A more sensitive, more selective and easily deployable radiation detection material is necessary to meet complex 21st century challenges. In the AAAS symposium “Radiation Detectors for Global Security: The Need for Science-Driven Discovery,” researchers addressed some of the technical challenges and gaps and proposed a science-driven approach to uncovering novel materials that will benefit national security and medicine.
  “Until now, it can be argued that we’ve approached the challenge in an Edisonian-style; I think it’s time to make a drastic change in how we pursue solutions to radiation detection,” said Anthony Peurrung, director of the Physical and Chemical Sciences division at Pacific Northwest National Laboratory. “In order for us to make new discoveries, we need to improve our understanding of radiation physics so that we make educated choices about which materials will and will not perform as we need them to, thus working more efficiently toward a solution.” 
  Five primary materials are used for radiation detection, but they all have limitations, such as small size, challenges in manufacturing, poor discrimination of radionuclides and poor sensitivity. For example, single crystalline materials, used as semiconductors or scintillators, generally provide the highest sensitivity and best energy resolution. But, it can take a decade or more to develop high-quality, single crystals that are of sufficient size for use as radiation detectors, and there are a limited number of manufacturing facilities to produce the crystals.
  Peurrung leads PNNL’s Radiation Detection and Material Discovery Initiative, which is a three-year, $4.5 million research effort aimed at discovering new materials for radionuclide identification, accelerating discovery processes and improving our fundamental understanding of radiation detection.
  Bill Weber, a Laboratory Fellow, organized the symposium. He is a AAAS fellow and is internationally recognized for his seminal scientific contributions on the interaction of radiation with solids and radiation effects in materials. 
  The symposium was held at the 2008 AAAS Annual Meeting in Boston, Mass., on Saturday, February 16, 2008, at 10:30 a.m. Other speakers included Bill Moses, Lawrence Berkeley National Laboratory, Kanai Shah, Radiation Monitoring Services, Inc. and Lynn Boatner, Oak Ridge National Laboratory. 
  PNNL is a DOE Office of Science national laboratory that solves complex problems in energy, national security and the environment, and advances scientific frontiers in the chemical, biological, materials, environmental and computational sciences. PNNL employs 4,200 staff, has a $750 million annual budget, and has been managed by Ohio-based Battelle since the lab's inception in 1965. 

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