TY - GEN
T1 - A microfabricated electrostatic field desorption ion source
AU - Hertz, Kristin L.
AU - Johnson, Benjamin B.
AU - Holland, Christopher E.
AU - Resnick, Paul J.
AU - Schwoebel, Paul R.
AU - Chichester, David L.
PY - 2012
Y1 - 2012
N2 - The use of an electrostatic field desorption (EFD) ion source would constitute a significant advance in the design and operation of neutron generators. The results would directly benefit the use of neutron generators for active interrogation in the search for special nuclear material and the replacement of radioisotopic sources, particularly in man-portable scenarios. The novel EFD approach uses high electrostatic fields to produce pure atomic deuterium ions from a conductive surface, rather than ions produced from deuterium plasma. This concept has the potential to surpass current state of the art sealed neutron tube designs in many key performance areas including lifetime, reliability, efficiency, and neutron yield. Over the past few years a thorough study of the ion production and neutron yield of fabricated devices has been conducted. Devices that are 1 mm2 consistently produce approximately 1000 n/cm2/s from the deuteron-deuteron reaction when operating in the dc mode. Electric fields of 20 V/nm are consistently achieved resulting in molecular deuterium ions from field ionization. Further increases in electric fields are necessary to reliably produce deuterons from field desorption. Both the modeling and experimental results to date are discussed.
AB - The use of an electrostatic field desorption (EFD) ion source would constitute a significant advance in the design and operation of neutron generators. The results would directly benefit the use of neutron generators for active interrogation in the search for special nuclear material and the replacement of radioisotopic sources, particularly in man-portable scenarios. The novel EFD approach uses high electrostatic fields to produce pure atomic deuterium ions from a conductive surface, rather than ions produced from deuterium plasma. This concept has the potential to surpass current state of the art sealed neutron tube designs in many key performance areas including lifetime, reliability, efficiency, and neutron yield. Over the past few years a thorough study of the ion production and neutron yield of fabricated devices has been conducted. Devices that are 1 mm2 consistently produce approximately 1000 n/cm2/s from the deuteron-deuteron reaction when operating in the dc mode. Electric fields of 20 V/nm are consistently achieved resulting in molecular deuterium ions from field ionization. Further increases in electric fields are necessary to reliably produce deuterons from field desorption. Both the modeling and experimental results to date are discussed.
UR - http://www.scopus.com/inward/record.url?scp=84881587045&partnerID=8YFLogxK
U2 - 10.1109/NSSMIC.2012.6551349
DO - 10.1109/NSSMIC.2012.6551349
M3 - Conference contribution
AN - SCOPUS:84881587045
SN - 9781467320306
T3 - IEEE Nuclear Science Symposium Conference Record
SP - 1434
EP - 1439
BT - 2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record, NSS/MIC 2012
T2 - 2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record, NSS/MIC 2012
Y2 - 29 October 2012 through 3 November 2012
ER -