Difference between revisions of "PAA Bibliography"

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=References=
  
=NAA=
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==Web Sites==
  
==Ancient Silver==
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Table of isotopes
  
[[File:Meyers_Zelst_Sayre_BNL-21513.pdf]]  This paper suggest that the gold and iridium content can be used to distinguish between Sasanian (Iran) coins and other silver coins.
 
  
 +
https://www-nds.iaea.org/relnsd/vcharthtml/VChartHTML.html
  
===Activating gold===
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http://www.nndc.bnl.gov/chart/
  
====Neutron knock out====
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http://atom.kaeri.re.kr/
<math>{197 \atop\; }Au (\gamma,n){196 \atop \; }Au</math>
 
  
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http://nucleardata.nuclear.lu.se/toi/radSearch.asp
  
Au-196 decays with a half life 6.183 days of by electron capture to Platinum (Pt-196) 92% of the time or the rest of the time it Beta decay to Hg-196
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http://www-nds.iaea.org
  
The highest relative intensity gamma ray has an energy of 333.03 keV  after Au-196 undergoes electron capture. Pt-196 is stable.
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http://www.nist.gov/pml/data/xcom/index.cfm
  
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http://yoyo.cc.monash.edu.au/~simcam/ton/
  
If Pt-196 is in an excited state, then  there are two lifetimes to de-excite of 8.1 seconds and  9.6 hours .  For the 9.6 hours state then dominant intensities are a photon emission energies of 188.27 and 147.81 keV.
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www-nds.iaea.org
  
====Proton Knockout====
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coincidence finder
  
<math>{197 \atop\; }Au (\gamma,p){196 \atop \; }Pt</math>
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http://radware.phy.ornl.gov/cf.html
  
Pt-196 is naturally occurring in 25% of the Platinum
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NEA Janis data base
  
You will need to produce it in an excited state (356, 689, 877,1526 keV) in order to get a gamma.
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http://www.oecd-nea.org/janisweb/index.html
  
===Activation Iridium===
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Talys
  
There are two naturally occuring isotopes of Iridium (37% Ir-191, 63%Ir-193)
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http://www.talys.eu/home/
  
====Neutron knock out====
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==Refereed Journals==
<math>{191 \atop\; }Ir (\gamma,n){190 \atop \; }Ir</math>
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===Elemental Analysis===
  
After 11.78 days Ir-190 electron captures to Os-190 (dominant decay) with the most intense line emission of 186.68 keV.
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Abstract:
  
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Twenty six elements was studied preliminary in the superficial sediments of Havana Bay using gamma activation analysis by the electron accelerator microtron MT-25 at the Flerov Laboratory of Nuclear Reactions, JINR. Samples from five zones of Havana Bay including the three coves were analyzed. The obtained results show a close relation between the concentration levels of the studied elements and the pollution sources. Some elements (As, Ba, Ni, Pb, Cu, Zn, Fe, Cr, Mn) have high concentration levels compared to the values for other environmental marine sediments reported in the literature.
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[[File:Gelen_JRMC_V266_2005_p485.pdf]]
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===NAA Coincidence counting===
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 +
Abstract:
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A new trace-element quantification method has been developed by combining multiple gamma-ray detection and neutron activation analysis. This method is characterized by high sensitivity and simultaneous analysis for multi- elements. The quantification accuracy amounts to 3–20% depending on statistics. It has been successfully applied to the analyses of igneous rock samples, long-lived radionuclide, 129I, and geologic samples. Future perspectives for an innovative pulsed neutron source and a new detector system will be presented.
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[[File:Oshima_JNST_v39_2002_p292.pdf]]
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===Gold prospecting using plant===
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http://www.nature.com/ncomms/2013/131022/ncomms3614/full/ncomms3614.html
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===Comparison of PAA and NAA ===
 +
Abstract:
 +
 +
The potential of photon activation analysis (PAA) for multielement trace analysis can hardly compare with that of neutron activation analysis (NAA). However, PAA appears superior over NAA for the determination of a number of elements, namely C, N, O, F, Mg, Si, Ca, Ti, Ni, Sr, Y, Zr, Nb, Sn, Tl and Pb in geological, environmental and biological materials. Most of these and other elements can be determined using nondestructive, instrumental PAA (IPAA), especially in geological materials. The possibilities of IPAA for multielement analysis using photoexitation and other photonuclear reactions are reviewed and compared with those of instrumental NAA (INAA), namely for geological materials. The need for and usefulness of radiochemical PAA (RPAA) procedures are also discussed.
 +
 +
[[File:Randa_JRMC_V271_2007_p589.pdf]]
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== Books==
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===[[Segebade_Weise_Lutz_PAA]]===
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=== IAEA===
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IAEA Handbook on photo nuclear data for applications cross-sections and specta  199
 +
 +
[[File:IAEA-TECDOC-1178_pg1-91.pdf]]
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[[File:IAEA-TECDOC-1178_Appendix_B.pdf]]
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 +
 +
S. Landsberger
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Nuclear Engineering Teaching Laboratory, University of Texas, Pickle Research Campus, R-9000, Austin, TX 78712
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Radioanalytical Methods in Interdisciplinary Research
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Chapter 21, pp 307–336
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Chapter DOI: 10.1021/bk-2004-0868.ch021
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ACS Symposium Series, Vol. 868
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ISBN13: 9780841238374eISBN: 9780841219731
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Publication Date (Print): November 04, 2003
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Copyright © 2004 American Chemical Society
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 +
===Nuclear Cross Sections ===
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 +
[[File:LosAlamosManual_LL-11711-M_1989_Fisher.pdf]]
 +
 +
==Detection Limits==
 +
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http://www.i-s-r.ca/docs%5CStatisticsV14.pdf
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 +
http://holbert.faculty.asu.edu/eee460/RadiationCountingStatistics.pdf
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http://arxiv.org/abs/1301.1528v1
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 +
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http://analytics.ncsu.edu/sesug/2003/SD08-Croghan.pdf
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http://www4.nau.edu/microanalysis/Microprobe-SEM/Statistics.html
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 +
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http://depa.fquim.unam.mx/amyd/archivero/Limite_deteccion_4836.pdf
 +
 +
[[File:Meyers Zelst Sayre BNL-21513.pdf]]  suggest that the gold and iridium content can be used to distinguish between Sasanian (Iran) coins and other silver coins.
 +
 +
==Commonly measured isotopes==
 +
[[PAA_Ba-133]]
 +
 +
[[PAA_Co-60]]
 +
 +
[[PAA_Cs-137]]
 +
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[[PAA_Mn-54]]
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[[PAA_Ni-57]]
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[[PAA_Na-22]]
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[[PAA_Y-88]]
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=Other methods=
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==NAA==
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== ICP-MS==
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==ICP-OES==
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==multi-element AAS==
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=Source Certificates =
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==Mn-54 #129804 ==
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[[File:Mn-54_129804.pdf]]
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==Co-60 #124838 ==
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[[File:Co-60_124838.pdf]]
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==Na-22 #129741 ==
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[[File:Na-22_129741.pdf]]
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==Cs-137 #129792 ==
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[[File:Cs-137_129792.pdf]]
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==Ba-133 #129789 ==
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[[File:Ba-133_129789.pdf]]
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==Y-88 #12610721 ==
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[[File:Y-88_12610721.pdf]]
  
  
 
[[PAA_Research]]
 
[[PAA_Research]]

Latest revision as of 19:08, 11 January 2017

References

Web Sites

Table of isotopes


https://www-nds.iaea.org/relnsd/vcharthtml/VChartHTML.html

http://www.nndc.bnl.gov/chart/

http://atom.kaeri.re.kr/

http://nucleardata.nuclear.lu.se/toi/radSearch.asp

http://www-nds.iaea.org

http://www.nist.gov/pml/data/xcom/index.cfm

http://yoyo.cc.monash.edu.au/~simcam/ton/

www-nds.iaea.org

coincidence finder

http://radware.phy.ornl.gov/cf.html

NEA Janis data base

http://www.oecd-nea.org/janisweb/index.html

Talys

http://www.talys.eu/home/

Refereed Journals

Elemental Analysis

Abstract:

Twenty six elements was studied preliminary in the superficial sediments of Havana Bay using gamma activation analysis by the electron accelerator microtron MT-25 at the Flerov Laboratory of Nuclear Reactions, JINR. Samples from five zones of Havana Bay including the three coves were analyzed. The obtained results show a close relation between the concentration levels of the studied elements and the pollution sources. Some elements (As, Ba, Ni, Pb, Cu, Zn, Fe, Cr, Mn) have high concentration levels compared to the values for other environmental marine sediments reported in the literature.

File:Gelen JRMC V266 2005 p485.pdf

NAA Coincidence counting

Abstract:

A new trace-element quantification method has been developed by combining multiple gamma-ray detection and neutron activation analysis. This method is characterized by high sensitivity and simultaneous analysis for multi- elements. The quantification accuracy amounts to 3–20% depending on statistics. It has been successfully applied to the analyses of igneous rock samples, long-lived radionuclide, 129I, and geologic samples. Future perspectives for an innovative pulsed neutron source and a new detector system will be presented.

File:Oshima JNST v39 2002 p292.pdf

Gold prospecting using plant

http://www.nature.com/ncomms/2013/131022/ncomms3614/full/ncomms3614.html

Comparison of PAA and NAA

Abstract:

The potential of photon activation analysis (PAA) for multielement trace analysis can hardly compare with that of neutron activation analysis (NAA). However, PAA appears superior over NAA for the determination of a number of elements, namely C, N, O, F, Mg, Si, Ca, Ti, Ni, Sr, Y, Zr, Nb, Sn, Tl and Pb in geological, environmental and biological materials. Most of these and other elements can be determined using nondestructive, instrumental PAA (IPAA), especially in geological materials. The possibilities of IPAA for multielement analysis using photoexitation and other photonuclear reactions are reviewed and compared with those of instrumental NAA (INAA), namely for geological materials. The need for and usefulness of radiochemical PAA (RPAA) procedures are also discussed.

File:Randa JRMC V271 2007 p589.pdf

Books

Segebade_Weise_Lutz_PAA

IAEA

IAEA Handbook on photo nuclear data for applications cross-sections and specta 199

File:IAEA-TECDOC-1178 pg1-91.pdf File:IAEA-TECDOC-1178 Appendix B.pdf


S. Landsberger Nuclear Engineering Teaching Laboratory, University of Texas, Pickle Research Campus, R-9000, Austin, TX 78712 Radioanalytical Methods in Interdisciplinary Research Chapter 21, pp 307–336 Chapter DOI: 10.1021/bk-2004-0868.ch021 ACS Symposium Series, Vol. 868 ISBN13: 9780841238374eISBN: 9780841219731 Publication Date (Print): November 04, 2003 Copyright © 2004 American Chemical Society

Nuclear Cross Sections

File:LosAlamosManual LL-11711-M 1989 Fisher.pdf

Detection Limits

http://www.i-s-r.ca/docs%5CStatisticsV14.pdf

http://holbert.faculty.asu.edu/eee460/RadiationCountingStatistics.pdf


http://arxiv.org/abs/1301.1528v1


http://analytics.ncsu.edu/sesug/2003/SD08-Croghan.pdf


http://www4.nau.edu/microanalysis/Microprobe-SEM/Statistics.html


http://depa.fquim.unam.mx/amyd/archivero/Limite_deteccion_4836.pdf

File:Meyers Zelst Sayre BNL-21513.pdf suggest that the gold and iridium content can be used to distinguish between Sasanian (Iran) coins and other silver coins.

Commonly measured isotopes

PAA_Ba-133

PAA_Co-60

PAA_Cs-137

PAA_Mn-54

PAA_Ni-57

PAA_Na-22

PAA_Y-88

Other methods

NAA

ICP-MS

ICP-OES

multi-element AAS

Source Certificates

Mn-54 #129804

File:Mn-54 129804.pdf

Co-60 #124838

File:Co-60 124838.pdf

Na-22 #129741

File:Na-22 129741.pdf

Cs-137 #129792

File:Cs-137 129792.pdf

Ba-133 #129789

File:Ba-133 129789.pdf

Y-88 #12610721

File:Y-88 12610721.pdf


PAA_Research