燃烧仪部分文章

燃烧仪部分文章

时间:2021-11-01   阅读:

生物氧化仪部分引用文献

Tritium Papers
1. Lewis A., Warwick P.E. & Croudace I.W. (2005). Penetration of tritium (as tritiated water vapour)
into low carbon steel and remediation using abrasive cleaning. J. Radiol. Prot., 25, 161-168.
2. Hong S.B., Kim H.R., Chung K.H., Park J.H. (2007). Depth distribution of H-3, C-14 and Co-60 in
decommissioning of the biological shielding concrete of KRR-2. Conference proceedings, WM’07, 25 Feb –
1st March 2007, Tucson, USA.
3. Oh J-S, Warwick PE, Croudace IW and Kim D-J (2007) An efficient and optimized method for total H-3 and C-
14 in environmental and decommissioning samples. In Warwick P (Ed) Environmental Radiochemical
Analysis III, Special Publication, Royal Society of Chemistry, 101-107.
4. Kim D-J, Croudace IW & Warwick PE (2007) The impact of sample storage conditions on tritium analysis. In
Warwick P (Ed) Environmental Radiochemical Analysis III, Special Publication, Royal Society of Chemistry, 108-
115.
5. Kim D-J., Warwick P.E. & Croudace I.W. (2008). Tritium speciation in nuclear reactor bioshield concrete and
its impact on accurate analysis. Anal. Chem., 80, 5476 – 5480.
6. Warwick P.E., Kim D. Croudace I.W. & Oh J. (2010). Effective desorption of tritium from diverse solid
matrices and its application to routine analysis of decommissioning materials. Anal. Chim. Acta, 676, 93-
102.
7. Croudace IW, Warwick PE and Marsh R. (2011) Advances in tritium extraction methods to aid efficient waste
characterisation. Nuclear Future, 7, 48-53.
8. Croudace, Ian W., Warwick, Phillip E. and Morris, Jenny E (2012) Evidence for the preservation of
technogenic tritiated organic compounds in an estuarine sedimentary environment. Environ. Sci. Technol.,
46, 4704-5712.
9. Kim H R., Kang M.J. & Choi G.S. (2011). An experiment on the radioactivity characterization of the tritium
contaminated metal sample. Annals Nucl. Energy, 38, 1074 – 1077.
10. Kim D-J., Croudace I.W. & Warwick P.E. (2012). The requirement for proper storage of nuclear and related
decommissioning samples to safeguard accuracy of tritium data. J. Haz. Mat, 213 – 214, 292-298.
11. Kim S.B., Baglan N. & Davis P.A. Current understanding of organically-bound tritium (OBT) in the
environment. J. Env. Rad., 126, 83 – 91.
12. Oh J-S., Warwick P.E., Croudace I.W. & Lee S-H. (2014) Rapid determination of tritium and carbon-14 in
urine samples using a combustion technique. J. Radioanal. Nucl. Chem., i299, 187 - 191.
13. Croudace I.W, Warwick P.E. Kim D-J., (2014). Using thermal evolution profiles to infer tritium speciation in
nuclear site metals: an aid to decommissioning. Anal. Chem., 86, 9177 – 9185.
14. Lim J.M., Kang M.J., Chung K.H., Kim C.J. & Choi G.S. (2015). Application of a high temperature tube furnace
and liquid scintillation counter for radioactivity determination of 14C and 3H in solid waste samples. J.
Radioanal. Nucl. Chem., 303, 1111 – 1115.
15. Croudace I.W., Warwick P.E. & Marsh R. (2017). A suite of robust radioanalytical techniques for the
determination of tritium and other volatile radionuclides in decommissioning wastes and environmental
matrices. Fusion Sci. Technol., 71, 290 – 295
16. Marsh RI, Croudace IW, Warwick PE, Cooper N, and St-Amant N (2017) A new bomb-combustion system for
tritium extraction Journal of Radioanalytical and Nuclear Chemistry, 314, 651–658.
17. Baglan N., Cossonnet C., Roche E., Kim S-B., Croudace I.W. & Warwick P.E. (2018). Feedback of the third
interlaboratory exercise organised on wheat in the framework of the OBT working group. J. Env. Rad., 181,
52 – 61.
18. Warwick P.E., Croudace I.W., Marsh R.M., Baglan, N. & Kim S. B (2018). A new reference material for tritium
organic molecules in sediment: results of an international intercomparison exercise. Geostandards and
Geoanalytical Res. 42, 253-262.
19. S. Rashmi Nayak · Renita Shiny D’Souza · S. Srinivas Kamat · M. P. Mohan · S. Bharath · Trilochana Shetty
K. Sudeep Kumara · B. Narayana1 ·B. N. Dileep · P. M. Ravi · N. Karunakara (2019) Organically bound
tritium: optimization of measurements in environmental matrices by combustion method and liquid
scintillation spectrometry J Radioanal Nucl Chem, 319:917–926.
2
Carbon-14 Papers
1. Hong S.B., Kim H.R., Chung K.H., Park J.H. (2007). Depth distribution of H-3, C-14 and Co-60 in
decommissioning of the biological shielding concrete of KRR-2. Conference proceedings, WM’07, 25 Feb –
1st March 2007, Tucson, USA.
2. Blowers, Paul, Caborn, Jane, Dell, Tony, Gingell, Terry, Harms, Arvic, Long, Stephanie, Sleep, Darren,
Stewart, Charlie, Walker, Jill and Warwick, Phil E. (2011) Determination of carbon-14 in environmental level,
solid reference materials. Appl. Radiat. Isot., 69, (10), 1323-1329.
3. Oh J-S., Warwick P.E., Croudace I.W. & Lee S-H. (2014) Rapid determination of tritium and carbon-14 in
urine samples using a combustion technique. J. Radioanal. Nucl. Chem., i299, 187 - 191.
4. Lim J.M., Kang M.J., Chung K.H., Kim C.J. & Choi G.S. (2015). Application of a high temperature tube furnace
and liquid scintillation counter for radioactivity determination of 14C and 3H in solid waste samples. J.
Radioanal. Nucl. Chem., 303, 1111 – 1115.
Iodine-129 Papers
1. Hou, X., Zhou, W.J., Chen, N., Zhang, L., Liu, Q., 2010. Determination of ultralow level 129I/127I in natural
samples by separation of microgram carrier free iodine and AMS determination, Anal. Chem., 82, 7713-7721.
2. Zhou, W.J., Hou, X., Chen, N., Zhang, L.Y., Liu, Q., He, C.H., Luo, M.Y., Liang, W.G., Fan, Y.K., Wang, Z.W., Fu,
Y.C., Li, H.B., 2010. Preliminary study of radioisotope 129I application in China using Xi’an accelerator mass
spectrometer. ICNS News 25, 8–23.
3. Zhang, L., Zhou, W.J., Hou, X., Chen, N., Liu, Q., He, C., Fan, Y., Luo, M., Wang, Z., Fu, Y., 2011. Level and
source of I-129 of environmental samples in Xi’an region, China. Sci. Total Environ. 409, 3780–3788.
4. Luo, M., Hou, X., Zhou, W.J., He, C., Chen, N., Liu, Q., Zhang, L., 2013. Speciation and migration of 129I in soil
profiles. J. Environ. Radioact. 118, 30–39.
5. Fan, Y., Hou, X., Zhou, W., Liu, G., 2016. I record of nuclear activities in marine sediment core from Jiaozhou
Bay in China. J. Environ. Radioact. 154, 15–24.
6. Hou, X., Wang, Y., 2016. Determination of ultra-low level 129I in vegetation using pyrolysis for iodine
separation and accelerator mass spectrometry measurement. J. Anal. At. Spectrom.
7. Xue Zhao, Xiaolin Hou, Du Jinzhou, Yukun Fan (2018) Anthropogenic 129I in the sediment cores in the East
China Sea: sources and transport pathway. Environmental Pollution.
PhD / Masters theses
1. Morris J (2001) PhD - Mechanisms of accumulation of organically-bound tritium in the estuarine
environment. PhD Supervisors: Croudace and Warwick.
2. Kim D-J (2005) PhD - Fundamental studies of methods for tritium analysis in environmental and
construction materials. PhD Supervisors: Croudace, and Warwick.
3. Marsh R (2006) PhD - Development of rapid and novel techniques for tritium extraction and analysis. PhD
Supervisors: Croudace, and Warwick
4. Fan, Y. (2013). PhD - Spatial distribution of 129I in Chinese surface soil and preliminary study on the 129I
chronology. Institute of Earth Environment, Chinese Academy of Sciences.
5. Wang, Y. (2016). MSc -129I in vegetation samples from Northwest of China. Institute of Earth Environment,
Chinese Academy of Sciences.




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