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Nd2Zr2O7烧绿石因其稳定的物理化学性质和辐照稳定性可以作为高放废物中锕系核素的固化基材.通过溶胶凝胶–喷雾热解–高温烧结方法制备了含铀的Nd2Zr2O7烧绿石固化体;开展了Nd2Zr2O7和Nd1.9U0.1Zr2O7固化体的重离子辐照实验,辐照剂量为1 dpa和3 dpa;利用X射线衍射和Raman光谱对固化体结构进行了分析.研究发现铀在Nd2Zr2O7烧绿石体系的固溶量仅为10 at%,高价态铀掺杂导致固化体结构向无序化转变.重离子辐照实验表明,Nd2Zr2O7烧绿石基材具有较高的抗辐照稳定性;而Nd1.9U0.1Zr2O7在较低辐照剂量下,固化体烧绿石体系结构破坏,重离子辐照诱导固化体结构转变为更加无序化的萤石结构.低固溶量和抗辐照能力减弱主要是由于锕系核素烧绿石固化体的结构无序化所致.Nd2Zr2O7 pyrochlore with higher physicochemical and radiation stability has been considered as a host matrix for actinide immobilization of high level radioactive wastes. Uranium is a constituent and the decay-daughter product of high level radioactive wastes. It is necessary to study the solubility and ion-irradiation effect of uranium in Nd2Zr2O7 pyrochlore. The solubility of U is studied by the A site substitution in the pyrochlore structure. A series of uranium-doped zirconate pyrochlore compositions is prepared by the sol-gel-spray pyrolysis-high temperature sintering method. The structures of immobilization are studied by using X-ray diffraction (XRD) and Raman spectroscopy. The XRD and Raman spectroscopy studies reveal that the solubility limit of uranium in Nd2Zr2O7 is estimated at 10 at%. The lattice parameter of pyrochlore decreases with U content increasing, which is due to lower ionic radius of U. The immobilization structure changes from order pyrochlore to disorder structure. Further addition of U content leads to the separation of U3O8 phase in the immobilization. The U ions with high valance may be substituted at A or B site in Nd2Zr2O7 pyrochlore, which results in the A–O and B–O bond destruction. In order to keep the balance of charge, extra O ions should enter into the vacancy site, the structure of pyrochlore maybe transforms into a disorder structure. The radiation resistance of immobilization is investigated by ion-beam irradiation with 2 MeV Kr15+ ions at room temperature. The Nd2Zr2O7 and Nd1.9U0.1Zr2O7 are irradiated at doses of 1 dpa and 3 dpa, respectively. Analyses of the XRD and Raman spectroscopy data show that the Nd2Zr2O7 pyrochlore remains full pyrochlore structure even at a higher irradiation dose, which suggests that the Nd2Zr2O7 exhibits higher radiation resistance as potential immobilization. In contrast, the Nd1.9U0.1Zr2O7 immobilization shows the weaker radiation resistance, the pyrochlore structure completely transforms into a disorder fluorite structure. The A–O and B–O bonds of Nd1.9U0.1Zr2O7 pyrochlore structure are easy to destroy under ion irradiation conditions due to the disorder of pyrochlore. At the same time, the excess O ions are rearranged in U-rich pyrochlore after irradiation. Bond destruction and ion rearrangement of pyrochlore structure result in the full disorder fluorite structure. The actinides-doped pyrochlore structure is modified due to the change in physicochemical propertyof actinide, which results in the reductionof the solubility limit and radiation resistance.
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Keywords:
- uranium /
- pyrochlore /
- solubility /
- ion-irradiation effects
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[19] Wang L L, Xie H, Chen Q Y, Wang Q, Deng C, Long Y (in Chinese) [王烈林, 谢华, 陈青云, 王茜, 邓超, 龙勇 2015 原子能科学技术 49 1012]
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[1] Ewing R C 1994 IAEA SR. 186 32
[2] Luo S G, Yang J W, Zhu X Z 2000 Acta Chim. Sin. 58 1608 (in Chinese) [罗上庚, 杨建文, 朱鑫璋 2000 化学学报 58 1608]
[3] Alain C, Constantin M 2003 Phys. Rev. B 67 174102
[4] Ewing R C 2005 Earth Planet Sci. Lett. 229 165
[5] Weber W J, Ewing R C 2000 Science 289 2051
[6] Sickafus K E, Minervini L, Grimes R W, Valdez J A, IshimaruM, Li F, McClellan K J, Hartmann T 2000 Science 289 478
[7] Wang S X, Begg B D, Wang L M, Ewing R C, Weber W J, Kutty KV G 1999 J. Mater. Res. 14 4470
[8] Chakoumakos B C, Ewing R C 1985 Mater. Res. Soc. Symp. Proc. 44 641
[9] Belin R C, Valenza P J, Raison P E, Tillard M 2008 J. Alloy. Compd. 448 321
[10] Kulkarni N K, Sampath S, Venugopal V 2000 J. Nucl. Mater. 281 95
[11] Yamazaki S, Yamashita T, Matsui T, Takanori N 2001 J. Nucl. Mater. 294 183
[12] Lian J, Zu X T, Kutty K V G, Chen J, Wang L M, Ewing R C 2002 Phys. Rev. B 66 054108
[13] Kutty K V G, Asuvathraman R, Madhavan R R, Hrudananda J 2005 J. Phys. Chem. Solids 66 596
[14] Vandenborre M T, Husson E, Chatry J P, Michel D 1983 J. Raman Spectrosc. 14 63
[15] Brown S, Gupta H C, Alonso A J, Martínez-Lope M J 2004 Phys. Rev. B 69 054434
[16] Mandal B P, Pandey M, Tyagi A K J 2010 J. Nucl. Mater. 406 238
[17] Lang M, Zhang F X, Ewing R C, LianJ, Christina T, Wang Z W 2009 J. Mater. Res. 24 1322
[18] Zhao M Z, Simon C, Middleburgh, Massey D L R, Lumpkin G R, Brendan J K, Peter E R B, Emily R 2013 J. Phys. Chem. C 117 26740
[19] Wang L L, Xie H, Chen Q Y, Wang Q, Deng C, Long Y (in Chinese) [王烈林, 谢华, 陈青云, 王茜, 邓超, 龙勇 2015 原子能科学技术 49 1012]
[20] Begg B D, Hess N J, McCready D E, Thevuthasanb S, Weber W J 2001 J. Nucl. Mater. 289 188
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