[1] 郭位. 核电,雾霾,你[M]. 北京:北京大学出版社,2014. GUO W. Nuclear power,haze and you[M]. Beijing:Peking University Press,2014.
[2] 张薛,李福志,赵璇. 核电厂放射性废水调研[J]. 核安全,2015,14(3):65-70. ZHANG X,LI F Z,ZHAO X. Survey of radioactive wastewater of nuclear power plant[J]. Nuclear Safety,2015,14(3):65-70.
[3] WU L Y,ZHANG G H,WANG Q Z,et al. Removal of strontium from liquid waste using a hydraulic pellet co-precipitation microfiltration (HPC-MF) process[J]. Desalination,2014,349(5):31-38.
[4] ZHANG L,LU Y,LIU Y L,et al. High flux MWCNTs-interlinked GO hybrid membranes survived in cross-flow filtration for the treatment of strontium-containing wastewater[J]. Journal of Hazardous Materials,2016,320:187-193.
[5] DELI D,LAW K,LIU Z G,et al. Selective removal of 90Sr and 60Co from aqueous solution using N-aza-crown ether functional poly(NIPAM) hydrogels[J]. Reactive and Functional Polmers,2012,72(6):414-419.
[6] WEN T,ZHAO Z W,SHEN C C,et al. Multifunctional flexible free-standing titanate nanobelt membranes as efficient sorbents for the removal of radioactive 90Sr2+ and 137Cs+ ions and oils[J]. Scientific Reports,2016,6:20920.
[7] RAHMAN R O A,IBRAHIUM H A,HUNG YT. Liquid radioactive wastes treatment:a review[J]. Water,2011,3(4):551-565.
[8] NOYES R. Nuclear waste cleanup technology and opportunities[M]. New Jersey:Noyes Publications,1995:301-302.
[9] BAETSLE L H,HUYS D. Structure and ion-exchange characteristics of polyantimonic acid[J]. Journal of Inorganic and Nuclear Chemistry,1968,30(2):639-649.
[10] 张兰,尉继英,赵璇,等. 自掺杂型锑氧化物材料的制备、表征及其对Sr(Ⅱ)的吸附性能[J]. 物理化学学报,2014,30(10):1923-1931. ZHANG L,WEI J Y,ZHAO X,et al. Preparation,characterization and Sr(Ⅱ) adsorption performance of sel-doped antimony oxide[J]. Acta Physico:Chemica Sinica,2014,30(10):1923-1931.
[11] INAN S,NOSTAR E. Structure and ion exchange behavior of zirconium antimonates for strontium[J]. Separation Science and Technology,2013,48(9):1364-1369.
[12] CAKIR P,INAN S,ALTAS Y. Investigation of strontium and uranium sorption onto zirconium-antimony oxide/polyacrylonitrile (Zr-Sb oxide/PAN) composite using experimental design[J]. Journal of Hazardous Materials,2014,271(5):108-119.
[13] ZHANG L,WEI J Y,ZHAO X,et al. Removal of strontium (Ⅱ) and cobalt (Ⅱ) from acidic solution by manganese antimonate[J]. Chemical Engineering Journal,2016,302:733-743.
[14] ZHANG L,WEI J Y,ZHAO X,et al. Competitive adsorption of strontium and cobalt onto tin antimonate[J]. Chemical Engineering Journal,2016,285:679-689.
[15] ZHANG L,WEI J Y,ZHAO X,et al. Adsorption characteristics of strontium on synthesized antimony silicate[J]. Chemical Engineering Journal,2015,277:378-387.
[16] ZHANG L,WEI J Y,ZHAO X,et al. Strontium (Ⅱ) adsorption on Sb(Ⅲ)/Sb2O5[J]. Chemical Engineering Journal,2015,267:245-252.
[17] MOLLER T,HARJULA R,KELOKASKI P,et al. Titanium antimonates in various Ti:Sb ratios:ion exchange properties for radionuclide ions[J]. Journal of Materials Chemistry,2003,13(3):535-541.
[18] WHITE D A,LABAYRU R. Synthesis of a manganese dioxide-silica hydrous composite and its properties as a sorption material for strontium[J]. Industrial and Engineering Chemistry Research,1991,30(1):207-210.
[19] INAN S,ALTAS Y. Adsorption of strontium from acidic waste solution by Mn-Zr mixed hydrous oxide prepared by co-precipitation[J]. Separation Science and Technology,2010,45(2):269-276.
[20] PENDELYUK O I,LISNYCHA T V,STRELKO V V. Amorphous MnO2-TiO2 composites as sorbents for Sr2+ and UO22+[J]. Adsorption,2005,11(1):799-804.
[21] AHMADI S J,AKBARI N,SHIRI-YEKTA Z,et al. Removal of strontium ions from nuclear waste using synthesized MnO2-ZrO2 nano-composite by hydrothermal method in supercritical condition[J]. Korean Journal of Chemical Engineering,2015,32(3):478-485.
[22] INAN S,ALTAS Y. Preparation of zirconium-manganese oxide/polyacrylonitrile (Zr-Mn oxide/PAN)composite spheres and the investigation of Sr(Ⅱ) sorption by experimental design[J]. Chemical Engineering Journal,2011,168(3):1263-1271.
[23] 孙倩. 新型纳米材料在环境与生物传感研究中的应用[D]. 上海:华东师范大学,2011. SUN Q. Study of novel nanomaterials and their applications in environmental and biological sensing[D]. Shanghai:East China Normal University,2011
[24] CHEN C L,HU J,DI X,et al. Surface complexation modeling of Sr(Ⅱ) and Eu(Ⅲ) adsorption onto oxidized multiwall carbon nanotubes[J]. Journal of Colloid and Interface Science,2008,323(1):33-41.
[25] CHEN C L,HU J,SHAO D D,et al. Adsorption behavior of multiwall carbon nanotube/iron oxide magnetic composites for Ni(Ⅱ) and Sr(Ⅱ)[J]. Journal of Hazardous Materials,2009,164(2-3):923-928.
[26] ASADOLLAHI N,YAVARI R,GHANADZADEH H. Preparation,characterization and analytical application of stannic molybdophosphate immobilized on multiwalled carbon nanotubes as a new adsorbent for the removal of strontium from wastewater[J]. Journal of Radioanalytical and Nuclear Chemistry,2015,303(3):2445-2455.
[27] LI T T,HE F,DAI Y D. Prussian blue analog caged in chitosan surface-decorated carbon nanotubes for removal cesium and strontium[J]. Journal of Radioanalytical and Nuclear Chemistry,2016,310(3):1-7.
[28] THESS A,LEE R,NIKOLAEV P,et al. Crystalline ropes of metallic carbon nanotubes[J]. Science,1996,273(5274):483-487.
[29] CHIANG I W,BRINSON B E,SMALLEY R E,et al. Purification and characterization of single-wall carbon nanotubes[J]. Journal of Physical Chemistry B,2012,105(6):1157-1161.
[30] PLATA D L,GSCHWEND P M,REDDY C M. Industrially synthesized single-walled carbon nanotubes:compositional data for users,environmental risk assessments,and source apportionment[J]. Nanotechnology,2008,19(18):185706.
[31] HONG B H. Centimeter scale pattern growth of graphene films for stretchable transparent electrodes[J]. Nature,2009,457(7230):706-710.
[32] CHAI L Y,WANG T,ZHANG L Y,et al. A Cu-m-phenylenediamine complex induced route to fabricate poly(m-phenylenediamine)/reduced graphene oxide hydrogel and its adsorption application[J]. Carbon,2015,81(1):748-757.
[33] SUI N,WANG L,WU X H,et al. Polyethylenimine modified magnetic graphene oxide nanocomposites for Cu2+ removal[J]. RSC Advances,2014,5(1):746-752.
[34] LIU L,ZHANG Y,HE Y,et al. Preparation of montmorillonite-pillared graphene oxide with increased single-and co-adsorption towards lead ions and methylene blue[J]. RSC Advances,2014,5(6):3965-3973.
[35] YANG S B,CHEN C L,CHEN Y,et al. Competitive adsorption of Pb,Ni,and Sr ions on graphene oxides:a combined experimental and theoretical Study[J]. ChemPlusChem,2015,80(3):480-484.
[36] ZHAO Y G,GUO C,FANG H,et al. Competitive adsorption of Sr(Ⅱ) and U(Ⅵ) on graphene oxide investigated by batch and modeling techniques[J]. Journal of Molecular Liquids,2016,222:263-267.
[37] ROMANCHUK A Y,SLESAREV A S,KALMYKOV S N,et al. Graphene oxide for effective radionuclide removal[J]. Physical Chemistry Chemical Physics,2013,15(7):2321-2327.
[38] WEN T,WU X L,LIU M C,et al. Efficient capture of strontium from aqueous solutions using graphene oxide-hydroxyapatite nanocomposites[J]. Dalton Transactions,2014,43(20):7464-7472.
[39] CHEN H,SHAO D D,LI J X,et al. The uptake of radionuclides from aqueous solution by poly(amidoxime) modified reduced graphene oxide[J]. Chemical Engineering Journal,2014,254:623-634.
[40] SUN Y B,SHAO D D,CHEN C L,et al. Highly efficient enrichment of radionuclides on graphene oxide-supported polyaniline[J]. Environmental Science and Technology,2013,47(17):9904-9910.
[41] CHEN H,LI J X,ZHANG S W,et al. Study on the acid-base surface property of the magnetite graphene oxide and its usage for the removal of radiostrontium from aqueous solution[J]. Radiochimica Acta,2013,101(12):785-794.
[42] DING N,KANATZIDIS M G. Selective incarceration of caesium ions by Venus flytrap action of a flexible framework sulfide[J]. Nature Chemistry,2010,2(3):187-191.
[43] MANOS M J,IYER R G,QUAREZ E,et al. {Sn[Zn4Sn4S17] }6-:A robust open framework based on metal-linked penta-supertetrahedral[Zn4Sn4S17] 10-clusters with ion-exchange properties[J]. Angewandte Chemie-International Edition,2005,44(23):3552-3555.
[44] MANOS M J,KANATZIDIS M G. Metal sulfide ion exchangers:superior sorbents for the capture of toxic and nuclear waste-related metal ions[J]. Chemical Science,2016,7(8):4804-4824.
[45] MANOS M J,DING N,KANATZIDIS M G. Layered metal sulfides:Exceptionally selective agents for radioactive strontium removal[J]. Proceedings of the National Academy of Sciences of the United States of America,2008,105(10):3696-3699.
[46] MERTZ J L,FARD Z H,MALLIAKAS C D,et al. Selective removal of Cs+,Sr2+,and Ni2+ by K2xMgxSn3-xS6(x=0.5-1)(KMS-2) relevant to nuclear waste remediation[J]. Chemistry of Materials,2013,25(10):2116-2127.
[47] SARMA D,MALLIAKAS C D,SUBRAHMANYAM K S,et al. K2xSn4-xS8-x (x=0.65-1):a new metal sulfide for rapid and selective removal of Cs+,Sr2+ and UO22+ ions[J]. Chemical Science,2016,7(2):1121-1132.
[48] QI X H,DU K Z,FENG M L,et al. A two-dimensionally microporous thiostannate with superior Cs+ and Sr2+ ion-exchange property[J]. Journal of Materials Chemistry A,2015,3(10):5665-5673.
[49] CHEGROUCHE S,MELLAH A,BARKAT A. Removal of strontium from aqueous solutions by adsorption onto activated carbon:kinetic and thermodynamic studies[J]. Desalination,2009,235(1-3):306-318.
[50] PARK Y,LEE Y C,SHIN W S,et al. Removal of cobalt,strontium and cesium from radioactive laundry wastewater by ammonium molybdophosphate-polyacrylonitrile (AMP-PAN)[J]. Chemical Engineering Journal,2010,162(2):685-695.
[51] HANDLEY-SIDHU S,MULLAN T K,GRAIL Q,et al. Influence of pH,competing ions,and salinity on the sorption of strontium and cobalt onto biogenic hydroxyapatite[J]. Scientific Reports,2016,6:23361.
[52] DYER A,PILLINGER M,NEWTON J,et al. Sorption behavior of radionuclides on crystalline synthetic tunnel manganese oxides[J]. Chemistry of Materials,2000,12(12):3798-3804.
[53] BORTUN A I,BORTUN L N,CLEARFIELD A. Evalution of synthetic inorganic ion exchangers for cesium and strontium removal from contaminated groundwater and wastewater[J]. Solvent Extraction and Ion Exchange,1997,15(5):909-929.
[54] FAN Q H,ZHAN L,ZHAO H G,et al. Adsorption of Pb(Ⅱ) on palygorskite from aqueous solution:effects of pH,ionic strength and temperature[J]. Applied Clay Science,2009,45(3):111-116.
[55] BENHAMMOU A,YAACOUBI A,NIBOU L,et al. Adsorption of metal ions onto Moroccan stevensite:kinetic and isotherm studies[J]. Journal of Colloid and Interface Science,2005,282(2):320-326.
[56] WANG Y X,LI J R,YANG J C E,et al. Granulous KMS-1/PAN composite for Cs+ removal[J]. RSC Advances,2015,5(111):91431-91435.
[57] KANATZIDIS M G,SARMA D,MANOS E. Column material for the capture of heavy metal and precious metal ions:WO 2015/080976 A1[P]. 2015-06-04.
[58] FARD Z H,ISLAM S M,KANATZIDIS M G. Porous amorphous chalcogenides as selective adsorbents for heavy metals[J]. Chemistry of Materials,2015,27(18):6189-6192.
[59] HOEFS J. Stable isotope geochemistry[M]. 7th ed. Gottingen:Springer International Publishing,2015:4.
[60] HUANG C P,LIN T Y,CHIAO L H,et al. Characterization of radioactive contaminants and water treatment trials for the Taiwan Research Reactor's spent fuel pool[J]. Journal of Hazardous Materials,2012,233:140-147.
[61] 朱琳,张伟,本志米. 改性前后硅藻土对Sr(Ⅱ)的吸附比较[J]. 广州化工,2011,39(20):52-53. ZHU L,ZHANG W,BEN Z M. Removal of strontium (Ⅱ) from aqueous solutions by natural and modified diatomite[J]. Guangzhou Chemical Industry,2011,39(20):52-53.
[62] SHAWABKEH R A,ROCKSTRAW D A,BHADA R K. Copper and strontium adsorption by a novel carbon material manufactured from pecan shells[J]. Carbon,2002,40(5):781-786.
[63] TAMURA K,KOGURE T,WATANABE Y,et al. Uptake of cesium and strontium ions by artificially altered phlogopite[J]. Environmental Science and Technology,2014,48(10):5808-5815.
[64] EL-KAMASH A M. Evaluation of zeolite A for the sorptive removal of Cs+ and Sr2+ ions from aqueous solutions using batch and fixed bed column operations[J]. Journal of Hazardous Materials,2008,151(2/3):432-445. |