Abstract:This paper reviewed effects of calcareous materials (mainly including CaO, Ca(OH)2 and CaCO3, and others) on soil physicochemical properties (pH, composition and content of soil organic matter), microbial community, and As bioavailability, including impacts on As tolerance in plants, uptake and accumulation of As by plants. The review can provide theoretical and technical references for accurately understanding mechanisms under effects of calcareous materials on As bioavailability in soils and uptake and accumulation of As by plants, and then contribute to rationally select calcareous materials to improve soil physicochemical properties and reduce As bioavailability and its environmental risks in soils. It has certain practical significances for ensuring planting safety and food safety in agricultural field.
马晟, 杨晓莉, 刘朝柱, 徐其静, 刘雪. 三种含钙物质对土壤砷植物有效性的影响[J]. 中国环境科学, 2022, 42(12): 5785-5795.
MA Sheng, YANG Xiao-li, LIU Chao-zhu, XU Qi-jing, LIU Xue. Effects of three calcium substances on plant bioavailability of arsenic in soil. CHINA ENVIRONMENTAL SCIENCECE, 2022, 42(12): 5785-5795.
曹烨,孙小虹,唐尧,等.中国砷矿成矿规律概要[J]. 地质论评, 2015,61(S1):806-807. Cao Y, Sun X H, Tang Y, et al. Summary of metallogenic regularity of arsenic deposits in China[J]. Geological Review, 2015,61(S1):806-807.
[2]
肖细元,陈同斌,廖晓勇,等.中国主要含砷矿产资源的区域分布与砷污染问题[J]. 地理研究, 2008,(1):201-212. Xiao S Y, Chen T B, Liao X Y., et al. Regional distribution of arsenic contained minerals and arsenic pollution in China[J]. Geographical Studies, 2008,(1):201-212.
[3]
宣之强.中国砷矿资源概述[J]. 化工矿产地质, 1998,20(3):8-14. Xuan Z Q. A brief account of Chinese arsenic resources[J]. Chemical Mineral Geology, 1998,20(3):8-14.
[4]
毕伟东,王成艳,王成贤.砷及砷化物与人类疾病[J]. 微量元素与健康研究, 2002,19(2):76-79. Bi W D, Wang C Y, Wang C H. Arsenic and arsenicals and human diseases[J]. Trace Elements and Health Research, 2002,19(2):76-79.
[5]
李慧,张立实.砷的毒性与生物学功能[J]. 现代预防医学, 2000,27(1):39-40. Li H, Zhang L S. Toxicity and biological functions of arsenic[J]. Modern Preventive Medicine, 2000,27(1):39-40.
[6]
丁琪琪,龚雄虎,王兆德,等.基于多指标综合评分法筛选地表水环境优先污染物-以湖北涨渡湖为例[J]. 湖泊科学, 2022,34(1):90-108. Ding Q Q, Gong X H, Wang ZD, et al. Screening of priority pollutants in surface water environment based on multi-index comprehensive scoring method-taking Zhangdu lake in Hubei province as an example[J]. Journal of Lake Science, 2022,34(1):90-108.
[7]
李嘉琦,左平春,李仓敏,等.我国城市空气中有毒有害污染物暴露分析[J]. 中国环境监测, 2019,35(1):59-74. Li J Q, Zuo P C, Li C M, et al. Exposure analysis of hazardous air pollutants in urban China[J]. Environmental Monitoring in China, 2019,35(1):59-74.
[8]
张丽丽,朱晓晶,于洋,等.京津冀及周边地区优先控制有毒有害大气污染物名录研究[J]. 环境科学研究, 2021,34(1):194-201. Zhang L L, Zhu X J, Yu Y, et al. Priority control of hazardous air pollutants in Beijing-Tianjin-Hebei and its surrounding areas[J]. Research of Environmental Sciences, 2021,34(1):194-201.
[9]
全国土壤污染状况调查公报[J]. 中国环保产业, 2014,(5):10-11. Bulletin of national soil pollution survey[J]. China Environmental Protection Industry, 2014,(5):10-11.
[10]
张建斌,丁建华,南格利.中国锡矿资源特征及主要远景区潜力分析[J]. 中国地质, 2015,42(4):839-852. Zhang J B, Ding J H, Nan G L. Tin resource characteristics and potential analysis of main prospective areas in China[J]. China Geology, 2015,42(4):839-852.
[11]
金晓丹,罗栋源,马华菊,等.广西某铅锌矿区土壤镉、铅、砷形态分布对水稻重金属的影响[J]. 西南农业学报, 2018,31(6):1293-1299. Jin X D, Luo D Y, Ma H J, et al. Effects of speciation distribution of cadmium, lead and arsenic in soil on heavy metals in rice in a lead-zinc mine area of Guangxi[J]. Southwest Agricultural Journal, 2018,31(6):1293-1299.
[12]
崔星怡,秦俊豪,李智鸣,等.不同品种空心菜对重污染土壤砷的吸收累积及其亚细胞分布[J]. 农业环境科学学报, 2017,36(1):24-31. Cui X Y, Qin J H, Li Z M, et al. Accumulation and subcellular distribution of arsenic in water spinach (Ipomoea aquatica) cultivars from arsenic contaminated soil[J]. Journal of Agro-Environment Science, 2017,36(1):24-31.
[13]
肖冰,薛培英,韦亮,等.基于田块尺度的农田土壤和小麦籽粒镉砷铅污染特征及健康风险评价[J]. 环境科学, 2020,41(6):2869-2877. Xiao B, Xue P Y, Wei L, et al. Pollution characteristics and health risk assessment of cadmium, arsenic, and lead in farmland soil and wheat grain based on field scale[J]. Environmental Science, 2020,41(6):2869-2877.
[14]
刘思洁,王慧,王博,等.吉林省主要食品中砷污染状况及居民膳食暴露风险评估[J]. 中国食品卫生杂志, 2018,30(6):645-649. Liu S J, Wang H, Wang B, et al. Arsenic contamination in main foods and the dietary exposure assessment for the population of Jilin Province, China[J]. Chinese Journal of Food Hygiene, 2018,30(6):645-649.
[15]
刘辉,黄利明,印晓虹.居民膳食砷摄入水平调查[J]. 浙江预防医学, 2015,27(6):547-550,571. Liu H, Huang L M, Yin X H. An analysis on the dietary arsenic intake level among residents in Hangzhou city[J]. Zhejiang Prevention Medicine, 2015,27(6):547-550,571.
[16]
Lee J S, Lee S W, Chon H T, et al. Evaluation of human exposure to arsenic due to rice ingestion in the vicinity of abandoned Myungbong Au-Ag mine site, Korea[J]. Journal of Geochemical Exploration, 2008,96(2/3):231-235.
[17]
陈德伟,汤寓涵,石文波,等.钙调控植物生长发育的进展分析[J]. 分子植物育种, 2019,17(11):3593-3601. Chen D W, Tang Y H, Shi W B, et al. 2019, Progress in the regulation of calcium growth and development[J]. Molecular Plant Breeding, 17(11):3593-3601.
[18]
张和臣,尹伟伦,夏新莉.非生物逆境胁迫下植物钙信号转导的分子机制[J]. 植物学通报, 2007,(1):114-122. Zhang H C, Yin W L, Xia X L. The mechanism of Ca2+ signal transduction under abiotic stresses in plants[J]. Chinese Bulletin of Botany, 2007,(1):114-122.
[19]
张信宝,王世杰,曹建华.西南喀斯特山地的土壤硅酸盐矿物物质平衡与土壤流失[J]. 地球与环境, 2009,37(2):97-102. Zhang X B, Wang S J, Cao J H. Mass balance of silicate minerals in soils and soil losses in the karst mountainous regions of southwest China[J]. Earth and Environment, 2009,37(2):97-102.
[20]
余海,王世杰.土壤中钙形态的连续浸提方法[J]. 岩矿测试, 2007,26(6):436-440. Yu H, Wang S J. Continuous leaching method for calcium morphology in soil[J]. Rock and Mineral Analysis, 2007,26(6):436-440.
[21]
陈青松,舒英格,周鹏鹏,等.喀斯特山区不同生态恢复下石灰土钙形态特征[J]. 水土保持学报, 2020,34(4):48-55. Chen Q S, Shu Y G, Zhou P P, et al. Morphological characteristics of lime soil calcium under different ecological restorations in karst mountainous areas[J]. Soil and Water Conservation Journal, 2020, 34(4):48-55.
[22]
李丽辉,王宝禄.云南省土壤As、Cd元素地球化学特征[J]. 物探与化探, 2008,(5):497-501. Li L H, Wang B L. Geochemical characteristics of soil As and Cd elements in Yunnan Province[J]. Geophysical & Geochemical Exploration, 2008,(5):497-501.
[23]
姚冬菊,刘恩光,宁增平,等.贵州某锑冶炼厂周边农田土壤锑、砷污染与人体健康风险评估[J]. 地球与环境, 2021,49(6):673-683. Yao D J, Liu E G, Ning Z P, et al. Antimony and arsenic pollution and human health risk assessment of farmland soil around an antimony smelter in Guizhou[J]. Earth and Environment, 2021,49(6):673-683.
[24]
曹胜,欧阳梦云,周卫军,等.石灰对土壤重金属污染修复的研究进展[J]. 中国农学通报, 2018,34(26):109-112. Cao S, Ouyang M Y, Zhou W J, et al. Research progress on remediation of soil heavy metal pollution by lime[J]. China Agricultural Bulletin, 2018,34(26):109-112.
[25]
王立群,罗磊,马义兵,等.重金属污染土壤原位钝化修复研究进展[J]. 应用生态学报, 2009,20(5):1214-1222. Wang L Q, Luo L, Ma Y B, et al. In situ immobilization of heavy metals in contaminated soils:A review[J]. Chinese Journal of Applied Ecology, 2009,20(5):1214-1222.
[26]
周娟,袁珍贵,郭莉莉,等.土壤酸化对作物生长发育的影响及改良措施[J]. 作物研究, 2013,27(1):96-102. Zhou J, Yuan Z Z, Guo L L, et al. Effects of soil acidification on crop growth and development and improvement measures[J]. Crop Research, 2013,27(1):96-102.
[27]
周晓阳,徐明岗,周世伟,等.长期施肥下我国南方典型农田土壤的酸化特征[J]. 植物营养与肥料学报, 2015,21(6):1615-1621. Zhou X Y, Xu M G, Zhou S W, et al. Soil acidification characteristics in southern China's croplands under long-term fertilization[J]. Journal of Plant Nutrition and Fertilizer, 2015,21(6):1615-1621.
[28]
赵占周.施用石灰类物质改良酸性土壤的原理与方法[J]. 西北园艺(果树), 2020,(4):33-36. Zhao Z Z. Principles and methods of application of lime to improve acidic soil[J]. Northwest Horticulture(Fruit Trees), 2020,(4):33-36.
[29]
Beckie H J, Ukrainetz H. Lime-amended acid soil has elevated pH 30years later[J]. Canadian Journal of Soil Science, 1996,76(1):59-61.
[30]
Frank T, Zimmermann I, Horn R. Lime application in marshlands of Northern Germany-Influence of liming on the physicochemical and hydraulic properties of clayey soils[J]. Soil & Tillage Research, 2020,204:104730.
[31]
钟倩云,曾敏,廖柏寒,等.碳酸钙对水稻吸收重金属(Pb、Cd、Zn)和As的影响[J]. 生态学报, 2015,35(4):1242-1248. Zhong Q Y, Zeng M, Liao B H, et al. Effects of CaCO3addition on uptake of heavy metals and arsenic in paddy fields[J]. Acta Ecologica Sinica, 2015,35(4):1242-1248.
[32]
李瑞东,王小利,段建军,等.碳酸钙对黄壤有机碳矿化及其温度敏感性的影响[J]. 农业环境科学学报, 2022,41(1):115-122. Li R D, Wang X L, Duan J J, et al. Effects of calcium carbonate on organic carbon mineralization and its temperature sensitivity in yellow soil[J]. Journal of Agro-Environment Science, 2022,41(1):115-122.
[33]
黄媛,苏以荣,梁士楚,等.桂西北典型土壤有机碳矿化对碳酸钙与水分含量的响应[J]. 生态学杂志, 2013,32(10):2695-2702. Huang Y, Su Y R, Liang S C, et al. Responses of organic carbon mineralization in typical soils in northwest Guangxi of China to calcium carbonate and soil moisture[J]. Chinese Journal of Ecology, 2013,32(10):2695-2702.
[34]
李忠,孙波,林心雄.我国东部土壤有机碳的密度及转化的控制因素[J]. 地理科学, 2001,(4):301-307. Li Z, Sun B, Lin X X. Density of Soil Organic Carbon and the Factors Controlling Its Turnover in East China[J]. Scientia Geographica Sinica, 2001,(4):301-307.
[35]
吴丽芳,倪大伟,王妍,等.典型岩溶流域不同土地利用类型土壤腐植酸与钙的关系[J]. 农业资源与环境学报, 2021,38(2):259-267. Wu L F, Ni D W, Wang Y, et al. Relationship between humic acids and calcium fractions in soils under contrasting land-use types in a typical karst basin[J]. Journal of Agricultural Resources and Environment, 2021,38(2):259-267.
[36]
陈家瑞,曹建华,梁毅,等.石灰土发育过程中土壤腐殖质组成及其与土壤钙赋存形态关系[J]. 中国岩溶, 2012,31(1):7-11. Chen J R, Cao J H, Liang Y, et al. Soil humus composition and its relationship with soil calcium speciation during the development of calcareous soil[J]. Carsologica Sinica, 2012,31(1):7-11.
[37]
Ko I, Kim J Y, Kim K W. Arsenic speciation and sorption kinetics in the As-hematite-humic acid system[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects, 2004,234(1):43-50.
[38]
Insam H, Mitchell C C, Dormaar J F. Relationship of soil microbial biomass and activity with fertilization practice and crop yield of three ultisols[J]. Soil Biology and Biochemistry, 1991,23(5):459-464.
[39]
胡柯鑫,董春华,罗尊长,等.不同缓释过氧化钙对潜育环境下水稻土微生物特性的影响[J]. 应用生态学报, 2020,31(6):1467-1475. Hu K X, Dong C H, Luo Z C, et al. Effects of different coated slow-release calcium peroxide on microbial characteristics of gleied paddy soil[J]. Chinese Journal of Applied Ecology, 2020,31(5):1467-1475.
[40]
淡俊豪,齐绍武,黎娟,等.生石灰对酸性土壤pH值及微生物群落功能多样性的影响[J]. 西南农业学报, 2017,30(12):2739-2745. Tang J H, Qi S W, Li J, et al. Effects of lime on pH and microbial community functional diversity in acid soils[J]. Southwest Agricultural Journal, 2017,30(12):2739-2745.
[41]
Li S., Liu J J, Yao Q, et al. Short-term lime application impacts microbial community composition and potential function in an acid black soil[J]. Plant and Soil, 2022,470(1):35-50.
[42]
Cha S, Kim Y S, Lee A L, et al. Liming alters the soil microbial community and extracellular enzymatic activities in temperate coniferous forests[J]. Forests, 2021,12(2):190.
[43]
Shangguan Y X, Qin Y S, Yu H, et al. Lime application affects soil cadmium availability and microbial community composition in different soils[J]. Clean-Soil Air Water, 2019,47(6):1800416.
[44]
杨明,许丽英,宋雨,等.厌氧微生物作用下土壤中砷的形态转化及其分配[J]. 生态毒理学报, 2013,8(2):178-185. Yang M, Xu L Y, Song Y, et al. Speciation transformation and distribution of arsenic in soils under action of anaerobic microbial activities[J]. Asian Journal of Ecotoxicology, 2013,8(2):178-185.
[45]
黄思映,杨旭,钱久李,等.微生物影响稻田土壤中砷转化研究进展[J]. 土壤, 2021,53(5):890-898. Huang S Y, Yang X, Qian J L, et al. Advances in Transformation of Arsenic in Paddy Fields Mediated by Microorganisms[J]. Soil, 2021,53(5):890-898.
[46]
杨洁,瞿攀,王金生,等.土壤中重金属的生物有效性分析方法及其影响因素综述[J]. 环境污染与防治, 2017,39(2):217-223. Yang J, Qu P, Wang J S, et al. Review of bioavailability analysis methods and influencing factors of heavy metals in soil[J]. Environmental Pollution and Prevention, 2017,39(2):217-223.
[47]
王金翠,孙继朝,黄冠星,等.土壤中砷的形态及生物有效性研究[J]. 地球与环境, 2011,39(1):32-36. Wang J C, Sun J C, Huang G X, et al. Speciation and bioavailability of arsenic in soils[J]. Earth and Environment, 2011,39(1):32-36.
[48]
王萍,王世亮,刘少卿,等.砷的发生、形态、污染源及地球化学循环[J]. 环境科学与技术, 2010,33(7):90-97. Wang P, Wang S L, Liu S Q, et al. Occurrence, speciation, source and geochemical cycle of arsenic[J]. Environmental Science & Technology, 2010,33(7):90-97.
[49]
Wang M, Wu S, Guo J, et al. Immobilization and migration of arsenic during the conversion of microbially induced calcium carbonate to hydroxylapatite[J]. Journal of Hazardous Materials, 2021,412(15):125261.
[50]
焦常锋,常会庆,王启震,等.碳酸钙和壳聚糖联用对高pH值石灰性土壤砷污染的钝化[J]. 农业工程学报, 2020,36(11):234-240. Jiao C F, Chang H Q, Wang Q Z, et al. Passivation effects of calcium carbonate and chitosan on arsenic pollution in high pH calcareous soil[J]. Transactions of the Chinese Society of Agricultural Engineering.
[51]
刘煌,孙小刚,徐茂权,等.砷污染耕地钝化剂的筛选与复配[J]. 湖南农业科学, 2021,(10):47-49. Liu H, Sun X G, Xu M Q, et al. Screening and combining of passivators for arsenic contaminated arable land[J]. Hunan Agricultural Science, 2021,(10):47-49.
[52]
Bade R, Oh S, Shin W S. Assessment of metal bioavailability in smelter-contaminated soil before and after lime amendment[J]. Ecotoxicology and Environmental Safety, 2012,80:299-307.
[53]
Neupane G, Donahoe R J. Calcium-phosphate treatment of contaminated soil for arsenic immobilization[J]. Applied Geochemistry, 2013,28:145-154.
[54]
Wei X, Zhang P B, Zhan Q, et al. Regulation of As and Cd accumulation in rice by simultaneous application of lime or gypsum with Si-rich materials[J]. Environmental Science and Pollution Research, 2021,28(6):7271-7280.
[55]
Yang X, Li J C, Liang T, et al. A combined management scheme to simultaneously mitigate As and Cd concentrations in rice cultivated in contaminated paddy soil[J]. Journal of Hazardous Materials, 2021, 416:125837.
[56]
Wan X M, Yang J X. The soil amendments to improve the efficiency of the intercropping system of Pteris vittata and Morus alba[J]. Water Air and Soil Pollution, 2018,229(5):149.
[57]
Jones C, Inskeep W, Neuman D. Arsenic transport in contaminated mine tailings following liming[J]. Journal of Environmental Quality, 1997,26(3):433-439.
[58]
吴长安.过氧化钙对土壤中砷生物有效性的影响[J]. 广东化工, 2012,39(8):29-30,19. Wu C A. The influence of calcium peroxide to arsenic bioavailability in soil[J]. Guangdong Chemical Industry, 2012,39(8):29-30,19.
[59]
钟倩云,曾敏,廖柏寒,等.2种固化剂对重金属和砷复合污染底泥的稳定化处理效果[J]. 水土保持学报, 2012,26(6):190-193. Zhong Q Y, Zeng M, Liao B H, et al. Effects of two curing agents on stabilization of sediment contaminated by heavy metals and arsenic[J]. Journal of Soil and Water Conservation, 2012,26(6):190-193.
[60]
He Y H, Lin H, Jin X N, et al. Simultaneous reduction of arsenic and cadmium bioavailability in agriculture soil and their accumulation in Brassica chinensis L. by using minerals[J]. Ecotoxicology and Environmental Safety, 2020,198:110660.
[61]
谢正苗,黄昌勇,何振立.土壤中砷的化学平衡[J]. 环境科学进展, 1998,(1):23-38. Xie Z M, Huang C Y, He Z L. Chemical equilibrium of arsenic in soils[J]. Advances in Environmental Science, 1998,(1):23-38.
[62]
Jackson B, Miller W. Effectiveness of phosphate and hydroxide for desorption of arsenic and selenium species from iron oxides[J]. Soil Science Society of America Journal, 2000,64(5):1616-1622.
[63]
陈静,王学军,朱立军.pH值对砷在贵州红壤中的吸附的影响[J]. 土壤, 2004:211-214. Chen J, Wang X J, Zhu L J. Effect of pH on the adsorption of arsenic in Guizhou red soil[J]. Soil, 2004:211-214.
[64]
Syu C H, Wu P R, Lee C H, et al. Arsenic phytotoxicity and accumulation in rice seedlings grown in arsenic-contaminated soils as influenced by the characteristics of organic matter amendments and soils[J]. Journal of Plant Nutrition and Soil Science, 2019,182(1):60-71.
[65]
Karczewska A, Galka B, Dradrach A, et al. Solubility of arsenic and its uptake by ryegrass from polluted soils amended with organic matter[J]. Journal of Geochemical Exploration, 2017,182:193-200.
[66]
Dobran S, Zagury G J. Arsenic speciation and mobilization in CCA-contaminated soils:Influence of organic matter content[J]. Science of the Total Environment, 2006,364(1-3):239-250.
[67]
Bauer M, Blodau C. Mobilization of arsenic by dissolved organic matter from iron oxides, soils and sediments[J]. Science of the Total Environment, 2006,354(2/3):179-190.
[68]
Wang S, Mulligan C N. Effect of natural organic matter on arsenic release from soils and sediments into groundwater[J]. Environmental Geochemistry and Health, 2006,28(3):197-214.
[69]
Verbeeck M, Thiry Y, Smolders E. Soil organic matter affects arsenic and antimony sorption in anaerobic soils[J]. Environmental Pollution, 2020,257:113566.
[70]
Langner P, Mikutta C, Kretzschmar R. Arsenic sequestration by organic sulphur in peat[J]. Nature Geoscience, 2012,5(1):66-73.
[71]
Williams P N, Zhang H, Davison W, et al. Organic matter-solid phase interactions are critical for predicting arsenic release and plant uptake in bangladesh paddy soils[J]. Environmental Science & Technology, 2011,45(14):6080-6087.
[72]
林先贵,胡君利.土壤微生物多样性的科学内涵及其生态服务功能[J]. 土壤学报, 2008,(5):892-900. Lin X G, Hu J L. Scientific connotation of soil microbial diversity and its ecological service function[J]. Soil Science, 2008,(5):892-900.
[73]
蔡林,王革娇.抗砷性微生物及其抗砷分子机制研究进展[J]. 微生物学通报, 2009,36(8):1253-1259. Cai L, Wang G J. Advances in arsenic-resistant microorganisms and their molecular mechanisms[J]. Bulletin of Microbiology, 2009,36(8):1253-1259.
[74]
吴佳,谢明吉,杨倩,等.砷污染微生物修复的进展研究[J]. 环境科学, 2011,32(3):817-824. Wu J, Xie M J, Yang Q, et al. Advances in microbial remediation of arsenic contamination[J]. Environmental Science, 2011,32(3):817-824.
[75]
杨婧,朱永官.微生物砷代谢机制的研究进展[J]. 生态毒理学报, 2009,4(6):761-769. Yang J, Zhu Y G. Research progress on the mechanism of arsenic metabolism in microorganisms[J]. Chinese Journal of Ecotoxicology, 2009,4(6):761-769.
[76]
Gustave W, Yuan Z F, Ren Y X, et al. Arsenic alleviation in rice by using paddy soil microbial fuel cells[J]. Plant and Soil, 2019, 441(1/2):111-127.
[77]
Xue S G, Jiang X X, Wu C, et al. Microbial driven iron reduction affects arsenic transformation and transportation in soil-rice system[J]. Environmental Pollution, 2020,260:114010.
[78]
Di X R, Beesley L, Zhang Z L, et al. Microbial arsenic methylation in soil and uptake and metabolism of methylated arsenic in plants:A review[J]. International Journal of Environmental Research and Public Health, 2019,16(24):5012.
[79]
Xu X W, Wang P, Zhang J, et al. Microbial sulfate reduction decreases arsenic mobilization in flooded paddy soils with high potential for microbial Fe reduction[J]. Environmental Pollution, 2019,251:952-960.
[80]
Tang X J, Li L Y, Wu C, et al. The response of arsenic bioavailability and microbial community in paddy soil with the application of sulfur fertilizers[J]. Environmental Pollution, 2020,264:114679.
[81]
Das S, Wang H Y, Song H J, et al. Soil microbial response to silicate fertilization reduces bioavailable arsenic in contaminated paddies[J]. Soil Biology & Biochemistry, 2021,159:108307.
[82]
Yamamura S, Sudo T, Watanabe M, et al. Effect of extracellular electron shuttles on arsenic-mobilizing activities in soil microbial communities[J]. Journal of Hazardous Materials, 2018,342:571-578.
[83]
井大炜,邢尚军,马丙尧,等.土壤与植物中钙营养研究进展[J]. 生物灾害科学, 2012,35(4):447-451. Jing D W, Xing S J, Ma B Y, et al. Research progress on calcium nutrition in soil and plants[J]. Biological Disaster Science, 2012, 35(4):447-451.
[84]
赵家印,杨欣悦,席运官,等.2种钝化剂对土壤重金属Cu、Cd有效性及植物累积的影响[J]. 江苏农业科学, 2020,48(13):308-313. Zhao J Y, Yang X Y, Xi Y G, et al. Effects of two amendments on the availability of soil heavy metals Cu and Cd and plant accumulation[J]. Jiangsu Agricultural Sciences, 2020,48(13):308-313.
[85]
汤民,张进忠,张丹,等.土壤改良剂及其组合原位钝化果园土壤中的Pb、Cd[J]. 环境科学, 2012,33(10):3569-3576. Tang M, Zhang J Z, Zhang D, et al. Soil amendments and their combinations in situ immobilize Pb and Cd in orchard soils[J]. Environmental Science, 2012,33(10):3569-3576.
[86]
郝金才,李柱,吴龙华,等.铅镉高污染土壤的钝化材料筛选及其修复效果初探[J]. 土壤, 2019,51(4):752-759. Hao J C, Li Z, Wu L H, et al. Screening of passivation materials for lead-cadmium highly polluted soil and preliminary study on its remediation effect[J]. Soil, 2019,51(4):752-759.
[87]
Syu C, Yu C H, Lee D Y. Effect of applying calcium peroxide on the accumulation of arsenic in rice plants grown in arsenic-elevated paddy soils[J]. Environmental Pollution, 2020,266(2):115140.
[88]
Liu C P, Luo C L, Xu X H, et al. Effects of calcium peroxide on arsenic uptake by celery (Apium graveolens L.) grown in arsenic contaminated soil[J]. Chemosphere, 2012,86(11):1106-1111.
[89]
Chou M L, Jean J S, Yang C M, et al. Inhibition of ethylenediaminetetraacetic acid ferric sodium salt (EDTA-Fe) and calciumperoxide (CaO2) on arsenic uptake by vegetables in arsenic-rich agricultural soil[J]. Journal of Geochemical Exploration, 2016,163:19-27.
[90]
Zhai W W, Zhao W L, Yuan H H, et al. Reduced Cd, Pb, and As accumulation in rice (Oryza sativa L.) by a combined amendment of calcium sulfate and ferric oxide[J]. Environmental Science and Pollution Research, 2020,27(2):1348-1358.
[91]
陈同斌,韦朝阳,黄泽春,等.砷超富集植物蜈蚣草及其对砷的富集特征[J]. 科学通报, 2002,(3):207-210. Chen T B, Wei C Y, Huang Z C, et al. Arsenic hyperaccumulator Pteris vittata and its arsenic enrichment characteristics[J]. Scientific Bulletin, 2002,(3):207-210.
[92]
Ma L Q, Komar K M, Tu C, et al. A fern that hyperaccumulates arsenic-A hardy, versatile, fast-growing plant helps to remove arsenic from contaminated soils[J]. Nature, 2001,409(6820):579-579.
[93]
Yang G, Wang Y, Zhu L, et al. Accumulation and speciation of arsenic in Pteris vittata gametophytes and sporophytes:effects of calcium and phosphorus[J]. Pedosphere, 2019,29(4):540-544.
[94]
廖晓勇,肖细元,陈同斌.砂培条件下施加钙、砷对蜈蚣草吸收砷、磷和钙的影响[J]. 生态学报, 2003,(10):2057-2065. Liao X Y, Xiao X Y, Chen T B. Effects of calcium and arsenic on the uptake of arsenic, phosphorus and calcium by Pteris vittata in sand culture[J]. Ecology, 2003,(10):2057-2065.
[95]
Fayiga A O, Ma L Q, Rathinasabapathi B. Effects of nutrients on arsenic accumulation by arsenic hyperaccumulator Pteris Vittata L.[J]. Environmental and Experimental Botany, 2008,62(3):231-237.
[96]
Caille N, Swanwick S, Zhao F J, et al. Arsenic hyperaccumulation by Pteris vittata from arsenic contaminated soils and the effect of liming and phosphate fertilisation[J]. Environmental Pollution, 2004,132(1):113-120.
[97]
Rahman A, Mostofa M G, Alam M, et al. Calcium mitigates arsenic toxicity in rice seedlings by reducing arsenic uptake and modulating the antioxidant defense and glyoxalase systems and stress markers[J]. Biomed Research International, 2015.https://doi.org/10.1155/2015/340812.
[98]
Rafiq M, Shahid M, Abbas G, et al. Comparative effect of calcium and EDTA on arsenic uptake and physiological attributes of Pisum sativum[J]. International Journal of Phytoremediation, 2017,19(7):662-669.
[99]
Rafiq M, Shahid M, Shamshad S, et al. A comparative study to evaluate efficiency of EDTA and calcium in alleviating arsenic toxicity to germinating and young Vicia faba L. seedlings[J]. Journal of Soils and Sediments, 2018,18(6):2271-2281.
[100]
Wilson S C, Leech C D, Butler L, et al. Effects of nutrient and lime additions in mine site rehabilitation strategies on the accumulation of antimony and arsenic by native Australian plants[J]. Journal of Hazardous Materials, 2013,261:801-807.
[101]
Carmen Pinero M, Perez-Jimenez M, Lopez-Marin J, et al. Amelioration of boron toxicity in sweet pepper as affected by calcium management under an elevated CO2 concentration[J]. Environmental Science and Pollution Research, 2017,24(11):10893-10899.
[102]
Brennan E G, Leone I A, Daines R H. Fluorine toxicity in tomato as modified by alterations in the nitrogen, calcium, and phosphorus nutrition of the plant[J]. Plant Physiology, 1950,25(4):736-747.
[103]
Kaya C, Higgs D. Calcium nitrate as a remedy for salt stressed cucumber plants[J]. Journal of Plant Nutrition, 2002,25(4):861-871.
[104]
Shao H B, Chu L Y, Shao M A. Calcium as a versatile plant signal transducer under soil water stress[J]. Bioessays, 2008,30(7):634-641.
[105]
Trofimova M S, Andreev I M, Kuznetsov VV. Calcium as an intracellular regulator of HSP96 synthesis and plant cell tolerance to high temperature[J]. Russian Journal of Plant Physiology, 1997, 44(4):443-447.
[106]
Singh R, Parihar P, Prasad S M. Sulphur and calcium attenuate arsenic toxicity in Brassica by adjusting ascorbate-glutathione cycle and sulphur metabolism[J]. Plant Growth Regulation, 2020,91(2):221-235.
[107]
Siddiqui M H, Alamri S, Khan M N, et al. Melatonin and calcium function synergistically to promote the resilience through ROS metabolism under arsenic-induced stress[J]. Journal of Hazardous Materials, 2020,398:122882.
[108]
Ji R J, Zhou L M, Liu J L, et al. Calcium-dependent protein kinase CPK31 interacts with arsenic transporter AtNIP1; l and regulates arsenite uptake in Arabidopsis thaliana[J]. PLoS ONE, 2017,12(3):e0173681.
[109]
Singh R, Parihar P, Prasad S M. Interplay of calcium and nitric oxide in improvement of growth and arsenic-induced toxicity in mustard seedlings[J]. Scientific Reports, 2020,10(1):12065.
[110]
Singh R, Parihar P, Prasad S M. Simultaneous exposure of sulphur and calcium hinder As toxicity:Up-regulation of growth, mineral nutrients uptake and antioxidants system[J]. Ecotoxicology and Environmental Safety, 2018,161:318-331.