Zn^(2+)和Mn^(2+)处理水钠锰矿后对Pb^(2+)吸附量的影响被引量：1

Effects on Pb^(2+) adsorption capacity of birnessite treated with Zn^(2+) and Mn^(2+)

导出

摘要分别采用Zn2+和Mn2+处理锰平均氧化度较高的水钠锰矿,对比研究了经不同浓度的Zn2+和Mn2+处理后矿物的锰平均氧化度、d110面网间距、对Pb2+的最大吸附量以及吸附过程中Zn2+和Mn2+的最大释放量等的变化.同时,通过Zn2+和Mn2+与水钠锰矿表面反应行为的不同,进一步明确矿物结构中的八面体空穴数量与重金属吸附量的关系.研究结果表明,水钠锰矿经Zn2+和Mn2+分别处理后,矿物类型未改变,并具有相似的晶体形貌.Zn2+溶液处理水钠锰矿时,随着Zn2+浓度的增大,水钠锰矿的锰平均氧化度和d110面网间距不变,说明结构中空穴数量未改变,Zn2+通过占据部分吸附点位,导致其对Pb2+的最大吸附量从3190mmo.lkg-1减少为2030mmol.kg-1.而Mn2+溶液处理水钠锰矿时,大多数Mn2+被氧化为Mn3+,这些Mn3+部分位于八面体空穴上下方的吸附位点,部分进入八面体空穴中.随着加入的Mn2+浓度增大,Mn2+被氧化为Mn3+而进入八面体空穴的数量增多,锰平均氧化度减小,d110面网间距从0.14160nm增大至0.14196nm,说明结构中空穴数量减少,对Pb2+的最大吸附量从3190mmol·kg-1减少至1332mmo·lkg-1.对比研究结果表明,水钠锰矿结构中的八面体空穴数量对Pb2+的吸附量的大小起着非常重要的作用. The Pb^2＋ adsorption behavior of birnessite with high Mn average oxidation state （AOS） before and after treatment by preadsorption of Zn^2＋ and Mn^2＋ was compared. The association of vacant Mn octahedral sites with Pb^2＋ adsorption was determined from the AOS, d（110）-interplanar spacing, maximum Pb^2＋ adsorption, and maximum Zn^2＋ and Mn^2＋ release during Pb^2＋ adsorption by the birnessites before and after treatment. The AOS and d（110） -interplanar spacing of the birnessites remained almost unchanged as the concentration of Zn^2＋ increased, indicative of an unchanged number of vacant Mn octahedral sites. Maximum Pb^2＋ adsorption decreased from 3190 to 2030 mmol·kg^-1 due to Zn^2＋ occupancy of the adsorption sites. When the concentration of Mn^2＋ in the pretreatment increased from 1 to 2.4 mmol·L^-1, the AOS of the birnessites decreased, and most of the Mn^2＋ was oxidized to Mn^3＋ located above or below vacant Mn octahedral sites or migrated into vacant Mn octahedral sites. The d（110） -interplanar spacings of the treated birnessites increased from 0. 14160 to 0. 14196 nm, indicative of a decrease in the number of vacant Mn octahedral sites, mainly due to the produced Mn^3＋ migrating into vacant Mn octahedral sites. Moreover, the maximum Pb^2＋ adsorption of the Mn^2＋ - treated birnessites was observed to decrease from 3190 to 1332 mmol·kg^-1. The results suggest that birnessite Pb^2＋ adsorption capacity is largely determined by the number of Mn site vacancies.

作者赵巍王庆庆刘凡邱国红谭文峰冯雄汉

机构地区华中农业大学农业部亚热带农业资源与环境重点开放实验室

出处《环境科学学报》 CAS CSCD 北大核心 2009年第8期1657-1665,共9页 Acta Scientiae Circumstantiae

基金国家自然科学基金项目(No.40771102) 全国优秀博士学位论文作者专项资金资助项目(No.200767) 湖北省自然科学基金计划青年杰出人才项目(No.2007ABB014)~~

关键词锰氧化物锌吸附水钠锰矿铅吸附八面体空穴 Zn^2＋ adsorption birnessite Pb^2＋ adsorption vacant Mn octahedral site

分类号 X703 [环境科学与工程—环境工程]

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