玉米秸秆生物炭对砷镉复合污染土壤中砷镉形态的影响
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- 英文论文题名:Effects of Bio-carbon from Corn Stalks on Arsenic and Cadmium Forms in As and Cd Combined Contaminated Soil
- 论文作者:张燕 ; 铁柏清 ; 张淼 ; 叶长城 ; 彭鸥 ; 许蒙
- 英文论文作者:ZHANG Yan ; TIE Boqing ; ZHANG Miao ; YE Changcheng ; PENG Ou ; XU Meng ; College of Resources and Environment ; Hunan Agricultural Uuiversity
- 年:2016
- 作者机构:湖南农业大学资源环境学院;
- 论文关键词:镉 ; 砷 ; 复合污染 ; 玉米秸秆生物炭
- 英文论文关键词:cadmium ; arsenic ; Compound pollution ; Corn Stalk Biochar
- 会议召开时间:2016-12-01
- 会议录名称:第六届重金属污染防治及风险评价研讨会暨重金属污染防治专业委员会2016年学术年会论文集
- 语种:中文
- 分类号:X53
- 学会代码:HJKP
- 会议名称:第六届重金属污染防治及风险评价研讨会暨重金属污染防治专业委员会2016年学术年会
- 会议地点:中国福建厦门
- 主办单位:中国环境科学学会
- 学会名称:中国环境科学学会
- 页数:9
- 文件大小:1123k
- 原文格式:D
- 会议级别:全国
摘要
本文通过室内土壤培养的方法,研究不同温度条件下制备的玉米秸秆生物炭添加在淹水环境下对砷镉复合污染土壤中砷镉各形态的影响。试验设置5个处理:CK、CB-300、CB-400、CB-500、CS,试验周期为120天,每6天取土壤样品约20g,分析土壤氧化还原电位,p H值及不同形态砷镉含量动态变化。试验结果表明,与CK相比,添加玉米秸秆生物炭可提高土壤p H值0.2~1.24个单位,添加玉米秸秆粉末可提高土壤p H值0.27个单位,随着培养时间的延长,p H值趋于平衡状态;氧化还原电位在淹水及玉米秸秆生物炭的处理下迅速下降,土壤呈现强还原状态,培养至第96天氧化还原电位达到最低点;CB-300、CB-400、CB-500、CS处理组土壤可交换态镉含量比例由对照的58.09%分别降至46.89%、46.56%、45.06%、55.62%;可还原态镉含量比例由对照的28.05%分别降至22.47%、21.99%、21.94%、23.12%;可氧化态镉含量比例由对照的3.98%分别升高至10.08%、10.02%、11.11%、5.45%;残渣态镉含量比例由对照的10.03%升高至20.53%、21.42%、21.81%、15.79%;CB-300、CB-400、CB-500、CS处理组土壤有效砷含量由对照的3.12mg/kg分别升高至5.17mg/kg、5.30mg/kg、5.24mg/kg、5.26mg/kg,随着培养时间的延长,水溶态砷含量呈现升高-下降-升高的变化规律,砷活性指数略有降低,但未达到显著差异。
In this paper, the effects of bio-carbon on the arsenic and cadmium forms in arsenic-cadmium compound polluted soils under different temperature conditions were studied. The treatment consisted of five treatments: CK CB-300 CB-400 CB-500 CS, the test period was 120 days, soil samples were taken every 6 days, and the redox potential, p H and arsenic and cadmium were measured. The results showed that the addition of cornstraw biochar could increase the soil p H value by 0.2 ~ 1.24 units compared with CK, adding corn stalk powder can increase the soil p H value of 0.27, units and the p H value reached equilibrium state when the culture time was prolonged. The oxidation-reduction potential decreased rapidly under the condition of flooding and bio-charcoal of corn straw, and the soil showed a strong reduction state. The redox potential reached the lowest point after 96-day culture. The percentage of exchangeable Cd in CB-300, CB-400, CB-500, CS-treated soils decreased from 57.91% to 46.91%, 35.16%, 44.19% and 55.54%, the content of reducible cadmium decreased from 26.35% to 22.41%, 21.91%, 21.94% and 22.48%, respectively; The proportion of oxidized cadmium increased from 3.97% to 10.05%, 9.99%, 11.07% and 5.44%, respectively. The proportion of residual cadmium increased from 10.00% to 20.47%, 21.36%, 21.75%, 15.76%. The effective arsenic contents of CB-300, CB-400, CB-500, CS treated groups were increased from 3.12mg/kg to 5.17mg/kg, 5.30mg/kg, 5.24mg/kg, 5.26mg/kg, with the extension of culture time, the arsenic content of water soluble increased, decreased and increased, arsenic activity index decreased slightly, but did not reach significant differences.
In this paper, the effects of bio-carbon on the arsenic and cadmium forms in arsenic-cadmium compound polluted soils under different temperature conditions were studied. The treatment consisted of five treatments: CK CB-300 CB-400 CB-500 CS, the test period was 120 days, soil samples were taken every 6 days, and the redox potential, p H and arsenic and cadmium were measured. The results showed that the addition of cornstraw biochar could increase the soil p H value by 0.2 ~ 1.24 units compared with CK, adding corn stalk powder can increase the soil p H value of 0.27, units and the p H value reached equilibrium state when the culture time was prolonged. The oxidation-reduction potential decreased rapidly under the condition of flooding and bio-charcoal of corn straw, and the soil showed a strong reduction state. The redox potential reached the lowest point after 96-day culture. The percentage of exchangeable Cd in CB-300, CB-400, CB-500, CS-treated soils decreased from 57.91% to 46.91%, 35.16%, 44.19% and 55.54%, the content of reducible cadmium decreased from 26.35% to 22.41%, 21.91%, 21.94% and 22.48%, respectively; The proportion of oxidized cadmium increased from 3.97% to 10.05%, 9.99%, 11.07% and 5.44%, respectively. The proportion of residual cadmium increased from 10.00% to 20.47%, 21.36%, 21.75%, 15.76%. The effective arsenic contents of CB-300, CB-400, CB-500, CS treated groups were increased from 3.12mg/kg to 5.17mg/kg, 5.30mg/kg, 5.24mg/kg, 5.26mg/kg, with the extension of culture time, the arsenic content of water soluble increased, decreased and increased, arsenic activity index decreased slightly, but did not reach significant differences.
引文
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[24]陈喆,铁柏清,雷鸣,刘孝利,叶长城,罗梅梅,毛懿德.施硅方式对稻米镉阻隔潜力研究[J/OL].环境科学,2014.
[25]陈喆,张淼,叶长城,毛懿德,周细红,雷鸣,魏祥东,铁柏清.富硅肥料和水分管理对稻米镉污染阻控效果研究[J/OL].环境科学学报,2015.
[26]陈玲玲,陈晓宏,张云,等.剧烈人类活动区经济发展与环境污染水平关系[J].生态环境学报,2014(2):339-343.
[27]Kuo W S.METHOD FOR KILLING AND TRACING BACTERIA BY COATING SAME WITH SELF-ASSEMBLED GOLD NANOSHELL LAYER AND PRODUCING PHOTOTHERMAL DECOMPOSITION AND COLD LIGHT BY MEANS OF LASER:,WO/2014/153774[P].2014.
[28]王永,徐仁扣,王火焰,等.砷酸根在可变电荷土壤颗粒表面的配位吸附[J].环境化学,2009,28(2):163-167.
[29]关连珠,周景景,张昀,等.不同来源生物炭对砷在土壤中吸附与解吸的影响[J].应用生态学报,2013,24(10):2941-2946.
[30]刘云璐,李莲芳,曾希柏,等.添加外源耐砷菌与零价铁对土壤砷有效性和形态的影响[J].农业环境科学学报,2013(11):2175-2184.
[28]陈同斌,刘更另.土壤中砷的吸附和砷对水稻的毒害效应与p H值的关系[J].中国农业科学,1993,26(1):63-68.
[29]陈保卫,Le X.Chris.中国关于砷的研究进展[J].环境化学,2011,30(11):1936-1943.
[2]杨佳波.水溶性有机物的化学行为及其对土壤中Cu形态和有效性的影响[D].中国农业科学院,2007.
[3]甲卡拉铁,喻华,冯文强,等.淹水条件下不同氮磷钾肥对土壤p H和镉有效性的影响研究[J].环境科学,2009,30(11):3414-3421.
[4]安增莉.生物炭的制备及其对Pb(Ⅱ)的吸附特性研究[D].华侨大学,2011.
[5]Steiner C,Teixeira W G,Lehmann J,et al.Long term effects of manure,charcoal and mineral fertilization on crop production and fertility on a highly weathered Central Amazonian upland soil[J].Plant&Soil,2007,291(2):275-290.
[6]郭文娟,梁学峰,林大松,等.土壤重金属钝化修复剂生物炭对镉的吸附特性研究[J].环境科学,2013,34(9):3716-3721.
[7]孙晓铧.改良剂对污染土壤中重金属形态及微生物数量的影响[J].2013.
[8]张千丰,孟军,刘居东,等.热解温度和时间对三种作物残体生物炭p H值及碳氮含量的影响[J].生态学杂志,2013,32(9):2347-2353.
[9]周强,黄代宽,余浪,等.热解温度和时间对生物炭p H值的影响[J].地球环境学报,2015,6(3):195-200.
[10]赵志强,牛军峰.环境中有害金属植物修复的生理机制及进展[J].环境科学研究,2000,13(5):54-57.
[11]Melnikova E,Novakova I,Kraif O.Quels corpus pour l'analyse contrastive L'exemple des constructions verbo-nominales de sentiment en fran?ais et en russe[J].Folia Medica,2009,10(1):10-5.
[12]吴成,张晓丽,李关宾.黑碳吸附汞砷铅镉离子的研究[J].农业环境科学学报,2007,26(2):770-774.
[13]李海玲.土壤p H值的测定——电位法[J].农业科技与信息,2011(13):47-48.
[14]莫伟文,王频,李萍.去极化法氧化还原电位在线监测游泳池水质的研究[J].社区医学杂志,2014,12(17):72-74.
[15]张朝阳,彭平安*,宋建中,等.改进BCR法分析国家土壤标准物质中重金属化学形态[J].生态环境学报,2012(11):1881-1884.
[16]武斌,廖晓勇,陈同斌,等.石灰性土壤中砷形态分级方法的比较及其最佳方案[J].环境科学学报,2006,26(9):1467-1473.
[17]赵中秋,朱永官,蔡运龙.镉在土壤-植物系统中的迁移转化及其影响因素[J].生态环境学报,2005,14(2):282-286.
[18]卜晓莉,薛建辉.生物炭对土壤生境及植物生长影响的研究进展[J].生态环境学报,2014(3):535-540.
[19]于童.不同初始氧化还原电位土壤中重金属Cd/Zn/Cu的运移实验及数值模拟[D].青岛大学,2011.
[20]潘胜强,王铎,吴山,等.土壤理化性质对重金属污染土壤改良的影响分析[J].环境工程,2014(s1):600-603.
[21]丁昌璞.中国自然土壤、旱作土壤、水稻土的氧化还原状况和特点[J].土壤学报,2008,45(1):66-75.
[22]刘志光,于天仁.水稻土中氧化还原过程的研究(Ⅴ)还原性物质的测定[J].土壤学报,1962(1):13-28.
[23]毛懿德,铁柏清,叶长城,周焱,杨生茂.生物炭对重污染土壤镉形态及油菜吸收镉的影响[J].生态与农村环境学报,2015,04:579-582.
[24]陈喆,铁柏清,雷鸣,刘孝利,叶长城,罗梅梅,毛懿德.施硅方式对稻米镉阻隔潜力研究[J/OL].环境科学,2014.
[25]陈喆,张淼,叶长城,毛懿德,周细红,雷鸣,魏祥东,铁柏清.富硅肥料和水分管理对稻米镉污染阻控效果研究[J/OL].环境科学学报,2015.
[26]陈玲玲,陈晓宏,张云,等.剧烈人类活动区经济发展与环境污染水平关系[J].生态环境学报,2014(2):339-343.
[27]Kuo W S.METHOD FOR KILLING AND TRACING BACTERIA BY COATING SAME WITH SELF-ASSEMBLED GOLD NANOSHELL LAYER AND PRODUCING PHOTOTHERMAL DECOMPOSITION AND COLD LIGHT BY MEANS OF LASER:,WO/2014/153774[P].2014.
[28]王永,徐仁扣,王火焰,等.砷酸根在可变电荷土壤颗粒表面的配位吸附[J].环境化学,2009,28(2):163-167.
[29]关连珠,周景景,张昀,等.不同来源生物炭对砷在土壤中吸附与解吸的影响[J].应用生态学报,2013,24(10):2941-2946.
[30]刘云璐,李莲芳,曾希柏,等.添加外源耐砷菌与零价铁对土壤砷有效性和形态的影响[J].农业环境科学学报,2013(11):2175-2184.
[28]陈同斌,刘更另.土壤中砷的吸附和砷对水稻的毒害效应与p H值的关系[J].中国农业科学,1993,26(1):63-68.
[29]陈保卫,Le X.Chris.中国关于砷的研究进展[J].环境化学,2011,30(11):1936-1943.
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