不同电解质对牛粪生物质炭中腐殖酸吸附–解吸的影响
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摘要
本文研究了NaCl、Na_2SO_4、Na_3PO_4 3种背景电解质对牛粪生物质炭中腐殖酸吸附和解吸的影响。结果表明:在这3种背景电解质作用下,牛粪生物质炭对腐殖酸的吸附量和吸附率随着加入液腐殖酸浓度的增加而增加,但是增加速度逐渐变缓。3种背景电解质相比,NaCl中牛粪生物质炭对腐殖酸的吸附量和吸附率均为最高,吸附量范围为0.13~6.10 mg/g,吸附率范围为25.40%~87.14%。随着加入液腐殖酸浓度的增加,吸附态腐殖酸的解吸量逐渐增加,解吸率逐渐减小。3种背景电解质相比,Na_2SO_4中牛粪生物质炭吸附的腐殖酸的解吸量最高,解吸量范围为0.15~0.78 mg/g。加入液腐殖酸浓度为140 mg/L,3种背景电解质中牛粪生物质炭吸附的腐殖酸的解吸量均达到最大值,解吸量的大小顺序为Na_2SO_4>Na_3PO_4>NaCl。Na_3PO_4对腐殖酸的解吸率影响最大,解吸率范围为17.24%~90.55%,NaCl对腐殖酸的解吸率影响最小,解吸率范围为8.22%~53.54%。用Langmuir拟合3种背景电解质中腐殖酸的等温吸附曲线和等温解吸曲线,其相关系数都达到显著水平。研究结果揭示了不同背景电解质对牛粪生物质炭吸附和解吸腐殖酸的影响,可为土壤保土保肥提供理论参考。
The effects of three kinds of background electrolytes(NaCl,Na_2SO_4 and Na_3PO_4)on the adsorption and desorption of humic acid in the dairy manure biochar were studied.Results showed that under the effect of the three kinds of background electrolytes,the dairy manure biochar adsorption capacity and adsorption rate increased with the increase of liquid humic acid concentration,however,the increasing speed gradually slowed down.Compared to the three kinds of background electrolytes,NaCl had the highest adsorption capacity and adsorption rate of humic acid in dairy manure biochar,The range of adsorption capacity was 0.13–6.10 mg/g,the range of adsorption rate was 25.40%–87.14%.With the increase of the concentration of adding liquid humic acid,the desorption capacity of adsorption state humic acid gradually increased,and the desorption rate gradually decreased.Compared to the three kinds of background electrolytes,Na_2SO_(4 )had the highest desorption rate of adsorptive humic acid in dairy manure biochar,and the range of desorption capacity was 0.15–0.78 mg/g.the concentration of liquid humic acid was 140 mg/L,the desorption capacity of the three kinds of background electrolytes to the adsorptive humic acid of dairy manure biochar have reached the maximum value,the order of desorption capacity was Na_2SO_4>Na_3PO_4>NaCl.Na_3PO_4 had the greatest effect in the desorption rate of humic acid,the range of desorption rate was 17.24%–90.55%,NaCl had the minimal effect in the desorption rate of humic acid,the range of desorption rate was 8.22%–53.54%.The isothermal adsorption curves and isothermal desorption curves of the three kinds of background electrolytes in humic acid were fitted with Langmuir,and the correlation coefficients were significant.The results showed that the effects of different background electrolytes to dairy manure biochar on the adsorption and desorption of humic acid were studied,which provided a theoretical reference for soil fertility and soil fertility.
The effects of three kinds of background electrolytes(NaCl,Na_2SO_4 and Na_3PO_4)on the adsorption and desorption of humic acid in the dairy manure biochar were studied.Results showed that under the effect of the three kinds of background electrolytes,the dairy manure biochar adsorption capacity and adsorption rate increased with the increase of liquid humic acid concentration,however,the increasing speed gradually slowed down.Compared to the three kinds of background electrolytes,NaCl had the highest adsorption capacity and adsorption rate of humic acid in dairy manure biochar,The range of adsorption capacity was 0.13–6.10 mg/g,the range of adsorption rate was 25.40%–87.14%.With the increase of the concentration of adding liquid humic acid,the desorption capacity of adsorption state humic acid gradually increased,and the desorption rate gradually decreased.Compared to the three kinds of background electrolytes,Na_2SO_(4 )had the highest desorption rate of adsorptive humic acid in dairy manure biochar,and the range of desorption capacity was 0.15–0.78 mg/g.the concentration of liquid humic acid was 140 mg/L,the desorption capacity of the three kinds of background electrolytes to the adsorptive humic acid of dairy manure biochar have reached the maximum value,the order of desorption capacity was Na_2SO_4>Na_3PO_4>NaCl.Na_3PO_4 had the greatest effect in the desorption rate of humic acid,the range of desorption rate was 17.24%–90.55%,NaCl had the minimal effect in the desorption rate of humic acid,the range of desorption rate was 8.22%–53.54%.The isothermal adsorption curves and isothermal desorption curves of the three kinds of background electrolytes in humic acid were fitted with Langmuir,and the correlation coefficients were significant.The results showed that the effects of different background electrolytes to dairy manure biochar on the adsorption and desorption of humic acid were studied,which provided a theoretical reference for soil fertility and soil fertility.
引文
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[19]朱志平,黄可龙,周艺.碳纳米管吸附腐植酸的动力学、热力学及机理研究[J].无机材料学报,2011,26(2):170-174
[20]黄容,高明,廖燕妮.不同生物质灰渣对磷的吸附解吸动力学特征[J].水土保持学报,2014,28(1):156-160
[21]Maghsoodloo S,Noroozi B,Haghi A K,et al.Consequence of chitosan treating on the adsorption of humic acid by granular activated carbon[J].Journal of Hazardous Materials,2011,191(1/2/3):380-387
[22]Li S,He M,Li Z,et al.Removal of humic acid from aqueous solution by magnetic multi-walled carbon nanotubes decorated with calcium[J].Journal of Molecular Liquids,2017,230(3):520-528
[23]Guan X H,Shang C,Chen G H.Competitive adsorption of organic matter with phosphate on aluminum hydroxide[J].Journal of Colloid&Interface Science,2006,296(1):51-58
[24]Qin X,Liu F,Wang G.Fractionation and kinetic processes of humic acid upon adsorption on colloidal hematite in aqueous solution with phosphate[J].Chemical Engineering Journal,2012,209(41):458-463
[2]吴景贵,王明辉,万忠梅,等.玉米秸秆腐解过程中形成胡敏酸的组成和结构研究[J].土壤学报,2006,43(3):443-451
[3]Yang J S,Jun bao Y U,Liu J S,et al.Humus distribution and fraction of typical marsh soil depth profiles in the Sanjiang Plain[J].Chinese Journal of Soil Science,2006,37(5):865-868
[4]Zhang J J,Dou S,Cui-Lan L I,et al.Studies on fractionation of soil humus[J].Chinese Journal of Soil Science,2004,35(6):706-709
[5]张阿凤,潘根兴,李恋卿.生物黑炭及其增汇减排与改良土壤意义[J].农业环境科学学报,2009,28(12):2459-2463
[6]Chang M P,Han J,Chu K H,et al.Influence of solution pH,ionic strength,and humic acid on cadmium adsorption onto activated biochar:Experiment and modeling[J].Journal of Industrial&Engineering Chemistry,2017,48(2):186-193
[7]Amonette J E,Joseph S.Characteristics of biochar:Microchemical properties[J].Journal of the Party School of Shengli Oilfield,2009,7(6):1649-1654
[8]巢军委,王建国,戴敏,等.生物炭对水稻土Olsen-P的影响[J].土壤,2015,47(4):670-674
[9]王光飞,马艳,郭德杰,等.不同用量秸秆生物炭对辣椒疫病防控效果及土壤性状的影响[J].土壤学报,2017,54(1):204-215
[10]Kolb S E,Fermanich K J,Dornbush M E.Effect of charcoal quantity on microbial biomass and activity in temperate soils[J].Soil Science Society of America Journal,2009,73(73):1173-1181
[11]王冰,赵闪闪,秦治家,等.生物质炭对黑土吸附-解吸硝态氮性能的影响[J].农业环境科学学报,2016,35(1):115-121
[12]王荣萍,余炜敏,梁嘉伟,等.改性生物炭对菜地土壤磷素形态转化的影响[J].生态环境科学学报,2016,25(5):872-876
[13]Liu N,Sun Z T,Wu Z C,et al.Adsorption characteristics of ammonium nitrogen by biochar from diverse origins in water[J].Advanced Materials Research,2013,664(4):305-312
[14]Xu G,Sun J N,Shao H B,et al.Biochar had effects on phosphorus sorption and desorption in three soils with differing acidity[J].Ecological Engineering,2014,62(1):54-60
[15]余晨,何盈盈,杨立.活性炭吸附腐殖酸的分段等温吸附模拟及热力学研究[J].水处理技术,2014,40(1):29-32
[16]徐仁扣.秸秆生物质炭对红壤酸度的改良作用:回顾与展望[J].农业资源与环境学报,2016,33(4):303-309
[17]Janus A,Pelfrêne A,Heymans S,et al.Elaboration,characteristics and advantages of biochars for the management of contaminated soils with a specific overview on Miscanthus biochars[J].Journal of Environmental Management,2015,162(4):275-289
[18]张鹏,武健羽,李力,等.猪粪制备的生物炭对西维因的吸附与催化水解作用[J].农业环境科学学报,2012,31(2):416-421
[19]朱志平,黄可龙,周艺.碳纳米管吸附腐植酸的动力学、热力学及机理研究[J].无机材料学报,2011,26(2):170-174
[20]黄容,高明,廖燕妮.不同生物质灰渣对磷的吸附解吸动力学特征[J].水土保持学报,2014,28(1):156-160
[21]Maghsoodloo S,Noroozi B,Haghi A K,et al.Consequence of chitosan treating on the adsorption of humic acid by granular activated carbon[J].Journal of Hazardous Materials,2011,191(1/2/3):380-387
[22]Li S,He M,Li Z,et al.Removal of humic acid from aqueous solution by magnetic multi-walled carbon nanotubes decorated with calcium[J].Journal of Molecular Liquids,2017,230(3):520-528
[23]Guan X H,Shang C,Chen G H.Competitive adsorption of organic matter with phosphate on aluminum hydroxide[J].Journal of Colloid&Interface Science,2006,296(1):51-58
[24]Qin X,Liu F,Wang G.Fractionation and kinetic processes of humic acid upon adsorption on colloidal hematite in aqueous solution with phosphate[J].Chemical Engineering Journal,2012,209(41):458-463
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