Phosphorus recovery from biogas fermentation liquid by Ca-Mg loaded biochar

Shortage in phosphorus (P) resources and P wastewater pollution is considered as a serious problem worldwide. The application of modified biochar for P recovery from wastewater and reuse of recovered P as agricultural fertilizer is a preferred process. This work aims to develop a calcium and magnesium loaded biochar (Ca-Mg/biochar) application for P recovery from biogas fermentation liquid. The physico-chemical characterization, adsorption efficiency, adsorption selectivity, and postsorption availability of Ca-Mg/biochar were investigated. The synthesized Ca-Mg/biochar was rich in organic functional groups and in CaO and MgO nanoparticles. With the increase in synthesis temperature, the yield decreased, C content increased, H content decreased, N content remained the same basically, and BET surface area increased. The P adsorption of Ca-Mg/biochar could be accelerated by nano-CaO and nano-MgO particles and reached equilibrium after 360 min. The process was endothermic, spontaneous, and showed an increase in the disorder of the solid-liquid interface. Moreover, it could be fitted by the Freundlich model. The maximum P adsorption amounts were 294.22, 315.33, and 326.63 mg/g. The P adsorption selectivity of Ca-Mg/biochar could not be significantly influenced by the typical pH level of biogas fermentation liquid. The nano-CaO and nano-MgO particles of Ca-Mg/biochar could reduce the negative interaction effects of coexisting ions. The P releasing amounts of postsorption Ca-Mg/biochar were in the order of Ca-Mg/B600 > Ca-Mg/B450 > Ca-Mg/B300. Results revealed that postsorption Ca-Mg/biochar can continually release P and is more suitable for an acid environment.     

铜藻基生物炭的水热制备及性能表征

以浙江优势大型海藻之一的铜藻为原料,采用水热炭化法制备了生物炭.同时,通过正交法,以碳回收率和得率为指标,考察了反应时间、反应温度及铜藻与去离子水质量比等因素的影响,确定制备水热炭的最佳工艺条件.结果表明,制备铜藻基水热炭的最佳工艺条件为:反应时间2 h,反应温度180℃,铜藻与去离子水质量比1/4,在此条件下,水热炭的碳回收率为65.0%,得率为51.4%.元素分析、BET、接触角测定和傅里叶红外表征结果表明,铜藻基水热炭比表面积为26.6 m2·g-1,pH值为4.8,具有较高的O/C和较低的C/N,与干法裂解炭相比,其亲水性更强,且表面具有更为丰富的含氧、含氮官能团,灰分含量更低,得率和碳回收率分别提高了53.4%和33.5%.     

沼渣生物炭基Fenton催化剂的制备及其高效降解吡虫啉农药废水的研究

以废弃物沼渣和含铁剩余污泥为原料,采用一步热解法制备沼渣生物炭基Fenton催化剂(以下简称催化剂),构建了非均相Fenton反应体系处理含吡虫啉模拟废水,考察了H2 O2和催化剂用量对吡虫啉去除率的影响.结果表明,非均相Fenton反应体系中,H2 O2最佳投加量为0.50 g/L,催化剂最佳投加量为1.00 g/L...     

不同原料生物炭对NH4+-N、PO43--P吸附性能的差异性及其成因分析

以芦苇、小麦秸秆和竹子为原料,利用回流式炭化工艺制备3种生物炭。比较三者对NH_4~+-N、PO_4~(3-)-P的吸附性能,并对三者吸附性能差异的成因进行分析。实验结果表明:3种生物炭对PO_4~(3-)-P的吸附效果整体上优于NH_4~+-N,因为3种生物炭的阳离子交换容量CEC值和Zeta电位绝对值的水平均较低,不利于阳离子的吸附;竹炭Z-C对NH_4~+-N的吸附效果最佳,6 h去除率为3.59%,低的N含量、pH及Zeta电位绝对值对NH_4~+-N的吸附有利;芦苇炭LW-C中的O更多地与K、Mg等结合,形成能够与PO_4~(3-)反应生成磷酸盐沉淀或者晶体物质的金属氧化物,从而具有最好的PO_4~(3-)-P的吸附效果,6 h时去除率达16.91%。     

玉米秸秆生物炭对沉积物中BDE-47生态毒性的影响

生物炭对于污染沉积物的原位修复具有很大的潜力,但关于生物炭对沉积物中有机污染物生态毒性影响的研究则较少报道。为评价生物炭对沉积物中BDE-47生态毒性的影响,以底栖动物铜锈环棱螺为测试生物,采用28 d慢性沉积物生物测试研究了不同添加比例的玉米秸秆生物炭(CSB)与BDE-47联合作用对BDE-47生物积累、肝胰脏细胞DNA损伤以及氧化胁迫生物标志物的影响。结果表明,在慢性暴露情况下,CSB对铜锈环棱螺不具有毒性;CSB通过显著降低沉积物间隙水中BDE-47的浓度而降低其在铜锈环棱螺体内的生物积累。在实验浓度范围内(1%～7%),CSB添加比例越高,降低BDE-47生物积累的效果越显著。不同添加比例的CSB均可以显著降低BDE-47对铜锈环棱螺DNA损伤的毒性,较高比例(4%和7%)CSB的效果更为显著,但BDE-47的氧化胁迫毒性不随CSB添加比例的升高而下降。因此,从降低BDE-47生态毒性的角度考虑,沉积物中CSB的合适添加比例为4%左右。     

柚子皮制备生物炭吸附苯酚的特性和动力学

廉价的柚子皮作为原材料制备生物炭吸附剂对含苯酚废水进行吸附研究。扫描电镜结果表明,柚子皮制备的生物炭具有较好表面吸附空间结构,比表面积测定为261.69 m2/g。此外,能谱对柚子皮生物炭元素分析发现,生物炭主要含有C、O、P、K,这些是生物质特点。红外对柚子皮生物炭分析发现生物炭含有羟基、氨基、羰基、羧基、磷酸酯或者硫酸酯等活性基团,这些是吸附苯酚的特性官能团。在初始浓度为100 mg/L,投加量为3 g/L,中性pH,30℃条件下吸附30 min后柚子皮生物炭对苯酚的去除率达到76.4%。伪二级动力学方程能很好地拟合柚子皮生物炭对苯酚的吸附过程。同时,Langmiur和Freundlich等温方程在整个温度都能较好地拟合数据,在30℃时,Langmuir理论最大吸附容量可达到49.75 mg/g。通过实际废水应用实验,表明柚子皮生物炭是一种有潜力可用于高浓度含酚废水的处理的有效材料。     

热解温度和时间对生物干化污泥生物炭性质的影响

污泥热解制备生物炭是一种很有潜力的污泥资源化处置方式,然而,生物炭产量和品质因污泥原料性质、热解条件(如热解温度、时间)的不同而存在显著差异。以生物干化污泥为主要研究对象,系统考察了热解温度及时间等热解因素对生物炭品质的影响。实验结果表明,随着热解温度的升高(300～700℃),热解时间的增加(2～4 h),生物炭产率均下降。低温热解(300℃)生物炭,偏酸性,而高温热解时(700℃)生物炭,偏碱性。生物炭N含量随着热解温度的升高、热解时间的增加而降低,而P、K及微量元素随着热解温度的升高,热解时间的增加而增加。DTPA浸提结果表明,高温热解明显降低了生物炭中微量元素的生物有效性。     

Efficacy of biochar in removal of organic pesticide,Bentazone from watershed systems

Abstract

Bentazone is one of the toxic insecticides used to control forest tent caterpillar moths, boll weevils, gypsy moths, and other types of moths in various field crops. We report the efficacy of biochar prepared from the Azardirachta Indica waste biomass as adsorbent for removal of Bentazone. Biochar material was prepared by pyrolysis process under limited oxygen conditions. Biochar material was characterized by proximate and ultimate analysis, SEM analysis, FTIR analysis and TG/DTA analyses. The Bentazone adsorption capacity by biochar from aqueous solutions was assessed. Effect of time, adsorbent dosage, insecticide concentration and pH on the adsorption characteristics of the biochar were evaluated. Adsorption parameters were obtained at equilibrium contact time of 150?min, with biochar dosage of 0.5?g at pH 8. From the optimization studies, desirability of 0.952 was obtained with response (adsorption uptake) of 79.40?mg/g, for initial concentration of insecticide (50?mg/L), adsorbent dosage (0.448?g), time 30.0?min and pH 2. The adsorption isotherm data for the removal of Bentazone fitted well with the Freundlich isotherm. This study indicates that the biochar produced from the bark of Azardirachta Indica biomass could be employed as a potential adsorbent for removal of synthetic organic pollutants from the water streams.     

生物炭配施磷肥对土壤养分、酶活性及紫花苜蓿养分吸收的影响

生物炭作为一种既能单独施用,又能与化肥共同施用的土壤改良剂,在农业生产实践中被广泛施用.然而,关于不同粒径生物炭与磷肥联合施用对土壤和植物的影响研究较少.采用盆栽试验,研究在两个磷水平下,不同粒径生物炭对土壤养分、酶活性以及紫花苜蓿养分吸收的影响[生物炭根据直径分为：C1(>1 mm)和C2(<0.01 mm)这两种处理].结果表明,生物炭和磷联合施用显著提高了土壤养分、酶活性和苜蓿养分吸收;其中,C2处理显著提高了土壤有效磷含量(P<0.05)和磷酸酶活性(P<0.01),而C1处理对铵态氮、硝态氮、脲酶和过氧化氢酶活性有显著影响(P<0.05).并且,不同粒径生物炭处理间的养分及酶的差异受到土壤磷水平的影响,P0水平下,C1和C2处理的铵态氮和硝态氮含量并没有显著差异;而在P1水平下,C1处理的铵态氮和硝态氮含量比C2处理高24.19%和18.68%(P<0.05),但C1和C2处理的有效磷之间并无显著差异;磷添加显著提高了苜蓿地上和地下部的N和P含量(P<0.05),但是不同粒径生物炭之间苜蓿养分含量并没有显著影响.综上所述,生物炭与磷肥...     

富含钙/铝的污泥生物炭复合材料对水溶液中磷酸盐的吸附机制

剩余污泥富含有机物,同时也含有重金属和病原体等有害物质.以水铝钙石和剩余污泥为原料,通过共混凝和共热解技术制备生物炭以降低污泥中重金属溶出风险,并对其磷酸盐吸附性能开展研究.结果表明,污泥生物炭中的Zn、Cu、Cd和Ni浸出量随水铝钙石投加量的增加而减少.水铝钙石与剩余污泥质量比为1∶1时,共热解制备得到的富含钙/铝污泥生物炭复合材料(1∶1HB800)重金属浸出风险最低,并对磷酸盐表现出较高的吸附能力,其过程可用Langmuir吸附等温线(R²=0.93)拟合,在25℃条件下对磷的最大吸附容量为51.38 mg·g^-1.1∶1HB800对高浓度磷的吸附过程符合拟二阶动力学模型,吸附速率由表面吸附和颗粒内扩散共同控制.相较于中性溶液,1∶1HB800对酸性和碱性水溶液中的磷酸盐具有更好的去除效果,这与1∶1HB800中钙/铝在不同pH条件下的浸出量及铝元素的存在形式有关.FTIR、XRD、SEM、零点电位和钙/铝离子的浸出实验分析结果表明,1∶1HB800对磷的吸附机制主要是共沉淀(Ca²⁺/Al³⁺