Application of Chicken Manure-derived Biochar for Adsorption of Lead

doi:10.13304/j.nykjdb.2021.0566

Abstract

Abstract:

With the rapid development of large-scale breeding， the production of poultry manure increases accordingly， how to treat and recycle it has increasingly become a research hotspot. The performance of chicken manure-derived biochar （CMBC-400， pyrolysis temperature of 400 ℃） was investigated to remove Pb²⁺in wastewater. The sorption kinetics， isotherms and thermodynamics of Pb²⁺ adsorption on CMBC-400 were investigated by batch experiments. The experimental data fitted well with the pseudo-second order model， which indicated chemisorption was the rate-limiting step of sorption process. Equilibrium sorption of CMBC-400 on Pb²⁺ fitted best with the Langmuir model， indicating a fixed number of identical and energetically equivalent active sites on the homogeneous surface of CMBC-400. The thermodynamic investigation confirmed that the sorption of CMBC-400 on Pb²⁺ could carry out spontaneously， and the higher temperature favored the processes. The SEM and XRD analysis indicated that CMBC-400 could intensely adsorb solution Pb²⁺ via precipitation of Pb-containing microcrystals. Moreover， soil experiments indicated that addition of CMBC-400 could effectively enhanced the conversion of the available Pb to the stable forms， thereby decreasing the bioavailability of soil Pb.

Key words: chicken manure-derived biochar, Pb, adsorption, immobilization

摘要：

随着规模化养殖的快速发展，畜禽粪便的产量随之增加，如何对其进行有效处理与资源化利用已成为研究热点。选取鸡粪为原料，在400 ℃下限氧热解制备生物炭（CMBC-400），探究其对水体中铅离子（Pb²⁺）的吸附性能。通过批处理试验考察吸附时间、Pb²⁺初始含量、吸附温度等因素对CMBC-400吸附Pb²⁺性能的影响，并利用吸附动力学、等温线和热力学计算模型对吸附数据进行拟合，进一步阐述吸附过程。结果表明，CMBC-400吸附Pb²⁺的过程更符合准二级动力学模型，表明该吸附过程的吸附速率主要受化学吸附控制；相比Freundlich和Dubinin-Radushkevich （D-R）模型，Langmuir等温线模型具有更高的拟合相关系数，表明CMBC-400表面均一，Pb²⁺吸附位点的吸附能大致相同；吸附热力学数据表明CMBC-400对Pb²⁺的吸附过程是自发的吸热反应。扫描电镜和X-射线衍射表征结果表明，CMBC-400主要通过在表面形成含Pb微晶的形式固定水体中的Pb²⁺。此外，向土壤中添加CMBC-400还可促进有效态Pb转化为稳定态，降低Pb的生物有效性。

关键词: 鸡粪生物炭, 铅, 吸附, 固定

CLC Number:

S141

Lei ZHOU, Zhaolan CHEN, Yubo YAN, Qiao LI. Application of Chicken Manure-derived Biochar for Adsorption of Lead[J]. Journal of Agricultural Science and Technology, 2022, 24(11): 199-207.

周蕾, 陈兆兰, 严玉波, 李桥. 鸡粪生物炭吸附固定铅的研究[J]. 中国农业科技导报, 2022, 24(11): 199-207.

Figures/Tables 9

Fig. 1 Adsorption of CMBC-400 on Pb2+ and linear fitting for adsorption kineticsA： Adsorption capacity； B： Linear fitting for adsorption kinetics

Table 1 Kinetic parameters for the adsorption of Pb2+

实测平衡吸附量q_e，exp/（mg·g^-1）

准一级动力学模型

Pseudo-first order model

准二级动力学模型

Pseudo-second order model

k₁/（g·mg^-1·min^-1）

理论平衡吸附量q_e，cal/（mg·g^-1）

决定系数R²

k₂/（g·mg^-1·min^-1）

理论平衡吸附量q_e，cal/（mg·g^-1）

Fig. 2 Adsorption of CMBC-400 on different Pb2+ mass concentrations and linear fitting for adsorption kineticsA： Effect of initial concentration on Pb2+ adsorption； B： Langmuir fitting curves； C： Freundlich fitting curves； D： D-R fitting curves

Table 2 Isotherm parameters for the adsorption of Pb2+

Langmuir

Freundlich

D-R

最大吸附量

q_max/（mg·g^-1）

b/（L·mg^-1）

决定系数

R²

K_F/（mg·g^-1）

1/n

决定系数

R²

理论饱和吸附量q_m /（mg·g^-1）

吸附自由能

E/（kJ·mol^-1）

决定系数

R²

Table 3 Comparison of maximum adsorption capacities for Pb2+ on various adsorbents

吸附剂 Adsorbent	最大吸附容量q_max/（mg·g^-1）	参考文献 Reference
鸡粪生物炭 CMBC-400	149.30	本研究 This study
棉花秸秆生物炭 Cotton straw biochar	33.78	［6］
木屑生物炭 Sawdust biochar	77.12	［19］
柚子皮生物炭 Pomelo peel biochar	93.09	［20］
双孢菇菌糠生物炭 Agaricus bisporus substrate biochar	266.23	［21］
酒糟生物炭 Wine lees-derived biochar	79.12	［22］
甘蔗生物炭 Sugar cane bagasse biochar	86.96	［23］
橙皮生物炭 Orange peel biochar	27.86	［23］
豚草生物炭 Invasive plant species biochar	358.70	［24］

Table 4 Thermodynamic parameters for the adsorption of Pb2+

温度 T/K	自由能变 ΔG $°$ /（kJ·mol^-1）	焓变 ΔH $°$ /（kJ·mol^-1）	熵变 ΔS $°$ /（kJ·mol^-1·K^-1）
293	-4.35	55.71	0.20
308	-5.75
323	-10.55

Table 4 Thermodynamic parameters for the adsorption of Pb2+

温度 T/K	自由能变 ΔG $°$ /（kJ·mol^-1）	焓变 ΔH $°$ /（kJ·mol^-1）	熵变 ΔS $°$ /（kJ·mol^-1·K^-1）
293	-4.35	55.71	0.20
308	-5.75
323	-10.55

Fig. 3 SEM images of CMBC-40A： CMBC-400； B~C： CMBC-400 loaded Pb2+

Fig. 4 XRD patterns of CMBC-400 before and after Pb2+ adsorption

Fig. 5 Pb mass concentration extracted by CaCl2 and proportion of different Pb forms amended with CMBC-400

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