慢热解木质生物炭对磷酸铵吸附解吸性能的评价

IF 0.9 4区环境科学与生态学 Q4 ENVIRONMENTAL SCIENCES

Environmental Engineering and Management Journal Pub Date : 2021-02-01 DOI:10.30638/EEMJ.2021.022

M. Rezaee, S. Gitipour, M. Sarrafzadeh

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引用次数: 5

摘要

生物炭作为一种土壤改良剂和用于水净化的有机/无机吸附剂而备受关注。在这种情况下，正确使用生物炭需要了解营养物质在生物炭上的吸附和解吸机制。在本研究中，在400和600℃的温度下制备了缓慢热解的木材生物炭，停留时间分别为60和120分钟，以研究其对磷酸盐和铵的吸附能力。评价了热解工艺条件和生物炭理化性质对潜在吸附能力的影响。吸附动力学结果表明，拟一阶和拟二阶模型都能很好地预测磷和铵的吸附动力学，表明化学吸附是磷和铵吸附的主要机制之一。Langmuir-Freundlich等温线是最适合铵吸附的模型，这意味着在非均相表面上发生化学吸附，而Langmuir等温线与磷酸盐吸附非常吻合。对于不同的生物炭，铵的吸附量范围为约0.34至5.3mg/g，磷酸盐的吸附量为约0.6至42.2mg/g。随着热解温度的升高和停留时间的延长，磷酸盐的吸附能力提高。然而，在较低的热解温度和停留时间下观察到的较高的铵吸附可归因于更多的含氧官能团。生物炭对磷酸盐和铵的吸附-解吸与溶液pH的关系更为密切，在pH为7和3时，分别观察到铵和磷酸盐的最大吸附容量。

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EVALUATION OF PHOSPHATE AND AMMONIUM ADSORPTIONDESORPTION OF SLOW PYROLYZED WOOD BIOCHAR

Biochar is attracting attention as a soil amendment and organic/inorganic adsorbent for water purification. Proper use of biochar in such cases requires understanding of the mechanisms of nutrient adsorption and desorption on biochar. In this study, slow pyrolyzed wood biochar s were prepared at temperatures 400 and 600 C with retention time of 60 and 120 minutes to investigate their phosphate and ammonium adsorption capacities. The effects of pyrolysis process conditions and biochar physicochemical properties on potential adsorption capacity were evaluated. Results of adsorption kinetics showed that both pseudo-first-order and pseudosecond-order models could well predict the adsorption kinetics of phosphate and ammonium indicating that the chemical adsorption was one of the main mechanisms of phosphate and ammonium absorption. Langmuir-Freundlich isotherm was the best-fit model for ammonium adsorption which means the occurrence of chemical adsorption on heterogeneous surface whilst Langmuir isotherm agreed well with the phosphate adsorption. For different biochar s, ammonium adsorption capacity ranged from about 0.34 to 5.3 mg/g and phosphate adsorption capacity ranged from about 0.6 to 42.2 mg/g. Phosphate adsorption capacity improved with increasing temperature and retention time of pyrolysis process. However, higher ammonium adsorption which was observed in lower pyrolysis temperature and residence time can be attributed to more oxygen-containing functional groups. Both phosphate and ammonium adsorptions-desorption by biochar are more strongly related to solution pH, and maximum adsorption capacities were observed at pH of 7 and 3 for ammonium and phosphate, respectively.

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来源期刊

Environmental Engineering and Management Journal 环境科学-环境科学

CiteScore

1.60

自引率

36.40%

发文量

审稿时长

8.6 months

期刊介绍： Environmental Engineering and Management Journal is an international journal that publishes reviewed original research papers of both experimental and theoretical nature in the following areas: environmental impact assessment; environmental integrated management; risk assessment and management; environmental chemistry; environmental protection technologies (water, air, soil); pollution reduction at source and waste minimization; chemical and biological process engineering; cleaner production, products and services; sensors in environment control; sources of radiation and protection technologies; waste valorization technologies and management; environmental biotechnology; energy and environment; modelling, simulation and optimization for environmental protection; technologies for drinking and industrial water; life cycle assessments of products; environmental strategies and policies; cost-profitt analysis in environmental protection; eco-industry and environmental market; environmental education and sustainable development. Environmental Engineering and Management Journal will publish: original communications describing important new discoveries or further developments in the above-mentioned topics; reviews, mainly of new rapidly developing areas of environmental protection; special themed issues on relevant topics; advertising.