Systematic optimization of biochars derived from corn wastes, pineapple leaf, and sugarcane bagasse for Cu(II) adsorption through response surface methodology.
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[1] G. Mazza,et al. Exergo-ecological analysis and life cycle assessment of agro-wastes using a combined simulation approach based on cape open to cape open (COCO) and SimaPro free-software , 2022, Renewable Energy.
[2] T. Yoshioka,et al. A novel strategy for rapid identification of pyrolytic synergy and prediction of product yield: insight into co-pyrolysis of xylan and polyethylene , 2022, Chemical Engineering Journal.
[3] Cuijuan Feng,et al. Specific chemical adsorption of selected divalent heavy metal ions onto hydrous γ-Fe2O3-biochar from dilute aqueous solutions with pH as a master variable , 2022, Chemical Engineering Journal.
[4] Shaziya H. Siddiqui,et al. Sequestration of Ni(II) and Cu(II) using FeSO4 modified Zea mays husk magnetic biochar: Isotherm, kinetics, thermodynamic studies and RSM , 2022, Journal of Hazardous Materials Advances.
[5] Ming Zhang,et al. Optimization of target biochar for the adsorption of target heavy metal ion , 2022, Scientific Reports.
[6] G. Mazza,et al. Multiobjective Optimization and Implementation of a Biorefinery Production Scheme for Sustainable Extraction of Pectin from Quince Biowaste , 2022, ACS Engineering Au.
[7] Deepak Kumar Sharma,et al. Effectiveness of Wheat Straw Biochar in Aqueous Zn Removal: Correlation with Biochar Characteristics and Optimization of Process Parameters , 2022, BioEnergy Research.
[8] W. Ding,et al. Insight into the co-removal of Cu(II) and ciprofloxacin by calcite-biochar composite: Enhancement and competition , 2022, Separation and Purification Technology.
[9] Kai Jiang,et al. Sulfur-functionalized Biochar Derived from Sodium Thiosulfate Modified Molten Salt Process for the Efficient Removal of Heavy Metal , 2022, Chemical Engineering Journal.
[10] Zhongbing Lin,et al. Effects of competitive adsorption with Ni(II) and Cu(II) on the adsorption of Cd(II) by modified biochar co-aged with acidic soil. , 2022, Chemosphere.
[11] Yingquan Chen,et al. Coeffect of pyrolysis temperature and potassium phosphate impregnation on characteristics, stability, and adsorption mechanism of phosphorus-enriched biochar. , 2021, Bioresource technology.
[12] T. Vo,et al. Adsorption of norfloxacin from aqueous solution on biochar derived from spent coffee ground: Master variables and response surface method optimized adsorption process. , 2021, Chemosphere.
[13] C. Weng,et al. Adsorption of metal on pineapple leaf biochar: key affecting factors, mechanism identification, and regeneration evaluation. , 2021, Bioresource technology.
[14] Xiaoyao Dao,et al. Calcite modification of agricultural waste biochar highly improves the adsorption of Cu(II) from aqueous solutions , 2021 .
[15] A. Vyas,et al. Parametric study and optimization of microwave assisted biodiesel synthesis from Argemone Mexicana oil using Response surface methodology , 2021, Chemical Engineering and Processing - Process Intensification.
[16] R. Hasanzadeh,et al. A novel systematic multi-objective optimization to achieve high-efficiency and low-emission waste polymeric foam gasification using response surface methodology and TOPSIS method , 2021, Chemical Engineering Journal.
[17] Hao-Bo Zheng,et al. Adsorption behaviors of paper mill sludge biochar to remove Cu, Zn and As in wastewater , 2021 .
[18] Yifan Sun,et al. In situ characterization of functional groups of biochar in pyrolysis of cellulose. , 2021, The Science of the total environment.
[19] K. Klouda,et al. Biochar – An efficient sorption material for the removal of pharmaceutically active compounds, DNA and RNA fragments from wastewater , 2021 .
[20] Shih-han Huang,et al. Comprehending the Causes of Presence of Copper and Common Heavy Metals in Sediments of Irrigation Canals in Taiwan , 2021, Minerals.
[21] Lujia Han,et al. Characteristics, adsorption behaviors, Cu(II) adsorption mechanisms by cow manure biochar derived at various pyrolysis temperatures. , 2021, Bioresource technology.
[22] Donghai Wang,et al. Effect of ultrasonic vibration-assisted pelleting of biomass on biochar properties , 2021, Journal of Cleaner Production.
[23] G. K. Gupta,et al. Mechanism of Cr(VI) uptake onto sagwan sawdust derived biochar and statistical optimization via response surface methodology , 2020, Biomass Conversion and Biorefinery.
[24] H. Panahi,et al. A comprehensive review of engineered biochar: Production, characteristics, and environmental applications , 2020 .
[25] Junboum Park,et al. High efficiency removal of heavy metals using tire-derived activated carbon vs commercial activated carbon: Insights into the adsorption mechanisms. , 2020, Chemosphere.
[26] F. Güzel,et al. Sorptive removal of copper(II) from water by biochar produced from a novel sustainable feedstock: wild herbs , 2020, Environmental Science and Pollution Research.
[27] M. Naeth,et al. Biochar surface complexation and Ni(II), Cu(II), and Cd(II) adsorption in aqueous solutions depend on feedstock type. , 2020, The Science of the total environment.
[28] G. Zeng,et al. Synergistic removal of copper and tetracycline from aqueous solution by steam-activated bamboo-derived biochar. , 2020, Journal of hazardous materials.
[29] Ling-hong Zhu,et al. Key factors and microscopic mechanisms controlling adsorption of cadmium by surface oxidized and aminated biochars. , 2020, Journal of hazardous materials.
[30] S. Roan,et al. A New Pineapple Cultivar, Tainung No. 23, with Improved Fruit Quality in Summer , 2019, HortScience.
[31] Jinpeng Wang,et al. Optimization of biochar preparation from the stem of Eichhornia crassipes using response surface methodology on adsorption of Cd2+ , 2019, Scientific Reports.
[32] Yongtao Li,et al. Adsorption of cadmium and lead ions by phosphoric acid-modified biochar generated from chicken feather: Selective adsorption and influence of dissolved organic matter. , 2019, Bioresource technology.
[33] X. Shu,et al. Effects of residence time on characteristics of biochars prepared via co-pyrolysis of sewage sludge and cotton stalks , 2019, Journal of Analytical and Applied Pyrolysis.
[34] B. Shan,et al. Effects of the pyrolysis temperature on the biotoxicity of Phyllostachys pubescens biochar in the aquatic environment. , 2019, Journal of hazardous materials.
[35] Y. Liu,et al. Assessing the effect of pyrolysis temperature on the molecular properties and copper sorption capacity of a halophyte biochar. , 2019, Environmental pollution.
[36] W. Prins,et al. Production and characterization of slow pyrolysis biochar from lignin-rich digested stillage from lignocellulosic ethanol production , 2019, Biomass and Bioenergy.
[37] Zhi Zhou,et al. Effect of pyrolysis condition on the adsorption mechanism of lead, cadmium and copper on tobacco stem biochar , 2018, Journal of Cleaner Production.
[38] I. Lima,et al. Effect of feed source and pyrolysis conditions on properties and metal sorption by sugarcane biochar , 2018 .
[39] Daniel C W Tsang,et al. Effect of pyrolysis temperature, heating rate, and residence time on rapeseed stem derived biochar , 2018 .
[40] C. Silva,et al. Properties of biochar derived from wood and high-nutrient biomasses with the aim of agronomic and environmental benefits , 2017, PloS one.
[41] G. Cornelissen,et al. Cation exchange capacity of biochar: An urgent method modification. , 2017, The Science of the total environment.
[42] F. Macías,et al. Influence of feedstock on the copper removal capacity of waste-derived biochars. , 2016, Bioresource technology.
[43] Mei-Hui Su,et al. Water footprint analysis of bioethanol energy crops in Taiwan , 2015 .
[44] K. M. Tripathi,et al. Effective removal of copper ions from aqueous solution using base treated black tea waste , 2014 .
[45] Andrew Cross,et al. The effect of pyrolysis conditions on biochar stability as determined by three methods , 2013 .
[46] J. Lehmann,et al. Corn growth and nitrogen nutrition after additions of biochars with varying properties to a temperate soil , 2012, Biology and Fertility of Soils.
[47] K. Cai,et al. Relative distribution of Cd2+ adsorption mechanisms on biochars derived from rice straw and sewage sludge. , 2019, Bioresource technology.
[48] C. Mackowiak,et al. Pyrolysis methods impact biosolids-derived biochar composition, maize growth and nutrition , 2017 .
[49] Jia Liu,et al. Effects of pyrolysis temperature and heating time on biochar obtained from the pyrolysis of straw and lignosulfonate. , 2015, Bioresource technology.
[50] D. Sparks. 5 – Sorption Phenomena on Soils , 1995 .