Study on adsorption efficiency and mechanism of methylene blue in water by Chinese medicine ricepaperplant pith residue

doi:10.19965/j.cnki.iwt.2022-0598

Abstract

Abstract:

The Chinese medicine ricepaperplant pith residue was selected as a biosorbent for the adsorption of methylene blue （MB） in water to investigate its adsorption efficacy and mechanism. The Box-Behnken Design of response surface methodology was used to investigate the effects of adsorbent dosing， pH， initial mass concentration of MB solution and adsorption time on the removal of MB， and the experimental parameters were optimized. The agreement between the predicted and experimental values was verified experimentally under the conditions of optimal parameter combinations. The adsorption isotherm and kinetic model fitting results showed that the adsorption process of MB from water by ricepaperplant pith residue was consistent with the Langmuir model （R²=0.997） and pseudo-second kinetic model （R²=0.999 8）， and the adsorption amount was 115.72 mg/g， indicating that the adsorption process was dominated by homogeneous monolayer adsorption. The adsorption rate of MB was controlled by both membrane diffusion and intra particle diffusion. Meanwhile， the adsorption process had the exchange of Na⁺， K⁺ and Ca²⁺， and the effect on Cl^- and SO₄^2- was not obvious. The characterization results showed that the adsorption of MB in solution by ricepaperplant pith residue showed an increase in specific surface area， deepening of pore volume， reduction in pore size， smaller charge intensity and little change in infrared groups， suggesting that the adsorption of MB in water by ricepaperplant pith residue is a monolayer adsorption with mainly electrostatic adsorption effect.

Key words: ricepaperplant pith, Chinese medicine residue, bioadsorption, methylene blue, response surface methodology

摘要：

选择中药通草残渣作为生物吸附剂，对水中亚甲基蓝染料（MB）进行吸附，探究其吸附效能和吸附机理。采用响应面法中Box-Behnken Design，考察吸附剂投加量、pH、MB溶液初始质量浓度和吸附时间对通草残渣去除MB的影响，并对实验参数进行优化。在最优参数组合条件下，通过实验验证其预测值和实验值符合度一致。吸附等温线与动力学模型拟合结果显示：通草残渣对水中亚甲基蓝的吸附过程符合Langmuir模型（R²=0.997）和准二级动力学模型（R²=0.999 8），其吸附量为115.72 mg/g，表明该吸附过程以均匀的单层吸附为主，对亚甲基蓝的吸附速率受膜扩散和颗粒内扩散共同控制。同时，该吸附过程存在Na⁺、K⁺、Ca²⁺的交换情况，对Cl^-、SO₄^2-的影响不明显。表征结果显示，通草残渣吸附水溶液中的亚甲基蓝后，出现比表面积增大、孔容加深、孔径缩小、电荷强度变小、红外基团变化不大的特点，提示通草残渣对水中亚甲基蓝是以静电吸附作用为主的单层吸附类型。

关键词: 通草, 中药渣, 生物吸附, 亚甲基蓝, 响应面法

CLC Number:

X703

Ya GAO, Dong LIANG, Huan CHANG, Peilin HE, Xin LIU. Study on adsorption efficiency and mechanism of methylene blue in water by Chinese medicine ricepaperplant pith residue[J]. Industrial Water Treatment, 2023, 43(4): 121-129.

高雅, 梁栋, 常欢, 何佩霖, 刘新. 中药通草渣对水中亚甲基蓝吸附效能与机理的研究[J]. 工业水处理, 2023, 43(4): 121-129.

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https://www.iwt.cn/EN/Y2023/V43/I4/121

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References 30

1	SHINDHAL T， RAKHOLIYA P， VARJANI S，et al. A critical review on advances in the practices and perspectives for the treatment of dye industry wastewater［J］. Bioengineered，2021，12（1）：70-87. doi:10.1080/21655979.2020.1863034
2	孙兰梅，孙宇明，李明阳，等.各种吸附材料对亚甲基蓝废水处理的研究［J］.山东化工，2018，47（14）：197-198. doi:10.3969/j.issn.1008-021X.2018.14.083
	SUN Lanmei， SUN Yuming， LI Mingyang，et al. Study on treatment of methylene blue wastewater by various adsorbent materials［J］. Shandong Chemical Industry，2018，47（14）：197-198. doi:10.3969/j.issn.1008-021X.2018.14.083
3	杨倩. 生物吸附法处理水体中重金属离子的研究进展［J］.云南化工，2018，45（7）：76-78. doi:10.3969/j.issn.1004-275X.2018.07.033
	YANG Qian. Advances in biological adsorption treatment of heavy metal ions in water［J］. Yunnan Chemical Technology，2018，45（7）：76-78. doi:10.3969/j.issn.1004-275X.2018.07.033
4	葛晓利，钟永科.大黄药渣制备超级活性炭［J］. 炭素技术，2014，33（2）：35-38.
	GE Xiaoli， ZHONG Yongke. Preparation of super activated carbon from rhubarb residue［J］. Carbon Techniques，2014，33（2）：35-38.
5	中国食品药品网：我国中药材产业发展现状［EB/OL］. （2021-09-13）［2022-04-15］.. doi:10.1016/j.chmed.2021.01.004
	China food and drug network：China's Chinese herbal medicine industry development status［EB/OL］. （2021-09-13）［2022-04-15］. doi:10.1016/j.chmed.2021.01.004
6	黄卉，麻馨尹，石静蕾，等.中药渣有机肥对土壤生态及药用植物生长发育的影响［J］.中药材，2020，43（5）：1266-1270. doi:10.13863/j.issn1001-4454.2020.05.045
	HUANG Hui， MA Xinyi， SHI Jinglei，et al. Effect of organic fertilizer of Chinese medicine residue on soil ecology and growth and development of medicinal plants［J］. Journal of Chinese Medicinal Materials，2020，43（5）：1266-1270. doi:10.13863/j.issn1001-4454.2020.05.045
7	马春芳.化学改性甘草废渣吸附剂的制备及其对重金属离子和染料分子吸附性能的研究［D］.银川：宁夏医科大学，2015.
	MA Chunfang. Preparation of chemically modified licorice waste adsorbent and its adsorption performance on heavy metal ions and dye molecules［D］. Yinchuan：Ningxia Medical University，2015.
8	SUN Qianzhe， SARATALE R G， SARATALE G D，et al. Pristine and modified radix Angelicae dahuricae （Baizhi） residue for the adsorption of methylene blue from aqueous solution：A comparative study［J］. Journal of Molecular Liquids，2018，265：36-45. doi:10.1016/j.molliq.2018.05.108
9	YAN T， LE L， HUI Z，et al. Adsorption and recovery of U（Ⅵ） from actual acid radioactive wastewater with low uranium concentration using thioacetamide modified activated carbon from liquorice residue［J］. Journal of Radioanalytical and Nuclear Chemistry，2018，317（2）：811-824. doi:10.1007/s10967-018-5952-8
10	TAO F， WANG Y， ZHAO Z，et al. Effective removal of Cr（VI） in aqueous solutions using Caulis lonicerae residue fermented by Phanerochaete chrysosporium［J］. Preparative Biochemistry & Biotechnology，2021，51（9）：842-851. doi:10.1080/10826068.2020.1805623
11	LI Zhen， HAN Qiang， ZONG Zhifan，et al. Exploring on the optimal preparation conditions of activated carbon produced from solid waste produced from sugar industry and Chinese medicine factory［J］. Waste Disposal & Sustainable Energy，2020，2：65-77. doi:10.1007/s42768-019-00032-w
12	李雨轩，朱鹤云，金春梅，等. 通草的化学成分及药理作用的研究进展［J］.吉林医药学院学报，2021，42（4）：293-295.
	LI Yuxuan， ZHU Heyun， JIN Chunmei，et al. Progress of research on the chemical composition and pharmacological effects of Tongcao［J］. Journal of Jilin Medical University，2021，42（4）：293-295.
13	LANGMUIR. The adsorption of gases on plane surfaces of glass，mica and platinum［J］. Journal of the American Chemical Society，1918，143（9）：1361-1403. doi:10.1021/ja02242a004
14	DANG V B， DOAN H D， DANG V T，et al. Equilibrium and kinetics of biosorption of cadmium（Ⅱ） and copper（Ⅱ） ions by wheat straw［J］.Bioresource Technology，2009，100（1）：211–219. doi:10.1016/j.biortech.2008.05.031
15	FREUNDLICH H M. Over the adsorption in solution［J］. Journal of Physical Chemistry A，1906，57：385-471. doi:10.1515/zpch-1907-5723
16	TEMKIN M， PYZHEV V. Recent modifications to Langmuir isotherms［J］. Acta Physico-Chimica Sinica，1940，12：217-222.
17	LANGERGREN S. About the theory of so-called adsorption of soluble substance［J］. Kung Sven Veten Hand，1898，24（4）：1-39.
18	HO Y S， MCKAY G. Pseudo-second order model for sorption processes［J］. Process Biochemistry，1999，34（5）：451-465. doi:10.1016/s0032-9592(98)00112-5
19	WEBER W J， MORRIS J C. Kinetics of adsorption on carbon from solution［J］. Asce Sanitary Engineering Division Journal，1963，1（2）：1-20. doi:10.1061/jsedai.0000430
20	HE P， LIU J， REN ZR，et al. Optimization and mechanisms of methylene blue removal by foxtail millet shell from aqueous water and reuse in biosorption of Pb（Ⅱ），Cd（Ⅱ），Cu（Ⅱ），and Zn（Ⅱ） for secondary times［J］. Journal of Phytoremediation，2022，24（4）：350-363. doi:10.1080/15226514.2021.1944978
21	BATISTA JÚNIOR R， SILVÉRIO B C， SOARES R R，et al. Response surface methodology applied to spent coffee residue pyrolysis：effect of temperature and heating rate on product yield and product characterization［J］. Biomass Conversion and Biorefinery，2021：1-14. doi:10.1007/s13399-021-01536-4
22	PENG S H， WANG R， YANG L Z，et al. Biosorption of copper，zinc，cadmium and chromium ions from aqueous solution by natural foxtail millet shell［J］. Ecotoxicology and Environmental Safety，2018，165：61-69. doi:10.1016/j.ecoenv.2018.08.084
23	田铖.基于响应面法的结构优化设计研究［D］. 上海：上海海洋大学，2016.
	TIAN Yue. Research on structural optimization design based on response surface method［D］. Shanghai：Shanghai Ocean University，2016.
24	DU Z， ZHANG Y， LI Z，et al. Facileone-pot fabrication of nano-Fe₃O₄/carboxyl-functionalized baker's yeast compositesand their application in methylene blue dye adsorption［J］. Applied Surface Science，2017，392：312–320. doi:10.1016/j.apsusc.2016.09.050
25	MALASH G F， EL-KHAIARY M I. Methylene blue adsorption by the waste of Abu-Tartour phosphate rock［J］. Journal of Colloid and Interface Science，2010，348（2）：537–545. doi:10.1016/j.jcis.2010.05.005
26	KAZAK O， EKER Y R， AKIN I，et al. A novel red mud@sucrose based carbon composite：preparation，characterization and its adsorption performance toward methylene blue in aqueous solution［J］. Journal of Environmental Chemical Engineering，2017，5（3）：2639-2647. doi:10.1016/j.jece.2017.05.018
27	LIU Y， ZHAO X， LI J，et al. Characterization of bio-char from pyrolysis of wheat straw and its evaluation on methylene blue adsorption［J］. Desalination and Water Treatment，2012，46（1/2/3）：115–123. doi:10.1080/19443994.2012.677408
28	侯韦竹，丁晶，赵庆良，等. 响应面法优化电氧化-絮凝耦合工艺深度处理垃圾渗滤液［J］. 中国环境科学，2017，37（3）：948-955.
	HOU Weizhu， DING Jing， ZHAO Qingliang，et al. Optimization of electro-oxidation and electro-coagulation combination process for landfill leachate advanced treatment by response surface methodology［J］. China Environmental Science，2017，37（3）：948-955.
29	WANG Jianlong， GUO Xuan. Adsorption isotherm models：Classification，physical meaning，application and solving method［J］. Chemosphere，2020，258：127279-127279. doi:10.1016/j.chemosphere.2020.127279
30	LIMA E C， SHER F， GULERIA A，et al. Is one performing the treatment data of adsorption kinetics correctly？［J］. Journal of Environmental Chemical Engineering，2021，9（2）：104813. doi:10.1016/j.jece.2020.104813

因素	水平
因素	-1	0	1
JZ吸附剂投加量（A）/（g·L^-1）	1	3	5
MB初始质量浓度（B）/（mg·L^-1）	100	300	500
pH（C）	2	6	10
吸附时间（D）/min	5	122.5	240

因素	水平
因素	-1	0	1
JZ吸附剂投加量（A）/（g·L^-1）	1	3	5
MB初始质量浓度（B）/（mg·L^-1）	100	300	500
pH（C）	2	6	10
吸附时间（D）/min	5	122.5	240

来源	平方和	自由度	均方差	F	P
模型	20 341.61	1	1 452.97	18.29	<0.000 1
A	3 298.09	1	3 298.09	41.51	<0.000 1
B	3 021.97	1	3 021.97	38.04	<0.000 1
C	9 523.71	1	9 523.71	119.87	<0.000 1
D	85.07	1	85.07	1.07	0.318 3
AB	186.87	1	186.87	2.35	0.147 4
AC	16.81	1	16.81	0.21	0.652 6
AD	33.76	1	33.76	0.42	0.525 1
BC	186.60	1	186.6	2.35	0.147 7
BD	49.07	1	49.07	0.62	0.445 0
CD	99.60	1	99.60	1.25	0.281 7
A²	637.74	1	637.74	8.03	0.013 3
B²	14.15	1	14.15	0.18	0.679 4
C²	3 527.67	1	3 527.67	44.40	<0.000 1
D²	87.45	1	87.45	1.10	0.311 9
残差	1 112.27	14	79.45	—	—
失拟项	1 039.47	10	103.95	5.71	0.053 8
纯误差	72.80	4	18.20	—	—
总计	21 453.88	28	—	—	—

来源	平方和	自由度	均方差	F	P
模型	20 341.61	1	1 452.97	18.29	<0.000 1
A	3 298.09	1	3 298.09	41.51	<0.000 1
B	3 021.97	1	3 021.97	38.04	<0.000 1
C	9 523.71	1	9 523.71	119.87	<0.000 1
D	85.07	1	85.07	1.07	0.318 3
AB	186.87	1	186.87	2.35	0.147 4
AC	16.81	1	16.81	0.21	0.652 6
AD	33.76	1	33.76	0.42	0.525 1
BC	186.60	1	186.6	2.35	0.147 7
BD	49.07	1	49.07	0.62	0.445 0
CD	99.60	1	99.60	1.25	0.281 7
A²	637.74	1	637.74	8.03	0.013 3
B²	14.15	1	14.15	0.18	0.679 4
C²	3 527.67	1	3 527.67	44.40	<0.000 1
D²	87.45	1	87.45	1.10	0.311 9
残差	1 112.27	14	79.45	—	—
失拟项	1 039.47	10	103.95	5.71	0.053 8
纯误差	72.80	4	18.20	—	—
总计	21 453.88	28	—	—	—

项目	Langmuir					Freundlich				Temkin
项目	q_max/（mg∙g^-1）	K_L/（L∙mg^-1）	R_L	R²_adj		K_F /（mg∙g^-1）∙（L∙mg^-1）^1/ⁿ	n	R²_adj		B/（J∙mol^-1）	A/（L·g^-1）	b/（J∙mol^-1）	R²_adj
数值	115.72	0.017 5	0.054~0.363	0.995		39.969 1	6.67	0.981		14.888 6	1.883 7	0.558	0.985

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