Ultra-large Specific Surface Area Activated Carbon Synthesized from Rice Husk with High Adsorption Capacity for Methylene Blue

doi:10.15541/jim20200632

Abstract

Abstract:

Activated carbon with high surface area and abundant pore structure is widely used for contaminant adsorption in wastewater treatment. Rice husks (RHs) with unique composition and microstructure are often used as carbon source to prepare activated carbon. Herein, ultra-large specific surface area activated carbon was synthesized from rice husks with pre-activation and activation by supersaturated KOH solution at different temperatures. With the increase of activation temperature, the specific surface area and total pore volume of activated carbon gradually increase. The activated carbon obtained at 900 ℃ shows the largest specific surface area of 3600 m²/g and the maximal total pore volume of 3.164 cm³/g, which are significantly superior to those of the commercial activated carbon (YP-80, the specific surface area of 1310 m²/g and the total pore volume of 0.816 cm³/g, respectively). The highest maximum adsorption capacity for methylene blue was found for the activated carbon with the largest specific surface area, namely, 983 mg/g, which is almost twice as high as that of YP-80 (525 mg/g). By adsorption kinetics fitting, the results are consistent with pseudo-second-order model which indicates that the process of adsorbing methylene blue is chemical adsorption.

Key words: rice husk, ultra-large specific surface area, activated carbon, adsorption, methylene blue

CLC Number:

TQ424

ZHOU Fan, BI Hui, HUANG Fuqiang. Ultra-large Specific Surface Area Activated Carbon Synthesized from Rice Husk with High Adsorption Capacity for Methylene Blue[J]. Journal of Inorganic Materials, 2021, 36(8): 893-903.

Figures/Tables 15

References 29

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Carbon	YP-80	RHAC600	RHAC700	RHAC800	RHAC900
I_D: I_G	0.997	0.992	1.017	1.025	1.020
SSA_BET/(m²•g^-1)	1310	2380	3173	3366	3600
Pore volume_total/(cm³•g^-1)	0.816	1.352	1.733	1.829	3.164
Micropore volume/(cm³•g^-1)	0.516	0.393	0.429	0.606	0.537
Adsorption limit/(mg•g^-1)	525	851	935	919	983

Carbon	YP-80	RHAC600	RHAC700	RHAC800	RHAC900
I_D: I_G	0.997	0.992	1.017	1.025	1.020
SSA_BET/(m²•g^-1)	1310	2380	3173	3366	3600
Pore volume_total/(cm³•g^-1)	0.816	1.352	1.733	1.829	3.164
Micropore volume/(cm³•g^-1)	0.516	0.393	0.429	0.606	0.537
Adsorption limit/(mg•g^-1)	525	851	935	919	983

Biomass	Activator	Pore volume/(cm³•g^-1)	SSA_BET/(m²•g^-1)	q_m/(mg•g^-1)
Tobacco stalks^[1]	ZnCl₂+Microwave	0.45	684.68	123.45
Dipterocarpus alatus^[2]	ZnCl₂/500 ℃	0.473	843	269.3
Sugar beet pulp^[3]	H₃PO₄/450 ℃	0.445	1029.3	250.0
Palm kernel shell^[4]	ZnCl₂/550 ℃	0.571	1058	225.3
Rice by-products^[5]	H₃PO₄/450 ℃	0.612/0.607	814/1000	246.9/213.7
Viscose fibers^[6]	Steam/900 ℃	0.54/0.76	1284/1614	256.1/325.8
Cotton^[7]	H₃PO₄+Microwave	0.98	1370	476.2
Cashew nut shell^[8]	ZnCl₂/400 ℃	0.973	1478	476
Arundo donax^[9]	ZnCl₂/400 ℃	1.113	1784	416.7
Sawdust^[10]	KOH/1000 ℃	1.27	2254	303.03
Bamboo shoots^[11]	KHCO₃/700 ℃/800 ℃	0.73/1.25	1476/2271	458
Bagasse/Cluster stalks^[12]	KOH/1300 ℃	0.82/1.4	1861/2662	714.3/925.9
This work	KOH/800 ℃/900 ℃	1.829/3.164	3366/3600	919/983

Biomass	Activator	Pore volume/(cm³•g^-1)	SSA_BET/(m²•g^-1)	q_m/(mg•g^-1)
Tobacco stalks^[1]	ZnCl₂+Microwave	0.45	684.68	123.45
Dipterocarpus alatus^[2]	ZnCl₂/500 ℃	0.473	843	269.3
Sugar beet pulp^[3]	H₃PO₄/450 ℃	0.445	1029.3	250.0
Palm kernel shell^[4]	ZnCl₂/550 ℃	0.571	1058	225.3
Rice by-products^[5]	H₃PO₄/450 ℃	0.612/0.607	814/1000	246.9/213.7
Viscose fibers^[6]	Steam/900 ℃	0.54/0.76	1284/1614	256.1/325.8
Cotton^[7]	H₃PO₄+Microwave	0.98	1370	476.2
Cashew nut shell^[8]	ZnCl₂/400 ℃	0.973	1478	476
Arundo donax^[9]	ZnCl₂/400 ℃	1.113	1784	416.7
Sawdust^[10]	KOH/1000 ℃	1.27	2254	303.03
Bamboo shoots^[11]	KHCO₃/700 ℃/800 ℃	0.73/1.25	1476/2271	458
Bagasse/Cluster stalks^[12]	KOH/1300 ℃	0.82/1.4	1861/2662	714.3/925.9
This work	KOH/800 ℃/900 ℃	1.829/3.164	3366/3600	919/983

Sample	q_e(exp)/(mg•g^-1)	q₁(cal)/(mg•g^-1)		k₁/min^-1
YP-80	525	19.8	96.23	0.0192
RHAC600	851	438.8	48.44	0.0614
RHAC700	935	85.9	90.81	0.0231
RHAC800	919	259	71.82	0.0433
RHAC900	983	89	90.95	0.0347