Inorganic Chemicals Industry ›› 2023, Vol. 55 ›› Issue (12): 59-65.doi: 10.19964/j.issn.1006-4990.2022-0703
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Preparation of amino alcohol modified GO/CNTs composite aerogel and boron adsorption from salt lake brines
CUI Xiangmei1(
), PAN Tongtong1, LUO Qinglong2,3,4, BIAN Fuxuan1, YE Xiushen2,3,4()
- 1. Qinghai University,Xining 810016,China
2. Key Laboratory of Comprehensive and Highly Efficient Utilization of Salt Lake Resources,Xining 810008,China
3. Qinghai Institute of Salt Lakes,Chinese Academy of Sciences,Xining 810008,China
4. Key Laboratory of Salt Lake Resources Chemistry of Qinghai Province,Xining 810008,China
-
Received:2022-11-30Online:2023-12-10Published:2023-12-14 -
Contact:YE Xiushen E-mail:cuixiangmei@qhu.edu.cn;yexs@isl.ac.cn
CLC Number:
Cite this article
CUI Xiangmei, PAN Tongtong, LUO Qinglong, BIAN Fuxuan, YE Xiushen. Preparation of amino alcohol modified GO/CNTs composite aerogel and boron adsorption from salt lake brines[J]. Inorganic Chemicals Industry, 2023, 55(12): 59-65.
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Fig.1
FT-IR spectra of graphene oxide/carbon nanotubeaerogels before and after modification"
Fig.1
Fig.2
SEM images of graphene oxide/carbon nanotubeaerogel before(a) and after modification(b)"
Fig.2
Fig.3
N2 adsorption-desorption isotherm and BJHpore size distribution curve of amino alcoholmodified boron adsorbent"
Fig.3
Table 1
BET specific surface area,pore volume andaverage pore size of adsorbent"
| 样品 | BET比表面积/ (m2∙g-1) | 孔体积/ (m3∙g-1) | 平均 孔径/nm |
|---|---|---|---|
| 硼吸附剂 | 1.434 4 | 0.007 76 | 23.363 9 |
Table 1
Fig.4
XPS full spectrum(a) and boron XPS spectra(b)of GO/CNTs adsorbent after adsorption"
Fig.4
Fig.5
Main forms of boron-oxygen anions in solution[15-16]"
Fig.5
Fig.6
Speciation distribution of boronin aqueous solution[17]"
Fig.6
Fig.7
Boron adsorption characteristics of adsorbentsin different pH solutions"
Fig.7
Fig.8
Complexation mode between borate anion species and polyols adsorption[22-24]"
Fig.8
Fig.9
Effect of initial boron mass concentration(a) and temperature(b) on boron adsorption"
Fig.9
Table 2
Comparison of adsorbents with thosereported in literatures"
| 吸附剂 | 功能基团 | Q/ (mg∙g-1) | Te/ min | 溶剂 |
|---|---|---|---|---|
| Amberlit IRA743[ | 葡甲胺 | 7.46 | 60 | — |
| CTS-MG[ | 葡甲胺 | 35.13 | 720 | DMF、THF |
| PAN-g-PG[ | 缩水甘油 | 34.59 | 10 | H2O、乙醇 |
| CA-KH-550-EPH[ | 葡甲胺 | 15.35 | 600 | DMF |
| PAN-PGMA[ | 葡甲胺 | 5.5 | 100 | DMF、THF |
| Si-MG[ | 葡甲胺 | 16.65 | 120 | DMF、甲苯 |
| GMA-MMA-DVB-MG[ | 葡甲胺 | 9.03 | 60 | 甲苯 |
| GMA-MMA-DVB-PG [ | 缩水甘油 | 32.43 | 80 | N-甲基吡咯烷酮 |
| CTS-MG[ | 葡甲胺 | 20.4 | 400 | 异丙醇 |
| P(GMA-co-TRIM)-MG[ | 葡甲胺 | 19.89 | 60 | DMF、甲苯 |
| GO/CNTs-OH(本工作) | —OH | 43.42 | 60 | H2O |
Table 2
Fig.10
Effect of contact time on boron adsorption"
Fig.10
Table 3
Kinetic parameters of boron adsorption"
| 吸附剂 | T/℃ | 准一阶动力学拟合参数 | 准二阶动力学拟合参数 | |||||
|---|---|---|---|---|---|---|---|---|
| Qe,cal/(mg∙g-1) | k1 | R2 | Qe,cal/(mg∙g-1) | k2 | R2 | |||
GO/ CNTs-OH | 25 | 27.42 | 0.050 06 | 0.973 | 30.86 | 0.070 63 | 0.997 | |
Table 3
Table 4
Composition of West Taijinar salt lake brine mg/L"
ρ (K+) | ρ (Na+) | ρ (Ca2+) | ρ (Mg2+) | ρ (Li+) | ρ (B3+) | ρ (Cl-) | ρ (SO42-) | ρ (CO32-) |
|---|---|---|---|---|---|---|---|---|
| 1 846 | 26 901 | 5.77 | 1.59 | 10 200 | 173.70 | 773.77 | 10 030 | 16 776 |
Table 4
Fig.11
Boron adsorption performance of adsorbent underinterference of inorganic salt in solution(a) andits recycling performance in actual brine(b)"
Fig.11
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