Page 34 - 《精细化工》2023年第12期
P. 34
·2576· 精细化工 FINE CHEMICALS 第 40 卷
[79] WU Z J, DAI J T, TANG L Y, et al. Sorbitol-based aqueous cyclic high toughness bio-based waterborne polyurethane enabled by a
carbonate dispersion for waterborne nonisocyanate polyurethane sorbitan monooleate[J]. Chemical Engineering Journal, 2022, 446:
coatings via an environment-friendly route[J]. Journal of Coatings 137124.
Technology and Research, 2018, 16(3): 721-732. [86] LIANG H Y, LU Q M, LIU M H, et al. UV absorption, anticorrosion,
[80] MHADESHWAR N, WAZARKAR K, SABNIS A S. Synthesis and and long-term antibacterial performance of vegetable oil based
characterization of ricinoleic acid derived monomer and its cationic waterborne polyurethanes enabled by amino acids[J].
application in aqueous emulsion and paints thereof[J]. Pigment & Chemical Engineering Journal, 2021, 421: 127774.
Resin Technology, 2019, 48(1): 65-72. [87] QU J Q (瞿金清), CHEN W (陈伟), TU W P (涂伟萍), et al.
[81] XIAO X Y (肖新颜), XIA Z B (夏正斌), ZHANG X D (张旭东), Development of leather finishes[J]. Fine Chemicals (精细化工),
et al. New development on environmentally friendly coatings[J]. 2000, 17(4): 232-236.
CIESC Journal (化工学报), 2003, 85(4): 531-537. [88] WANG J (汪金), LI X M (李晓敏), QU Y Q (区英强), et al. A study
[82] YANG J J (杨建军), CHEN H Y (陈虹雨), WU Q Y (吴庆云), et al. on preparation and synthesis process of carbon dioxide based
Latest research progress of modified waterborne polyurethane waterborne polyurethane[J]. Coating and Protection (涂层与防护),
anticorrosive coatings[J]. Fine Chemicals (精细化工), 2021, 38(10): 2022, 43(4): 40-48.
1981-1987, 1995. [89] HONARKAR H. Waterborne polyurethanes: A review[J]. Journal of
[83] SHEN R L, LONG M J, LEI C D, et al. Anticorrosive waterborne Dispersion Science and Technology, 2017, 39(4): 507-516.
polyurethane coatings derived from castor oil and renewable diols [90] SHELDON R A. The greening of solvents: Towards sustainable
[J]. Chemical Engineering Journal, 2022, 433: 134470. organic synthesis[J]. Current Opinion in Green and Sustainable
[84] ZHANG J B, LIU Y Z, WANG X W, et al. Self-polishing emulsion Chemistry, 2019, 18: 13-19.
platforms: Eco-friendly surface engineering of coatings toward water borne [91] GAO F, BAI R X, FERLIN F, et al. Replacement strategies for
marine antifouling[J]. Progress in Organic Coatings, 2020, 149: 105945. non-green dipolar aprotic solvents[J]. Green Chemistry, 2020,
[85] DENG H H, XIE F, SHI H B, et al. UV resistance, anticorrosion and 22(19): 6240-6257.
(上接第 2564 页) biochar[J]. Fine Chemicals (精细化工), 2021, 38(2): 395-403.
[56] MO G H (莫官海), XIE S B (谢水波), ZENG T T (曾涛涛), et al.
[46] GAO Y, HUANG J D, LI M, et al. Chemical modification of The efficiency and mechanism of U( Ⅵ ) removal from acidic
combusted coal gangue for U(Ⅵ) adsorption: Towards a waste wastewater by sewage sludge-derived biochar[J]. CIESC Journal (化
control by waste strategy[J]. Sustainability, 2021, 13(15): 8421. 工学报), 2020, 71(5): 2352-2362.
[47] WU W Y, CHEN Z, HUANG Y, et al. Red mud for the efficient [57] YU S F, WU X Y, YE J, et al. Dual effect of acetic acid efficiently
adsorption of U(Ⅵ) from aqueous solution: Influence of calcination enhances sludge-based biochar to recover uranium from aqueous
on performance and mechanism[J]. Journal of Hazardous Materials, solution[J]. Frontiers in Chemistry, 2022, 10: 48.
2021, 409: 124925. [58] SUN Y W, ZENG B Y, DAI Y T, et al. Modification of sludge-based
[48] WANG Y, CHEN B W, XIONG T, et al. Immobilization of U(Ⅵ) in biochar using air roasting-oxidation and its performance in adsorption
wastewater using coal fly ash aerogel (CFAA) as a low-cost adsorbent of uranium(Ⅵ) from aqueous solutions[J]. Journal of Colloid and
[J]. Process Safety and Environmental Protection, 2022, 160: 900-909. Interface Science, 2022, 614: 547-555.
[49] LI Q C, XIONG T, LIAO J, et al. Explorations on efficient extraction [59] LIU W J, ZHANG L Y, CHEN F M, et al. Efficiency and mechanism
of uranium with porous coal fly ash aerogels[J]. Science of the Total of adsorption of low-concentration uranium from water by a new
Environment, 2022, 839: 156365. chitosan/aluminum sludge composite aerogel[J]. Dalton Transactions,
[50] PANG H W, HUANG S Y, WU Y H, et al. Efficient elimination of 2020, 49(10): 3209-3221.
U(Ⅵ) by polyethyleneimine-decorated fly ash[J]. Inorganic Chemistry [60] LEI Z J (雷增江). Performance ang mechanism of U(Ⅵ) and Cr(Ⅵ)
Frontiers, 2018, 5(10): 2399-2407. in wastewater by aluminum sludge based gel spheres[D]. Hengyang:
[51] CHEN Z S, WANG J, PU Z X, et al. Synthesis of magnetic University of South China (南华大学), 2021.
Fe 3O 4/CFA composites for the efficient removal of U(Ⅵ) from [61] CHEN Z, SU M H, CHEN N, et al. Effectiveness and mechanism of
wastewater[J]. Chemical Engineering Journal, 2017, 320: 448-457. uranium adsorption on size-graded red mud[J]. Environmental
[52] LEI Z J (雷增江), YANG B (杨斌), YANG J H (杨金辉), et al. Research, 2022, 212: 113491.
Adsorption performance and mechanism of Cr(Ⅵ) by aluminum [62] LI N, WU J K, SU R D, et al. Bioinspired green tea waste/graphene
sludge composite gel spheres[J]. Fine Chemicals (精细化工), 2021, aerogel for solar-enhanced uranium extraction from seawater[J].
38(7): 1450-1458. Desalination, 2023, 545: 116153.
[53] XU D Y (徐大勇), ZHANG M (张苗), YANG W W (杨伟伟), et al. [63] HADJITTOFI L, PASHALIDIS I. Uranium sorption from aqueous
Preparation of alumina modified sludge biocharcoal particles and solutions by activated biochar fibres investigated by FTIR spectroscopy
their adsorption characteristics for Pb(Ⅱ)[J]. Chemical Industry and and batch experiments[J]. Journal of Radioanalytical and Nuclear
Engineering Progress (化工进展), 2020, 39(3): 1153-1166. Chemistry, 2015, 304(2): 897-904.
[54] SUN T (孙涛), ZHU X P (朱新萍), LI D P (李典鹏), et al. [64] ZHOU S K (周书葵), TIAN L Y (田林玉), RONG L S (荣丽杉), et al.
Comparison of biochars characteristics from different raw materials[J]. Remediation of uranium contaminated soil with three combinated
Journal of Agricultural Resources and Environment (农业资源与环 stabilizers[J]. Fine Chemicals (精细化工), 2020, 37(10): 2105-2111.
境学报), 2017, 34(6):543-549. [65] SANG W X (桑伟璇). Removal of U(Ⅵ) and Th(Ⅳ) in aqueous
[55] MO G H (莫官海), NONG H D (农海杜), HU Q (胡青), et al. U(Ⅵ) solution by nZVAl/Ni[D]. Nanchang: East China University of
removal efficiency and mechanism by acidified sewage sludge-derived Technology (东华理工大学), 2021.