Page 86 - 《精细化工》2022年第9期

P. 86

·1804· 精细化工 FINE CHEMICALS 第 39 卷

0.0125 mol/L 的 NaOH 溶液中，于 75 ℃下，以 400 r/min 1700091.
[13] BHATTACHARYYA R, RAY S K. Adsorption of industrial dyes by
的搅拌速率水解反应 2.0 h 得到 H-SL-g-P(AA-AM)/ semi-IPN hydrogels of acrylic copolymers and sodium alginate[J].
Journal of Industrial & Engineering Chemistry, 2015, 22: 92-102.
PVP，水解后树脂的吸水倍率可达 2011.12 g/g，相 [14] LIPATOV Y S. Polymer blends and interpenetrating polymer
较于未水解树脂的吸水倍率（1194.29 g/g）提升了 networks at the interface with solids[J]. Progress in Polymer Science,
2002, 27(9): 1721-1801.
68.39%。并利用 FTIR、LNMR、XRD、TG 以及 SEM [15] TARDAJOS M G, NASH M, ROCHEV Y, et al. Homologous
copolymerization route to functional and biocompatible
证明了水解前后样品的结构、热稳定性和表面形貌 polyvinylpyrrolidone[J]. Macromolecular Chemistry and Physics,
的差异。 2012, 213(5): 529-538.
[16] GUO Y, HAO Z X, WAN C. Tribological characteristics of
（2）水解前后树脂的溶胀行为均符合一阶与二 polyvinylpyrrolidone (PVP) as a lubrication additive for artificial
knee joint[J]. Tribology International, 2016, 93: 214-219.
阶溶胀动力学模型；H-SL-g-P(AA-AM)/PVP 在质量 [17] GHOBASHY M M, El-DAMHOUGY B K, NADY N, et al.
分数为 0.1%~1.1%的 NaCl 溶液中以及质量分数为 Radiation crosslinking of modifying super absorbent (polyacrylamide/
gelatin) hydrogel as fertilizers carrier and soil conditioner[J]. Journal
0.1%~0.3% 的 MgCl 2 溶液中的吸水倍率均高于 of Polymers and the Environment, 2018, 26: 3981-3994.
[18] ZHANG F, XU G M, ZHU L J, et al. Effects of hydrolysis treatment
SL-g-P(AA-AM)/PVP，在质量分数为 0.5%~1.1%的 on the structure and properties of semi-interpenetrating superabsorbent
MgCl 2 溶液和质量分数为 0.1%~1.1%的 FeCl 3 溶液中 polymers[J]. Journal of Applied Polymer Science, 2021, 138(44):
e51307.
的吸水倍率低于 SL-g-P(AA-AM)/PVP。 [19] ZHAO J J, ZHENG K, NAN J Y, et al. Synthesis and characterization
of lignosulfonate-graft-poly (acrylic acid)/ hydroxyethyl cellulose
（3）H-SL-g-P(AA-AM)/PVP 在 30、45 和 60 ℃ semi-interpenetrating hydrogels[J]. Reactive and Functional Polymers,
下和在土壤中的保水性能均优于 SL-g-P(AA-AM)/ 2017, 115: 28-35.
[20] ZHANG S J (张世杰), LIU S M (刘述梅), ZHAO J Q (赵建青), et
PVP，且具有一定的重复使用性能，5 次循环使用后 al. Study on catalytical hydrolysis reaction of polyvinylpyrrolidone
[C]//Abstract Collection of 2005 National Polymer Academic Papers
的吸水倍率仍可达 759.59 g/g，使其在农林业方面具 Conference (2005 年全国高分子学术论文报告会论文摘要集),
2005: 134.
备良好的潜在应用价值。 [21] OLAD A, POURKHIYABI M, GHAREKHANI H, et al. Semi-IPN
superabsorbent nanocomposite based on sodium alginate and
参考文献： montmorillonite: Reaction parameters and swelling characteristics[J].
Carbohydrate Polymers, 2018, 190: 295-306.
[1] GUILHERME M R, AOUADA F A, FAJARDO A R, et al. [22] WANG C H (王春海), AI Q (艾青), ZHAO Y F (赵银凤), et al.
Superabsorbent hydrogels based on polysaccharides for application Adsorption of copper ions by sodium lignosulfonate-chitosan
in agriculture as soil conditioner and nutrient carrier: A review[J]. polyelectrolyte complex[J]. Chemistry and Industry of Forest
European Polymer Journal, 2015, 72: 365-385. Products (林产化学与工业), 2012, 32(1): 29-34.
[2] RASHIDZADEH A, OLAD A. Slow-released NPK fertilizer [23] WEN P, WU Z S, HE Y H, et al. Microwave-assisted synthesis of a
encapsulated by NaAlg-g-poly(AA-co-AAm)/MMT superabsorbent semi-IPN slow-release nitrogen fertilizer with water absorbency from
nanocomposite[J]. Carbohydrate Polymers, 2014, 114: 269-278. cotton stalks[J]. ACS Sustainable Chemistry & Engineering, 2016,
[3] RODRIGUES F H A, FAJARDO A R, PEREIRA A G B, et al. 4(12): 6572-6579.
Chitosan-graft-poly(acrylic acid)/rice husk ash based superabsorbent [24] MAHDAVINIA G R, POURJAVADI A, HOSSEINZADEH H, et al.
hydrogel composite: Preparation and characterization[J]. Journal of Modified chitosan 4. Superabsorbent hydrogels from poly (acrylic
Polymer Research, 2012, 19(12): 1-10. acid-co-acrylamide) grafted chitosan with salt- and pH-responsiveness
[4] KOSEMUND K, SCHLATTER H, OCHSENHIRT J L, et al. Safety properties[J]. European Polymer Journal, 2004, 40(7): 1399-1407.
evaluation of superabsorbent baby diapers[J]. Regulatory Toxicology [25] CHEN J, LI F Z, LUO Y L, et al. A self-healing elastomer based on
and Pharmacology, 2009, 53(2): 81-89. an intrinsic non-covalent cross-linking mechanism[J]. Journal of
[5] XU G M (徐桂明), ZHU L J (朱丽珺), ZHANG J C (张金池), et al. Materials Chemistry A, 2019, 7: 15207-15214.
Synthesis and properties of PVA/P(AA-AM)/urea semi-interpenetrating [26] POURJAVADI A, HOSSEINZADEH H. Synthesis and properties of
superabsorbent resin[J]. Fine Chemicals (精细化工), 2019, 36(11): partially hydrolyzed acrylonitrile-co-acrylamide superabsorbent
2185-2206. hydrogel[J]. Bulletin of the Korean Chemical Society, 2010, 31(11):
2+
[6] KONG W J, YUE Q Y, LI Q, et al. Adsorption of Cd on GO/PAA 3163-3172.
hydrogel and preliminary recycle to GO/PAA-CdS as efficient [27] LIU X W, LUAN S, LI W. Utilization of waste hemicelluloses lye for
photocatalyst[J]. Science of the Total Environment, 2019, 668: superabsorbent hydrogel synthesis[J]. International Journal of
1165-1174. Biological Macromolecules, 2019, 132: 954-962.
[7] KIM B S, CHEN Y T, SRINOI P, et al. Hydrogel-encapsulated [28] LIM D W, WHANG H S, YOON K J, et al. Synthesis and
mesoporous silica-coated gold nanoshells for smart drug delivery[J]. absorbency of a superabsorbent from sodium starch sulfate-g-
International Journal of Molecular Sciences, 2019, 20(14): 3422. polyacrylonitrile[J]. Journal of Applied Polymer Science, 2001,
[8] ZHOU D B (周道兵), CHU F X (储富祥). Progress of studies on 79(8): 1423-1430.
graft modification and application of lignosulfonate[J]. Chemistry [29] LI A, LIU R F, WANG A Q. Preparation of starch-graft-poly
and Industry of Forest Products (林产化学与工业), 2005, 25(10): (acrylamide)/attapulgite superabsorbent composite[J]. Journal of
171-174. Applied Polymer Science, 2005, 98(3): 1351-1357.
[9] XIANG Y J (向育君), XU W J (徐伟箭), XIA X N (夏新年), et al. [30] MARANDI G B, SHARIFNIA N, HOSSEINZADEH H. Synthesis
Lately progress of lignosulfonate research and main application[J]. of an alginate-poly(sodium acrylate-co-acrylamide) superabsorbent
Polymer Bulletin (高分子通报), 2010,(9): 99-104. hydrogel with low salt sensitivity and high pH sensitivity[J]. Journal
[10] HONG S M (洪思明), YE D (叶冬), MU X K (穆新科), et al. of Applied Polymer Science, 2006, 101(5): 2927-2937.
Synthesis and characterization of LS-g-PAMPS/ST salt-tolerant [31] POURJAVADI A, ZOHURIAAN-MEHR M J, GHASEMPOORI S
superabsorbent resin[J]. Synthetic Materials Aging and Application N, et al. Modified CMC. Ⅴ. Synthesis and super-swelling behavior
(合成材料老化与应用), 2015, 44(2): 56-60. of hydrolyzed CMC-g-PAN hydrogel[J]. Journal of Applied Polymer
[11] LYU G L (吕高磊), HAN F Q (韩福芹), ZHANG C T (张春涛), et Science, 2007, 103(2): 877-883.
al. Preparation of sodium lignosulfonate-g-AA-AM super-absorbents [32] GHAREKHANI H, OLAD A, MIRMOHSENI A, et al.
composites[J]. Applied Chemical Industry (应用化工), 2018, 47(4): Superabsorbent hydrogel made of NaAlg-g-poly(AA-co-AAm) and
762-766. rice husk ash: Synthesis, characterization, and swelling kinetic
[12] HUO Q, LIU D, ZHAO J J, et al. Construction and water absorption studies[J]. Carbohydrate Polymers, 2017, 168: 1-13.
capacity of a 3D network-structure starch-g-poly(sodium acrylate)/PVP [33] SCHOTT H. Swelling kinetics of polymers[J]. Journal of
semi-IPN superabsorbent resin[J]. Starch-Starke, 2017, 69(11/12): Macromolecular Science, Part B: Physics, 1992, 31(1): 1-9.

81 82 83 84 85 86 87 88 89 90 91