低分子质量抗泥型PCE光催化合成及其在高岭土上的吸附研究

doi:10.19964/j.issn.1006-4990.2024-0588

摘要/Abstract

摘要：

明确高岭土对抗泥型聚羧酸系减水剂（PCE）的吸附作用，能有效指导催化合成抗泥型PCE过程中的分子结构设计。研究以Co/CeO₂为催化剂，（NH₄）₂S₂O₈为引发剂，烯丙基聚氧乙烯醚（APEG-1000）、2-丙烯酰胺基-2-甲基丙磺酸（AMPS）和乙烯基磺酸钠（VS）为单体，可见光催化合成系列低分子质量APEG抗泥型PCEs，其分子链段中含有胺基、磺酸基、聚氧乙烯链等功能性基团，数均分子质量为1 400左右，重均分子质量为3 800左右，具有较窄的分子质量分布。最佳制备条件为：APEG-1000、AMPS和VS的物质的量比为1∶0.1∶0.1，（NH₄）₂S₂O₈、Co/CeO₂用量分别为单体总质量的9%和0.2%，反应温度为60 ℃，反应时间为4 h，制备的PCE具有较好的分散性和抗泥性，水泥初始净浆流动度为272 mm，掺高岭土后流动度为260 mm且60 min内无损失。表征发现，该PCE与高岭土存在强相互作用。一方面有利于PCE的锚定吸附；另一方面使高岭土的主要衍射峰（001）面层间距增大0.002 9 nm、片层厚度减少4.64 nm。这种吸附作用对提高减水剂的抗泥性和保持性是有益的。

关键词: 可见光催化, 聚羧酸减水剂, 吸附, 高岭土

Abstract:

The adsorption mechanism of water reducer to clay is of great significance in effectively guiding the design of molecular structure of mud⁃inhibiting polycarboxylate superplasticizer（PCE）.Here，we prepared a series of low molecular weight anti⁃mud PCEs by visible light heterogeneous photocatalysis using Co/CeO₂ as catalyst，（NH₄）₂S₂O₈ as initiator，allyl polyoxyethylene ether（APEG-1000），2-acrylamido-2-methylpropanesulfonic acid（AMPS） and sodium vinyl sulfonate（VS） as monomers.The molecular chain contained functional groups such as carboxyl，amine，sulfonic acid，and polyethylene oxide chains，with a number⁃average molecular weight of approximately 1 400 and a weight⁃average molecular weight of approximately 3 800，and a relatively narrow molecular weight distribution.The most suitable synthesis process condition was obtained as follows.The ratio of APEG-1000、AMPS and VS was 1∶0.1∶0.1.The amount of（NH₄）₂S₂O₈ and Co/CeO₂ was 9% and 0.2%，respectively.The reaction temperature was 60 ℃.The reaction time was 4 h.The initial flow of the cement paste was 272 mm，while the flow was 260 mm after adding kaolin without loss in 60 minutes，demonstrating superior dispersion and antimud properties.The systematic characterizations revealed that the excellent antimud performance could be attributed to several factors.On the one hand，the strong interactions were conducived to anchoring adsorption of the PCE by cement and kaolin particles.On the other hand，the main diffraction peak（001） of kaolin was increased by 0.002 9 nm and the layer thickness was reduced by 4.64 nm when PCE was inserted into the interlayers of kaolin.Overall，this adsorption was beneficial to improve the mud resistance and retention of polycarboxylate superplasticizers.

Key words: photocatalytic, polycarboxylate superplasticizers, adsorption, kaolin

中图分类号:

TU528.042.2

吴凤龙, 宋瑾. 低分子质量抗泥型PCE光催化合成及其在高岭土上的吸附研究[J]. 无机盐工业, 2026, 58(1): 52-60.

WU Fenglong, SONG Jin. Study on photocatalytic synthesis of low molecular weight anti⁃mud polycarboxylate superplasticizers and its adsorption effect for kaolin[J]. Inorganic Chemicals Industry, 2026, 58(1): 52-60.

图/表 15

图1

图2

图3

图4

图5

表1

图6

图7

图8

图9

图10

表2

高岭土的层间距和片层厚度

样品	间距/nm					厚度/nm
样品	001	$1 - 1 - 1$	002	111	$2 - 02$	001
高岭土	0.715 9	0.433 5	0.356 4	0.333 1	0.236 6	27.84
PCE-1-K	0.718 1	0.435 4	0.356 7	0.333 7	0.237 1	24.56
PCE-2-K	0.718 8	0.435 8	0.357 1	0.334 1	0.237 5	23.20
PCE-3-K	0.719 9	0.435 9	0.357 3	0.334 3	0.237 7	21.97
PCE-4-K	0.721 1	0.436 2	0.357 6	0.334 5	0.237 9	20.87
PCE-5-K	0.718 9	0.435 7	0.356 6	0.333 8	0.237 3	24.35

表2

图11

图12

图13

参考文献 25

[1]	QI Shuai， WANG Tao， HAN Zheng，et al.Synthesis and performance of a series of novel low⁃molecular⁃weight superplasticisers with star⁃shaped phosphate frame［J］.Advances in Cement Research，2020，32（11）：492-501.
[2]	LIU Bobo， KE Kuliang， YANG Yinggang，et al.Preparation and application of low molecular weight polyether polycarboxylate superplasticizer［J］.Journal of Physics：Conference Series，2022，2194（1）：012035.
[3]	ZHONG Lina.Study on preparation and properties of polycarboxylate superplasticizer with different molecular weight methylallyl polyoxyethylene ether［J］.Journal of Physics：Conference Series，2023，2539（1）：012056.
[4]	LI Hongling， WANG Yaqian， YANG Xinyu，et al.Synthesis and characterization on anti⁃clay polycarboxylate superplasticizer in concrete［J］.Case Studies in Construction Materials，2024，20：e03076.
[5]	ZHANG Hengtong， LIU Cailin， REN Xianyan，et al.Synthesis of polycarboxylic ether superplasticizers based on the high conversion of EPEG in a transition metal oxide heterogeneous catalytic system［J］.Colloids and Surfaces A：Physicochemical and Engineering Aspects，2022，643：128780.
[6]	CHEN Huanhuan， LUO Shaohua， LEI Xuefei，et al.Performance and mechanism of constructed CuO/CeO₂ p-n heterojunction for photocatalytic degradation of methylene blue［J］.Transactions of Nonferrous Metals Society of China，2024，34（6）：1951-1964.
[7]	XU Xiutao， SHAO Chunfeng， ZHANG Jinfeng，et al.Rational design of S-scheme CeO₂/Bi₂MoO₆ microsphere heterojunction for efficient photocatalytic CO₂ reduction［J］.Acta Physico⁃Chimica Sinica，2024，40（10）：2309031.
[8]	CHEN Jie， XIAO Yuting， WANG Nan，et al.Facile synthesis of a Z-scheme CeO₂/C₃N₄ heterojunction with enhanced charge transfer for CO₂ photoreduction［J］.Science China Materials，2023，66（8）：3165-3175.
[9]	HUANG Xiubing， ZHANG Kaiyue， PENG Baoxiang，et al.Ceria⁃based materials for thermocatalytic and photocatalytic organic synthesis［J］.ACS Catalysis，2021，11（15）：9618-9678.
[10]	吴慧，郑君宁，李蓉，等.NiPt/CeO₂催化剂的制备及其催化水合肼分解制氢性能研究［J］.中国稀土学报，2024，42（6）：1102-1110.
	WU Hui， ZHENG Junning， LI Rong，et al.Synthesis of NiPt/CeO₂ catalyst and its catalytic performance for hydrogen production via hydrazine hydrate decomposition［J］.Journal of the Chinese Society of Rare Earths，2024，42（6）：1102-1110.
[11]	REN Puning， GAO Zhuyan， MONTINI T，et al.Stepwise photoassisted decomposition of carbohydrates to H₂ ［J］.Joule，2023，7（2）：333-349.
[12]	SONG Jin， WU Fenglong.Ceria⁃based quantum dots/nanorods supported metallic cobalt for efficient photocatalytic hydrogen production［J］.International Journal of Hydrogen Energy，2023，48（54）：20705-20716.
[13]	吴凤龙，宋瑾.CeO₂可见光催化合成APEG保坍抗泥型聚羧酸减水剂［J］.化学研究与应用，2024，36（3）：581-592.
	WU Fenglong， SONG Jin.Synthesis of APEG slump retention type polycarboxylate superplasticizer over CeO₂ under visible light［J］.Chemical Research and Application，2024，36（3）：581-592.
[14]	GUO Guangming， WU Si， LIU Guoshan，et al.Synthesis and performance of HPEG-AA-AMPS-HPA polycarboxylate superplasticizer［J］.Journal of Physics：Conference Series，2024，2737（1）：012007.
[15]	CHEN Jing， YANG Changhui， HE Yan，et al.Effects and mechanism of hyperbranched phosphate polycarboxylate superplasticizers on reducing viscosity of cement paste［J］.Materials，2024，17（8）：1896.
[16]	XIONG Qiumin， CHEN Xiaobin， QIU Nianli，et al.Preparation and performance study of anti mud polycarboxylic acid slump retaining agent［J］.Journal of Physics：Conference Series，2024，2713（1）：012008.
[17]	ZHANG Ming， GUO Chunfang， ZHANG Qian，et al.Preparation and clay tolerance research of a polycarboxylate superplasticizer modified by phosphonate group［J］.Journal of Polymer Research，2024，31（8）：239.
[18]	解利荣，张光华，董勋，等.不同磷酸酯单体的EPEG型聚羧酸减水剂的制备及抗泥性能［J］.精细化工，2022，39（11）：2371-2376.
	XIE Lirong， ZHANG Guanghua， DONG Xun，et al.Preparation and anti⁃mud function of EPEG polycarboxylate superplasticizers with different phosphate monomers［J］.Fine Chemicals，2022，39（11）：2371-2376.
[19]	MA Baoguo， LI Chunbao， LV Yang，et al.Preparation for polyacrylic acid modified by ester group in side chain and its application as viscosity enhancing agent in polycarboxylate superplasticizer system［J］.Construction and Building Materials，2020，233：117272.
[20]	XIONG Qiumin， CHEN Xiaobin， DANG Wei，et al.Research on synthesis and property of anti⁃clay polycarboxylate superplasticizer［J］.IOP Conference Series：Earth and Environmental Science，2020，531（1）：012036.
[21]	HE Zhihao， HUANG Teng， GAO Meiben，et al.Effect of the side⁃chain length in polycarboxylic superplasticizer on the competition adsorption in the presence of montmorillonite：A density functional theory study［J］.Molecules，2024，29（4）：752.
[22]	DALAS F， NONAT A， POURCHET S，et al.Tailoring the anionic function and the side chains of comb⁃like superplasticizers to improve their adsorption［J］.Cement and Concrete Research，2015，67：21-30.
[23]	龚双梅，李晓波，张荣荣，等.Ce（Ⅵ）与6种天然黄酮化合物的氧化还原体系及其应用［J］.应用化学，2011，28（11）：1286-1291.
	GONG Shuangmei， LI Xiaobo， ZHANG Rongrong，et al.Redox system of cerium（Ⅵ）-flavonoids and applications［J］.Chinese Journal of Applied Chemistry，2011，28（11）：1286-1291.
[24]	SONG Jin， WU Fenglong， LU Yulun，et al.CeVO₄/CeO₂ heterostructure⁃supported co nanoparticles for photocatalytic H₂ production from ammonia borane under visible light［J］.ACS Applied Nano Materials，2021，4（5）：4800-4809.
[25]	MEHDI S， LIU Yanyan， WEI Huijuan，et al.P⁃induced co⁃based interfacial catalysis on Ni foam for hydrogen generation from ammonia borane［J］.Applied Catalysis B：Environmental，2023，325：122317.

编号	M_p	M_n	M_w	M_z	M_z+1	PD
PCE-0	1 676	1 257	3 106	9 883	19 813	2.47
PCE-1	2 100	1 370	3 531	11 373	24 278	2.58
PCE-2	2 100	1 419	3 826	13 004	27 368	2.70
PCE-3	2 173	1 424	3 857	12 477	25 848	2.71
PCE-4	2 058	1 430	3 885	12 835	26 190	2.72
PCE-5	1 837	1 267	3 765	15 263	33 991	2.97

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