A Supramolecular Thickener Based on Non-Covalent Enhancement Mechanism

Yingxian Ma, Liqiang Huang, Zhi Zhu, Yuliang Du, J. Lai, Jianchun Guo
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Abstract

Inspired by non-covalent enhancement mechanism, we introduced glycinamide-conjugated monomer (NAGA) with dual-amide in one side group to amplify the hydrogen bonding interactions. Via one-step free radical polymerization strategy, we prepared a type of supramolecular thickener based on binary polymer. With NMR, FT-IR and SEM results’ help, we determined that PNAGA-AM system had unique bis-amide structure of glycinamide-conjugated monomer. As a result, the synthesized polymer could generate a much denser structure based on the high-ordered multiple hydrogen bonding with lower molecular weight (Mn = 778,400 g/mol), increasing the strength and stability of the chains. PNAGA-AM system had good thickening and temperature-resistant properties. The thickener viscosity of PNAGA-AM(3.0wt%) had twice as much as that of corresponding PAM system. And the viscosity of the 1.5 wt% solution prepared by PNAGA-AM could maintain 74 mPa·s at 150 °C. Meanwhile, the supramolecular system showed excellent salt resistance and self-healing performance with the non-covalent/hydrogen bonding interactions and physical entanglements. The viscosity of the PNAGA-AM system did not drop but increase in high salinity (≤ 300,000 mg/L salinity), and the maximum viscosity could increase nearly 44 % compared with the initial situation. In addition, the self-healing efficiency was over 100 % at 120 °C. Overall, the fracturing fluid system based on PNAGA-AM system could maintain outstanding rheological properties under extreme conditions and showed brilliant recovery performance, to make up the disadvantages of currently used fracturing fluid. It is expected to mitigate potential fluid issues caused by low water quality, harsh downhole temperatures and high-speed shearing.
一种基于非共价增强机理的超分子增稠剂
受非共价增强机制的启发,我们引入了单侧基双酰胺的甘氨酸酰胺共轭单体(NAGA)来增强氢键相互作用。采用一步自由基聚合策略,制备了一种基于二元聚合物的超分子增稠剂。通过NMR、FT-IR和SEM分析,我们确定了PNAGA-AM体系具有独特的甘氨酰胺共轭单体双酰胺结构。结果表明,合成的聚合物可以产生更致密的基于高序多氢键的结构,且分子量更低(Mn = 778,400 g/mol),提高了链的强度和稳定性。PNAGA-AM体系具有良好的增稠性和耐温性。PNAGA-AM增稠剂粘度为3.0wt%,是PAM增稠剂的2倍。在150℃下,PNAGA-AM制备的1.5 wt%溶液的粘度可保持在74 mPa·s。同时,该超分子体系表现出优异的耐盐性和自愈性,具有非共价/氢键相互作用和物理纠缠。在高盐度(≤300,000 mg/L)条件下,PNAGA-AM体系的粘度不但没有下降,反而有所增加,最大粘度比初始情况增加了近44%。在120℃下,自愈率可达100%以上。综上所述,基于PNAGA-AM体系的压裂液体系在极端条件下仍能保持优异的流变性能,并表现出优异的采收率,弥补了现有压裂液的不足。该技术有望缓解由低水质、恶劣的井下温度和高速剪切造成的潜在流体问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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