材料科学
弹性体
聚氨酯
化学工程
聚合物
溶解
绝热过程
工作(物理)
热塑性弹性体
溶剂
微观结构
热的
热塑性聚氨酯
溶解度
溶解度参数
共聚物
分离(统计)
复合材料
纳米技术
电子设备和系统的热管理
水溶液
分离过程
科技与社会
工艺工程
组分(热力学)
形状记忆合金
作者
Borui Li,Yuheng Fu,Lijia Wang,Yibo Zhang,Quanling Yang,Hongmei Qin,Chuanxi Xiong,Shixian Zhang
标识
DOI:10.1021/acsapm.6c00774
摘要
The elastocaloric effect (eCE) enables solid-state cooling through reversible, stress-induced thermal changes, yet its practical implementation remains limited by insufficient control over microphase separation in elastomeric materials. Here, we report a solubility-parameter-guided solvent-processing strategy that enables precise, scalable regulation of microphase separation in segmented polyurethane (PU) elastomers without chemical modification. A mixed N,N-dimethylacetamide/1,4-dioxane (DMAc/DIOX) solvent system with a continuously tunable solubility parameter (δ = 18.02–21.40) was employed to enable selective dissolution of hard and soft segments during solution casting, inducing a controlled dissolution–precipitation process. When δ approaches the hard-segment value, PU exhibits the most distinct microphase separation, characterized by a high hydrogen-bond index (75.3%), a reduced soft-segment glass-transition temperature (224 K), and well-defined hard domains, enabling efficient strain-induced ordering. This optimized microstructure yields a large adiabatic temperature change of 19.1 K under low-stress stretch–recovery conditions. These results demonstrate that solubility-parameter-driven solvent design offers an effective, scalable, and general route to optimize microphase separation. This work provides a promising pathway for sustainable thermal management technologies in segmented polymer systems.
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