Improved dielectric and actuated performance of thermoplastic polyurethane by blending with XNBR as macromolecular dielectrics.

In the present study, carboxylated nitrile rubber (XNBR) with high dielectric constant (ε r) and low elastic modulus (Y) was introduced into thermoplastic polyurethane (TPU) with good mechanical properties to prepare macroscopic homogeneous high performance dielectric elastomer (DE) blends. The results show that the XNBR macromolecules can disrupt the N-H/C=O hydrogen bonds of TPU, leading to the increase in dipole polarizability of TPU matrix. On the other hand, the formation of hydrogen bonds between XNBR and TPU increases the interfacial interaction and thus the interfacial polarizability of XNBR/TPU blends. The improvement of both the dipole polarizability and the interfacial polarizability result in the significant improvement of ε r of TPU with increasing the content of XNBR. Meanwhile, the Y of TPU is decreased due to the disruption of hydrogen bonds of TPU and the softening effect of XNBR. The simultaneous increase in ε r and decrease in Y of TPU results in the large increase in electromechanical sensitivity (β) and actuated strain at low electric field of XNBR/TPU blends. Interestingly, the ε r at 103 Hz, the β and the actuated strain at certain electrical field of the blend with XNBR/TPU blending ratio of 80/20 is even higher than that of pure XNBR, which is attributed to the co-continuous structure of this blend as well as the synergetic effect of the increase in dipole polarizability of both TPU and XNBR and the increase in interfacial polarizability. Comparing with our previous study on TPU DE blend by adding low molecular weight plasticizer, XNBR/TPU macromolecular DE blend show better overall performance such as higher mechanical strength, higher breakdown strength and better stability, thus are more likely to be applied in biological and medical fields, where a low electric field is required. Image 1 • Macroscopic homogeneous high performance XNBR/TPU DE blends were prepared. • XNBR disrupts the hydrogen bonds of TPU, increasing the dipole polarizability of TPU. • The formation of XNBR/TPU Hydrogen bonds increases the interfacial polarizability. • The elastic modulus of TPU is decreased by blending with XNBR. • The ε r and actuated strain of XNBR/TPU 80/20 blend is higher than that of pure XNBR. [ABSTRACT FROM AUTHOR]