Abstract
High-entropy strategy presents a promising approach for enhancing the piezoelectric properties of bismuth layer-structured ferroelectrics, yet the vast compositional space poses significant challenges for traditional trial-and-error methods. In this work, a machine learning (ML)-assisted design strategy is proposed to accelerate the discovery of high-performance, high-entropy CaBi(4)Ti(4)O(15) ceramics. Based on a small data set containing 114 compositions, seven key elements closely related to the piezoelectric coefficient (d(33)) were identified through feature engineering. Using the eXtreme Gradient Boosting regression model, the d(33) values of 22500 candidate compositions were predicted, thereby guiding the synthesis of Ca(1-x)(Na(1/6)Bi(1/6)Li(1/6)Ce(1/6)K(1/6)Bi(1/6))(x)Bi(4)Ti(3.9)(Nb(1/2)Mn(1/2))(0.1)O(15) ceramics. The optimal composition (x = 0.3) achieved a record-high d(33) of 28.1 pC/N, along with outstanding temperature stability (93% retention after 500 °C annealing). Structural characterization indicates that the high-entropy-induced chemical disorder promotes the formation and switching of nanodomains. On the other hand, the significant lattice distortion it induces enhances the spontaneous polarization, with both aspects synergistically improving the piezoelectric performance. This work demonstrates the effectiveness of ML in navigating complex composition-performance relationships in high-entropy piezoceramics and provides a viable route for designing piezoelectric materials with superior integrated performance for high-temperature applications.