1. We have shown that amino acid polycrystalline assemblies can be grown using an evaporative method onto custom silicone molds so that the resultant bulk assembly can act as a stand-alone component. Compared to ceramic device fabrication, our methodology contains only a few steps starting from weighing the starting materials, mixing to form saturated homogeneous solution, deposition into the mold and subsequent slow evaporation at room temperature, followed by demolding and air drying. Moreover, these eco-friendly piezoelectric elements demonstrate a maximum peak-peak voltage of 1.1 V and can operate at high temperatures.
2. We have achieved successful crystallisation of the multicomponent solid, S-Mand•L-Lys•5H2O, made from two components which have diverse and challenging crystallisation behaviours. This material demonstrates a single crystal d33 piezoelectric constant of 3.5pC/N but a polycrystalline d33 of 11 pC/N at the macroscale due to contributions from shear piezoelectric components induced in the triclinic structure. The brittleness of the crystals (Young’s modulus = 37 GPa) is overcome by reinforcing the substrate-free piezoelectric disc with a thin polymer coating to prevent flaking. DFT-calculated crystal, intramolecular, and intermolecular dipoles substantiate the nanoscale origins of the anisotropic piezoelectric responses.
3. Working with our collaborators, we have crystallised a series of structures sustained by both halogen bonds and hydrogen bonds, that exhibit a considerably high shear piezoelectric response. We have used Density Functional Theory (DFT) calculations to predict, quantify, and rationalise the piezoelectric response of these crystalline materials. Our calculations reveal a high shear piezoelectric response in all three crystals, with the highest predicted response of d15 = 99.19 pC/N. Piezoresponse Force Microscopy (PFM) experiments confirm effective shear piezoelectric constants of 54-74 pC/N. All three crystals belong to space groups that allow for natural longitudinal piezoelectric responses, with experimentally validated single crystal d33 values of 5-10 pC/N. This work adds to the growing number of unpoled molecular crystals approaching triple-digit piezoelectric responses to rival conventional perovskite ceramics.