Flexible high-performance microcapacitors enabled by all-printed two-dimensional nanosheets

Chemically exfoliated nanosheets have exhibited great potential for applications in various electronic devices. Solution-based processing strategies such as inkjet printing provide a low-cost, environmentally friendly, and scalable route for the fabrication of flexible devices based on functional inks of two-dimensional nanosheets. In this study, chemically exfoliated high- k perovskite nanosheets (i.e., Ca 2 Nb 3 O 10 and Ca 2 NaNb 4 O 13 ) are well dispersed in appropriate solvents to prepare printable inks, and then, a series of microcapacitors with Ag and graphene electrodes are printed. The resulting microcapacitors, Ag/Ca 2 Nb 3 O 10 /Ag, graphene/Ca 2 Nb 3 O 10 /graphene, and graphene/Ca 2 NaNb 4 O 13 /graphene, demonstrate high capacitance densities of 20, 80, and 150 nF/cm 2 and high dielectric constants of 26, 110, and 200, respectively. Such dielectric enhancement in the microcapacitors with graphene electrodes is possibly attributed to the dielectric/graphene interface. In addition, these microcapacitors also exhibit good insulating performance with a moderate electrical breakdown strength of approximately 1 MV/cm, excellent flexibility, and thermal stability up to 200 ℃. This work demonstrates the potential of high- k perovskite nanosheets for additive manufacturing of flexible high-performance dielectric capacitors.