Abstract
Solution‐processable thin‐film dielectrics represent an important material family for large‐area, fully‐printed electronics. Yet, in recent years, it has seen only limited development, and has mostly remained confined to pure polymers. Although it is possible to achieve excellent printability, these polymers have low (≈2–5) dielectric constants (εr). There have been recent attempts to use solution‐processed 2D hexagonal boron nitride (h‐BN) as an alternative. However, the deposited h‐BN flakes create porous thin‐films, compromising their mechanical integrity, substrate adhesion, and susceptibility to moisture. These challenges are addressed by developing a “one‐pot” formulation of polyurethane (PU)‐based inks with h‐BN nano‐fillers. The approach enables coating of pinhole‐free, flexible PU+h‐BN dielectric thin‐films. The h‐BN dispersion concentration is optimized with respect to exfoliation yield, optical transparency, and thin‐film uniformity. A maximum εr ≈ 7.57 is achieved, a two‐fold increase over pure PU, with only 0.7 vol% h‐BN in the dielectric thin‐film. A high optical transparency of ≈78.0% (≈0.65% variation) is measured across a 25 cm2 area for a 10 μm thick dielectric. The dielectric property of the composite is also consistent, with a measured areal capacitance variation of <8% across 64 printed capacitors. The formulation represents an optically transparent, flexible thin‐film, with enhanced dielectric constant for printed electronics.
Highlights
Printed electronics hold great potential for flexible, wearable, and large form-factor devices 1–3
Our work demonstrates hexagonal boron nitride (h-BN) enhanced transparent and flexible PU polymer dielectric for the potential applications in printable electronics
We demonstrate the fabrication of single-coat 10-μm thick, pin-hole free, flexible dielectric films with high optical uniformity and transparency
Summary
Printed electronics hold great potential for flexible, wearable, and large form-factor devices 1–3. Polyurethane (PU) represents a class of polymers that are widely used in graphics, and functional printing and coatings industry 12 due to its high tensile strength, scratch, corrosion and solvent resistance 13,14 These properties make PU and related dielectric composites interesting for electronics, but with a moderate εr (∼3-4 15–17). 2D hexagonal boron nitride (h-BN), an insulating analogue of graphene, is frequently used as a dielectric screening layer for graphene and other 2D materials for device applications 20–22 due to its wide bandgap (∼6 eV) 23,24,26 This approach has been applied to printable electronics, using solution-phase exfoliation of h-BN and its incorporation into functional inks 25,27,28. Our approach in enhancing the dielectric constant of a commonly used printable polymer, while keeping high optical transparency, could be of interest in large area, fully printed transparent and flexible capacitive structures, such as low pass filters and touch sensors
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