Although flakes of two-dimensional (2D) heterostructures at the micrometer scale can be formed with adhesive-tape exfoliation methods, isolation of 2D flakes into monolayers is extremely time consuming because it is a trial-and-error process. Controlling the number of 2D layers through direct growth also presents difficulty because of the high nucleation barrier on 2D materials. We demonstrate a layer-resolved 2D material splitting technique that permits high-throughput production of multiple monolayers of wafer-scale (5-centimeter diameter) 2D materials by splitting single stacks of thick 2D materials grown on a single wafer. Wafer-scale uniformity of hexagonal boron nitride, tungsten disulfide, tungsten diselenide, molybdenum disulfide, and molybdenum diselenide monolayers was verified by photoluminescence response and by substantial retention of electronic conductivity. We fabricated wafer-scale van der Waals heterostructures, including field-effect transistors, with single-atom thickness resolution.
Recent advances in flexible and stretchable electronics have led to a surge of electronic skin (e-skin)–based health monitoring platforms. Conventional wireless e-skins rely on rigid integrated circuit chips that compromise the overall flexibility and consume considerable power. Chip-less wireless e-skins based on inductor-capacitor resonators are limited to mechanical sensors with low sensitivities. We report a chip-less wireless e-skin based on surface acoustic wave sensors made of freestanding ultrathin single-crystalline piezoelectric gallium nitride membranes. Surface acoustic wave–based e-skin offers highly sensitive, low-power, and long-term sensing of strain, ultraviolet light, and ion concentrations in sweat. We demonstrate weeklong monitoring of pulse. These results present routes to inexpensive and versatile low-power, high-sensitivity platforms for wireless health monitoring devices.
Free-standing
crystalline membranes are highly desirable owing
to recent developments in heterogeneous integration of dissimilar
materials. Van der Waals (vdW) epitaxy enables the release of crystalline
membranes from their substrates. However, suppressed nucleation density
due to low surface energy has been a challenge for crystallization;
reactive materials synthesis environments can induce detrimental damage
to vdW surfaces, often leading to failures in membrane release. This
work demonstrates a novel platform based on graphitized SiC for fabricating
high-quality free-standing membranes. After mechanically removing
epitaxial graphene on a graphitized SiC wafer, the quasi-two-dimensional
graphene buffer layer (GBL) surface remains intact for epitaxial growth.
The reduced vdW gap between the epilayer and substrate enhances epitaxial
interaction, promoting remote epitaxy. Significantly improved nucleation
and convergent quality of GaN are achieved on the GBL, resulting in
the best quality GaN ever grown on two-dimensional materials. The
GBL surface exhibits excellent resistance to harsh growth environments,
enabling substrate reuse by repeated growth and exfoliation.
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