Abstract
We report on the fabrication and characteristics of an individually addressable gallium nitride (GaN) microdisk light-emitting diode (LED) array in free-standing and ultrathin form. A high-quality GaN microdisk array with n-GaN, InGaN/GaN quantum wells and p-GaN layers was epitaxially grown on graphene microdots patterned on SiO2/Si substrates. Due to the weak attachment of the graphene microdots to the growth substrate, a microdisk array coated with a polyimide layer was easily separated from the substrate using mechanical or chemical methods to form an ultrathin free-standing film. Individually addressable microdisk LEDs were created by forming thin metal contacts on the p-GaN and n-GaN surfaces in a crossbar configuration. Each microdisk LED that comprised an ultrahigh resolution array of 2500 pixels per inch was found to be uniquely addressable. The devices in free-standing form exhibited stable electrical and optoelectronic characteristics under extreme bending conditions and continuous operation mode despite the absence of a heat dissipating substrate. These results present promising approaches for the fabrication of high-quality inorganic semiconductor devices for ultrahigh resolution and high-performance flexible applications.
Highlights
Inorganic microlight-emitting diode arrays are emerging as one of the most promising light emitters for next-generation display technologies and ultrahigh resolution optogenetic light source arrays[1,2,3,4,5]
We report on the fabrication and electroluminescence (EL) characteristics of a flexible and individually addressable gallium nitride (GaN) microdisk lightemitting diode (LED) array in free-standing and ultrathin form, enabled by position-controlled graphene microdots that act as microdisk growth and release sites
This enabled the fabrication of numerous flexible microdisk LED arrays from a single growth of a large-area GaN microdisk array
Summary
Inorganic microlight-emitting diode (micro-LED) arrays are emerging as one of the most promising light emitters for next-generation display technologies and ultrahigh resolution optogenetic light source arrays[1,2,3,4,5]. In free-standing and ultrathin form, the applicability of micro-LEDs can be further expanded to include various wearable, medical, and implantable devices[5,11,12,13,14], which require conformal contact on human skin or organs with minimal discomfort and stress. The inherent rigidity of inorganic materials and difficulty separating inorganic thin films from their single crystal growth substrates represent substantial challenges to the fabrication of freestanding and ultrathin inorganic LEDs. we report on the fabrication and electroluminescence (EL) characteristics of a flexible and individually addressable gallium nitride (GaN) microdisk LED array in free-standing and ultrathin form, enabled by position-controlled graphene microdots that act as microdisk growth and release sites
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