Over the years, a significant research drive towards this objective is in exploring new materials for LED-chip encapsulation, mostly by deploying either higher refractive index glasses or epoxy materials incorporated with filler powders or nanoparticle-loaded-epoxy or engineered epoxy resins, etc. However, these techniques either make the LED chips bulkier or their fabrication becomes more challenging and less economically viable for mass production.
To meet the goals the research team has developed a nanoparticle ‘meta-grid’, which can be placed at an appropriate location within the epoxy casing of the LEDs, for improving light output from LEDs. A ‘meta-grid’ is a specially-designed, optimised, two-dimensional array of specific nanoparticles, of size much smaller than the wavelength of light.
Shinier, robust and pinchpenny LEDs
While prescribing minimal changes to the manufacturing process, the research team has developed this novel scheme of boosting transmission of light generated inside an LED chip across the LED-chip/encapsulant interface. This is achieved by reducing the Fresnel reflection loss at the chip/encapsulant interface, within a fixed photon escape cone, based on tuning the destructive interference phenomena with help of the ‘meta-grid’. The technique has revealed optimal design parameters for such meta-grids to produce greater light output over any narrow/broadband emission spectrum, besides boosting LEDs’ lifetime by eliminating heating of the chip from unwanted reflections within the chip.
Dr.DebabrataSikdar, Assistant Professor, Department of Electronics and Electrical Engineering, IIT Guwahati said, “In this invention, the effects of the ‘meta-grid’ on the standard commercial LEDs, based on group III–V materials are demonstrated. However, the proposed concept of enhancing light transmission from an emissive layer to its encapsulant casing can be extended to other types of light emitting devices hosting an emissive-layer/encapsulant interface. Generally, our nanoparticle ‘meta-grid’ scheme for enhanced light extraction could potentially cater to a wider range of optical gadgets, not just semiconductor LEDs.”
Talking about their work, Prof. Sir John B. Pendry, Department of Physics, Imperial College London, said, “The simplicity of the proposed scheme and the clear physics underpinning it should make it robust and, hopefully, easily adaptable to the existing LED manufacturing process. It is obvious that with larger light extraction efficiency, LEDs will provide greater energy savings as well as longer lifetimes of the devices”.
The research team includes DrDebabrataSikdar, Prof Sir John B. Pendry and ProfAlexei A. Kornyshev from Imperial College, London. The findings have been published in Light: Science & Applications journal. (India Science Wire)