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Research Tracker

This tool is intended for researchers and program managers to quickly find research projects around the country that are relevant to their work. The four organizations who provided content for this purpose represent the largest energy efficient buildings research portfolios in the country. These organizations each provided the content that they were comfortable sharing publically. Therefore, upon clicking on a particular project, it is possible that certain pieces of content are not present. Where possible, a point of contact is provided so that specific questions can be directed to that person. We welcome your comments! If you would like to provide any feedback on this tool (positive or constructive) please email basc@pnnl.gov.

Showing results 1 - 35 of 35

Development and Industrialization of InGaN/GaN LEDs on Patterned Sapphire Substrates for Low Cost Emitter Architecture

Lumileds, LLC will reduce LED manufacturing costs by eliminating some of the complex processes associated with current flip-chip technology and enabling lower-cost packaging methods. This project looks to address the needs of the indoor and outdoor illumination markets, which demand the most competitive Lm/W and Lm/$ characteristics in small footprint components.

Eliminating Plasmon Losses in High Efficiency White Organic Light Emitting Devices for Lighting Applications

University of Michigan - Ann Arbor will develop innovative methods to outcouple the light within OLED devices in order to increase external quantum efficiency. This will be accomplished through nanoscale texturing beneath the anode outside the active region, fabricating sub-anode gratings along with microlens arrays, and top emitting structures with a sub-anode grid coupled with a reflective mirror at the base.

From the Laboratory to the California Marketplace: A New Generation of LED Lighting Solutions

This project will design and develop innovative LED lighting solutions for three key general illumination product categories. These solutions are a best-in-class medium, screw-base replacement lamp, linear tubular light emitting diode (TLED) replacement lamps and spectrally optimized, dedicated LED luminaires. Product design requirements will be based on consumer light quality and functional performance preferences determined through a series of unique laboratory-based consumer preference and product characterization studies

From the Laboratory to the California Marketplace: A New Generation of LED Lighting Solutions

This project will design and develop innovative LED lighting solutions for three key general illumination product categories. These solutions are a best-in-class medium, screw-base replacement lamp, linear tubular light emitting diode (TLED) replacement lamps and spectrally optimized, dedicated LED luminaires. Product design requirements will be based on consumer light quality and functional performance preferences determined through a series of unique laboratory-based consumer preference and product characterization studies

Graded Alloy Quantum Dots for Energy-Efficient Solid-State Lighting

Columbia University will use an inexpensive and widely tunable library of quantum dot (QD) synthesis reagents along with automated high-throughput synthesis and analysis tools to grade the alloy composition of QD heterostructures, in order to provide stable and efficient narrow-band red down-converters for LEDs.

High Efficacy, Multi-Functional SSL Platform

Cree, Inc. will incorporate a high-efficacy LED light engine into a demonstration luminaire, with concurrent advancements in LED light engines, optics, and sensors integrated to result in high efficacy as well as additional features such as spectral tuning.

High Efficiency and Stable White OLED Using a Single Emitter

Arizona State University is demonstrating an efficient and stable white organic light diode (WOLED) using a single emitter on a planar glass substrate. By simplifying the device fabrication process, increasing the robustness of materials, and providing cost-effective emitter materials, Arizona State University will help reduce the overall manufacturering costs of WOLEDs.

High Performance Green LEDs for Solid State Lighting

This project will address the fundamental challenges for green LEDs by a combination of innovations in epitaxial growth and layer design, advanced processes including tunnel junctions, and advanced materials characterization.

High-Efficacy High-Power LED for Directional Applications

Lumileds, LLC will develop a high-efficacy, high-power LED emitter enabled by patterned sapphire substrate flip-chip architecture, die development to include novel contact design, phosphors with reduced bandwidth, and new optical materials for light extraction from the die.

High-Performance OLED Panel and Luminaire

OLEDWorks will develop the cost-effective and scalable manufacturing methods needed to produce a high-performance, large-area OLED lighting panel and luminaire system. This work will help develop and integrate the cost effective manufacturing technologies necessary to achieve the DOE performance and cost targets.

High-Voltage LED Light Engine with Integrated Driver

Lumileds, LLC will develop an LED light engine that integrates a new low-cost, high-power chip and optimized drivers. This light engine will enable comprehensive luminaire system cost reduction.

Highly Integrated Modular LED Luminaire

GE Global Research will build a scalable, efficient, modular luminaire to address the integration of driver, optics, and package in a flexible integration platform that allows for simplified manufacturing to customized performance specifications.

Improved Radiative Recombination in AlGaInP LEDs

This project will improve the external quantum efficiency (EQE) of amber and red aluminium gallium indium phosphide (AlGaInP)-based LEDs by developing strain-engineered cladding layers to provide enhanced carrier confinement.

Investigating the Health Impacts of Outdoor Lighting

This project will attempt to measure the impact of lighting on the users of an outdoor lighting space. The experiments will determine the effects of different lighting types on the melatonin levels of the participants. As different CCT light sources will be used, their differing spectral contents can be evaluated to determine the most appropriate light source for implementation in the outdoor environment.

Low Cost Corrugated Substrates for High Efficiency OLEDs

North Carolina State University will develop OLEDs fabricated on low-cost high index corrugated substrates with a semi-random periodicity to give enhancements in extraction efficiency across the entire visible spectrum, due to the extraction of the thin-film-guided and surface-plasmon modes.

Luminaires for Advanced Lighting in Education

RTI International will develop and demonstrate novel luminaire designs that utilize advanced classroom lighting system technology, demonstrate the benefits of dynamic lighting, and collect feedback from education stakeholders. These efforts could increase the use of next-generation lighting in schools.

Miniaturized Air to Refrigerant Heat Exchangers

This project will attempt to develop and demonstrate a novel fabrication process that eliminates the use of shadow masks during the OLED deposition process. The proposed system will allow blanket deposition of all organic and cathode layers everywhere on the substrate, eliminating the need for masks.

Narrow Emitting Red Phosphors for Improving pcLED Efficacy

Lumenari, Inc. will develop a narrow-bandwidth red phosphor to improve phosphor-converted LED efficacy up to 28%. This will be accomplished through a combination of experimental and computational techniques to develop a novel host material for the selected emitter ion.

OLED Luminaire with Panel Integrated Drivers and Advanced Controls

Acuity Brands Lighting will develop an OLED luminaire that features DC current drivers integrated with each panel and advanced user controls. This advancement in OLED technology could lead to more-efficient OLED lighting systems and reduced energy use for building lighting.

Print-Based Manufacturing of Integrated, Low Cost, High Performance SSL Luminaires

Eaton Corporation will develop a new low-cost, high-efficiency LED architecture made possible by advanced manufacturing techniques which will enable both high efficiency and high color quality. Reduced material costs and optimized manufacturing could reduce the integrated light engine price from $50/klm at the project's inception to less than $4/klm.

Scalable Light Module for Low-Cost, High Efficiency LED Luminaires

Cree will develop a versatile, low-cost, low profile LED light-module architecture that facilitates the assembly of a variety of high-efficacy, broad-area LED luminaires. This lightweight architecture will be applicable to numerous high-efficiency, broad-area LED luminaires and will ultimately reduce the cost per lumen of LED lighting.

System Reliability Model for Solid-State Lighting Luminaires

RTI International will develop and validate a reliability model and accelerated life testing methodologies to predict the lifetime of integrated solid-state lighting luminaires. By improving testing methods, this project will give additional product information to manufacturers and SSL users who seek to justify higher first cost for SSL products over less efficient lighting technologies.

The Approach to Low-Cost High-Efficiency OLED Lighting

The University of California, Los Angeles, will develop components for the fabrication of OLEDs with improved energy efficiency and reduced manufacturing cost. This improved OLED technology could lead to lower-cost, more-efficient lighting options being available on the market.