IIT Madras Researchers Design White Light Emitters for LED Applications, win ‘SERB-Technology Translation Award’
As conventional LED materials cannot emit white light, there has been a worldwide search for materials that can directly emit white light rather than through these indirect techniques that can cause loss of efficiency
CHENNAI: Indian Institute of Technology Madras Researchers have successfully developed a white light emitter for use in LEDs. The development of energy-efficient Light Emitting Diodes or LEDs replaced the energy-inefficient incandescent lamps in lighting and display applications. While LEDs have been available in almost all colours, white LEDs are a more recent development.
Conventional LED materials cannot emit white light and specialized techniques such as coating blue LED with yellow phosphor and combining blue, green, and red LEDs, have been used to produce white light. There has been a worldwide search for materials that can directly emit white light rather than through these indirect techniques that can cause loss of efficiency.
The innovation has been patented by the Researchers and was recently granted the Government of India’s ‘SERB-Technology Translation Award.’ The Science and Engineering Research Board (SERB) provides financial assistance to researchers, academic institutions, research and development laboratories, industrial concerns, and other agencies. The team proposes to use the grant money of Rs. 30 lakh to produce LEDs using their distorted perovskite materials.
The research was led by Dr. Aravind Kumar Chandiran, Assistant Professor, Department of Chemical Engineering, IIT Madras, and Prof. Ranjit Kumar Nanda B., Department of Physics, IIT Madras.
Apart from the patent, the results of this research work have been published in the prestigious peer-reviewed International journal belonging to the Nature group – Communications Materials.
The Research Paper was co-authored by Dr. Tamilselvan Appadurai, Mr. Ravi Kashikar, Ms. Poonam Sikarwar, Dr. Sudhadevi Antharjanam, Dr. Ranjit Kumar Nanda B. and Dr. Aravind Kumar Chandiran
Explaining the practical applications of this Research, Dr. Aravind Kumar Chandiran, Assistant Professor, Department of Chemical Engineering, IIT Madras, said, “The indigenously-developed bright white light emitters can potentially replace the conventional high-cost materials and phenomenally save the energy cost per lumens.”
Touching on the future of their discovery, Dr. Aravind Kumar Chandiran added, “We believe that our work contributes to Government of India’s ‘Make in India’ programme and we hope to become a technology leader in light emitters in the near future.”
In their Communications Materials Research Paper, the researchers, in addition to reporting the details of the specific perovskite material, have also proposed a clear design strategy that scientists can employ to develop white light emitters.
Highlighting the impact this research could have in the field, Prof. Ranjit Kumar Nanda B., Department of Physics, IIT Madras, said, “Tuning the distortion at the atomic level to extract white light will motivate perovskite community to explore this topic much deeper.”
The IIT Madras team has been exploring crystalline materials called ‘Halide-Perovskites’ for various applications due to their extraordinary optoelectronic properties and excellent light-to-current conversion efficiencies.
The researchers developed expertise in tuning the material at an atomic level to obtain different properties. Through a recent project that included simulation and experimental work, the team distorted the crystal structure of this material to obtain a natural white light emitter.
Elaborating further, Dr. Aravind Kumar Chandiran said, “The strategic introduction of distortion in halide perovskite generated intense light covering the complete visible spectrum. These materials show at least eight times intense white light emission compared to the conventional and well-known Ce:YAG emitters.”
This distorted perovskite can be used independently as a white light emitter or as a phosphor in combination with blue LEDs to produce white light.
Unlike other recently developed white LED materials, this distorted perovskite showed phenomenal stability under ambient conditions. The emission of intense light and stability make them useful in long-lasting, energy-saving lighting applications. Apart from general lighting, white LEDs can potentially be used in liquid crystal display backlights, display mobile lighting, and medical and communication equipment.