Categories: Blog

Colloidal Quantum Dots Make LEDs Shine Bright in the Infrared — LED professional


The ICFO team has reported a solution processed nanocomposite system comprising infrared colloidal quantum dots that also meets these criteria and at the same time offers low cost and facile CMOS integration. Colloidal Quantum Dots (CQDs) are extremely small semiconductor particles or crystals, as small as a few nanometers in size, and because of their size they are capable of having unique optical and electronic properties. They are excellent absorbers and emitters of light, having their properties change as a function of their size and shape: smaller quantum dots emit in the blue range while larger quantum dots emit in the red.

The use of colloidal quantum dot (CQD) light-emitting diodes (LEDs) has become one of the key ingredients in leading technologies such as, for example, 3rd generation, solution processed, and inorganic solar cells. The implementation of these nanocrystals in devices for optical sensing in the short-wave and mid- infrared have triggered a vast number of applications including surveillance, night vision, product, process and environmental monitoring and spectroscopy.

In this recent study published in Nature Nanotechnology, ICFO researchers Santanu Padhan, Francesco Di Stasio, Yu Bi, Shuchi Gupta, Sotirios Christodoulou, and Alexandros Stavrinadis, led by ICREA Prof. at ICFO Gerasimos Konstantatos, have developed CQD infrared emitting LEDs, which have achieved unprecedented values in the infrared range, with an external quantum efficiency of 7.9% and a power conversion efficiency of 9.3%, a value never attained before with these type of devices.

The key feature of this work has been the development of a CQD composite structure engineered at the suprananocrystalline level to reach unprecedently low electronic defect density. Prior efforts in suppressing electronic defects in CQD solids have been primarily been based on chemical passivation of the CQD surface, something that could not solve the problem in PbS QDs. The researchers at ICFO took an alternative path of creating the appropriate matrix in which they embedded the emitting QDs, to serve as a remote electronic passivant for the emitter CQDs. Moreover, the energetic landscape of the matrix was engineered in order to facilitate efficient charge funnelling into the QD emitters in order to achieve efficient electrical injection.

With these new blend devices, the team of researchers took a step further and constructed solar cells to test their performance in the infrared range. In doing so they discovered that the effective passivation achieved in these nanocomposites along with the modulation of the electronic density of states has resulted in solar cells that deliver open circuit voltage very close to the theoretical limit. The open circuit voltage (VOC), which is the maximum voltage available from a solar cell, increased from 0.4 V for a single QD configuration, up to ~0.7 V for the ternary blend configuration, an impressive value considering the lower bandgap of the cell at ~0.9 eV. As ICREA Prof at ICFO Gerasimos Konstantatos comments, “The most surprising finding of this study is the extremely low electronic trap density that can be achieved in a conductive QD material system that is full of chemical defects arising on the surface of the dots, the very high quantum efficiency of those LEDs has been the consequence of this passivation strategy we demonstrate. The other exciting outcome has been the potential to reach so high Voc values for QD solar cells that was synergistically achieved thanks to the very low trap density as well as to a novel engineering approach of the density of states in a semiconductor film”. Santanu Pradhan, the first author of this study adds: “Next we will focus on how to further exploit this reduction of electronic density of states synergistically with other means to allow for simultaneous achievement of high Voc and current production, thereby targeting record power conversion efficiencies in solar cell devices” The results obtained in this study prove that the engineering of QCD infrared-emitting LEDs at the nanoscale integrated in solar cells can significantly improve the performance efficiency of these devices in the infrared range. Such results open the pathway into a range of the spectra that is still to be fully exploited and offers amazing new applications, such as on-chip spectrometers for food inspection, environmental monitoring, manufacturing process monitoring as well as active imaging systems for biomedical or night vision applications.

As ICREA Prof at ICFO Gerasimos Konstantatos comments, “The most surprising finding of this study is the extremely low electronic trap density that can be achieved in a conductive QD material system that is full of chemical defects arising on the surface of the dots, the very high quantum efficiency of those LEDs has been the consequence of this passivation strategy we demonstrate. The other exciting outcome has been the potential to reach so high Voc values for QD solar cells that was synergistically achieved thanks to the very low trap density as well as to a novel engineering approach of the density of states in a semiconductor film”. Santanu Pradhan, the first author of this study adds: “Next we will focus on how to further exploit this reduction of electronic density of states synergistically with other means to allow for simultaneous achievement of high Voc and current production, thereby targeting record power conversion efficiencies in solar cell devices”.

The results obtained in this study prove that the engineering of QCD infrared-emitting LEDs at the nanoscale integrated in solar cells can significantly improve the performance efficiency of these devices in the infrared range. Such results open the pathway into a range of the spectra that is still to be fully exploited and offers amazing new applications, such as on-chip spectrometers for food inspection, environmental monitoring, manufacturing process monitoring as well as active imaging systems for biomedical or night vision applications.

About ICFO:

ICFO is a young research institution that aims to advance the very limits of knowledge in Photonics, namely the science and technology of harnessing Light. Light, especially laser light, is one of the major enabling technologies currently available to humankind. Our research thrusts target the global forefront of photonics, and aim to tackle important challenges faced by society at large. We focus on current and future problems in Health, Energy, Information, Safety, Security and caring for the Environment.

Acknowledgements:

The original paper, “High-Efficiency Colloidal Quantum Dot Infrared Light-Emitting Diodes Via Engineering at the Supra-Nanocrystalline Level” from Santanu Pradhan, Francesco Di Stasio, Yu Bi, Shuchi Gupta, Sotirios Christodoulou, Alexandros Stavrinadis and Gerasimos Konstantatos has been published on December 3rd at Nature Nanotechnology: www.nature.com/articles/s41565-018-0312-y 



Source link

admin

Share
Published by
admin

Recent Posts

High TLCI Illumination for Accurate Color in Telework & Indoor Video Recording — LED professional

Over the past 50 years, Nichia has demonstrated its commitment to improving the overall performance…

3 years ago

Blueglass to Aquire US Laser Diode Facility — LED professional

To fund the acquisition and ongoing operation of the production facility, BluGlass has secured A$3.4…

3 years ago

High-performance for wavelengths in infrared

New CAS 140D IR spectroradiometer with improved optical and electronic components offer the user higher…

3 years ago

Seoul Semiconductor Relocates Headquarters of Automobile Division to Germany — LED professional

SSC boasts world's only LED and LD technology for vehicles using all wavelengths of light…

3 years ago

Panel technology: HELLA develops new design concepts for the vehicle front end

  ​E-cars do not have a classic radiator grille, so the front of the vehicle…

3 years ago

Data Reporting, Diagnostics, Sensors and NLCs Added to ANSI C137.4-2021 Standard for Digital Lighting Control — LED professional

“We welcome the further alignment of ANSI C137.4-2021 and D4i, which is expected to lead…

3 years ago