Nanotechnology Now – Press Release: Improving quantum dot interactions, one layer at a time: Scientists have found a way to control an interaction between quantum dots that could lead to more efficient solar cells


Home > Press > Improving quantum dot interactions, one layer at a time: Scientists have found a way to control an interaction between quantum dots that could lead to more efficient solar cells

Low quantum dot concentrations during superlattice fabrication suppresses quantum resonance between dots in the same layer, while high concentrations activates it

CREDIT
DaeGwi Kim, Osaka City University
Low quantum dot concentrations during superlattice fabrication suppresses quantum resonance between dots in the same layer, while high concentrations activates it

CREDIT
DaeGwi Kim, Osaka City University

Abstract:
Osaka City University scientists and colleagues in Japan have found a way to control an interaction between quantum dots that could greatly improve charge transport, leading to more efficient solar cells. Their findings were published in the journal Nature Communications.

Improving quantum dot interactions, one layer at a time: Scientists have found a way to control an interaction between quantum dots that could lead to more efficient solar cells


Osaka, Japan | Posted on November 20th, 2020

Nanomaterials engineer DaeGwi Kim led a team of scientists at Osaka City University, RIKEN Center for Emergent Matter Science and Kyoto University to investigate ways to control a property called quantum resonance in layered structures of quantum dots called superlattices.

“Our simple method for fine-tuning quantum resonance is an important contribution to both optical materials and nanoscale material processing,” says Kim.

Quantum dots are nanometer-sized semiconductor particles with interesting optical and electronic properties. When light is shone on them, for example, they emit strong light at room temperature, a property called photoluminescence. When quantum dots are close enough to each other, their electronic states are coupled, a phenomenon called quantum resonance. This greatly improves their ability to transport electrons between them. Scientists have been wanting to manufacture devices using this interaction, including solar cells, display technologies, and thermoelectric devices.

However, they have so far found it difficult to control the distances between quantum dots in 1D, 2D and 3D structures. Current fabrication processes use long ligands to hold quantum dots together, which hinders their interactions.

Kim and his colleagues found they could detect and control quantum resonance by using cadmium telluride quantum dots connected with short N-acetyl-L-cysteine ligands. They controlled the distance between quantum dot layers by placing a spacer layer between them made of oppositely charged polyelectrolytes. Quantum resonance is detected between stacked dots when the spacer layer is thinner than two nanometers. The scientists also controlled the distance between quantum dots in a single layer, and thus quantum resonance, by changing the concentration of quantum dots used in the layering process.

The team next plans to study the optical properties, especially photoluminescence, of quantum dot superlattices made using their layer-by-layer approach. “This is extremely important for realizing new optical electronic devices made with quantum dot superlattices,” says Kim.

Kim adds that their fabrication method can be used with other types of water-soluble quantum dots and nanoparticles. “Combining different types of semiconductor quantum dots, or combining semiconductor quantum dots with other nanoparticles, will expand the possibilities of new material design,” says Kim.

####

About Osaka City University
We are Osaka City University – the oldest research university in Osaka. With 9 undergraduate faculties and 11 graduate schools all dedicated to making urban life better, energy cleaner, and people healthier and happier, we have won numerous awards and have produced 2 Nobel laureates. For more information, please visit our website at https://www.osaka-cu.ac.jp/en

For more information, please click here

Contacts:
James Gracey

81-666-053-592

@OCU_PR

Copyright © Osaka City University

If you have a comment, please Contact us.

Issuers of news releases, not 7th Wave, Inc. or Nanotechnology Now, are solely responsible for the accuracy of the content.

Bookmark:
Delicious
Digg
Newsvine
Google
Yahoo
Reddit
Magnoliacom
Furl
Facebook

RELATED JOURNAL ARTICLE:

News and information

New type of ultrahigh piezoelectricity in hydrogen-bonded ferroelectrics November 20th, 2020

Staying ahead of the curve with 3D curved graphene November 20th, 2020

Nanosoft releases nanoCAD Plus 20 as a major update November 20th, 2020

Spintronics advances — Controlling magnetization direction of magnetite at room temperature: Scientists develop an energy-efficient strategy to reversibly change ‘spin orientation’ or magnetization direction in magnetite at room temperature November 20th, 2020

Display technology/LEDs/SS Lighting/OLEDs

Breakthrough quantum-dot transistors create a flexible alternative to conventional electronics: Quantum dot logic circuits provide the long-sought building blocks for innovative devices, including printable electronics, flexible displays, and medical diagnostics October 30th, 2020

Veeco Announces Aledia Order of 300mm MOCVD Equipment for microLED Displays: Propel™ Platform First 300mm System with EFEM Designed for Advanced Display Applications October 20th, 2020

HKU Engineering team develops novel miniaturised organic semiconductor: An important breakthrough essential for future flexible electronic devices October 8th, 2020

28HV Solution Accelerates GLOBALFOUNDRIES Leadership in OLED Display Drivers for Mobile Devices: With more than 75 million units shipped to leading smartphone suppliers, GF’s 28HV solution is optimized to enable faster, brighter, sharper, and more power-efficient OLED displays October 1st, 2020

Possible Futures

New type of ultrahigh piezoelectricity in hydrogen-bonded ferroelectrics November 20th, 2020

Staying ahead of the curve with 3D curved graphene November 20th, 2020

Nanosoft releases nanoCAD Plus 20 as a major update November 20th, 2020

Spintronics advances — Controlling magnetization direction of magnetite at room temperature: Scientists develop an energy-efficient strategy to reversibly change ‘spin orientation’ or magnetization direction in magnetite at room temperature November 20th, 2020

Discoveries

New type of ultrahigh piezoelectricity in hydrogen-bonded ferroelectrics November 20th, 2020

Staying ahead of the curve with 3D curved graphene November 20th, 2020

Spintronics advances — Controlling magnetization direction of magnetite at room temperature: Scientists develop an energy-efficient strategy to reversibly change ‘spin orientation’ or magnetization direction in magnetite at room temperature November 20th, 2020

NIST sensor experts invent supercool mini thermometer November 17th, 2020

Announcements

New type of ultrahigh piezoelectricity in hydrogen-bonded ferroelectrics November 20th, 2020

Staying ahead of the curve with 3D curved graphene November 20th, 2020

Nanosoft releases nanoCAD Plus 20 as a major update November 20th, 2020

Spintronics advances — Controlling magnetization direction of magnetite at room temperature: Scientists develop an energy-efficient strategy to reversibly change ‘spin orientation’ or magnetization direction in magnetite at room temperature November 20th, 2020

Interviews/Book Reviews/Essays/Reports/Podcasts/Journals/White papers/Posters

New type of ultrahigh piezoelectricity in hydrogen-bonded ferroelectrics November 20th, 2020

Staying ahead of the curve with 3D curved graphene November 20th, 2020

Spintronics advances — Controlling magnetization direction of magnetite at room temperature: Scientists develop an energy-efficient strategy to reversibly change ‘spin orientation’ or magnetization direction in magnetite at room temperature November 20th, 2020

NIST sensor experts invent supercool mini thermometer November 17th, 2020

Energy

CEA-Leti to Build Quantum-Photonics Platform to Ensure Ultra-Secure Data for Finance, Energy, Defense and Other Industries : Project Will Build Demonstrators for Transmitting and Receiving Qubits and Focus on Integrating the Technology in a Unique Platform to Address Quantum Comp October 30th, 2020

Development of cost-efficient electrocatalyst for hydrogen production: Development of a highly efficient and durable electrocatalyst for water electrolysis that will lead to cost-efficient hydrogen production. Trace amounts of titanium doping on low-cost molybdenum phosphide resu October 9th, 2020

Multi-institutional team extracts more energy from sunlight with advanced solar panels October 6th, 2020

New design principles for spin-based quantum materials: Criteria for designing targeted quantum materials could support Internet of Things devices and other resource-intensive technologies September 20th, 2020

Battery Technology/Capacitors/Generators/Piezoelectrics/Thermoelectrics/Energy storage

New type of ultrahigh piezoelectricity in hydrogen-bonded ferroelectrics November 20th, 2020

Staying ahead of the curve with 3D curved graphene November 20th, 2020

Anions matter: Zinc-ion hybrid capacitors with ideal anions in the electrolyte show extra-long performance November 13th, 2020

Order in the disorder: density fluctuations in amorphous silicon discovered October 30th, 2020

Quantum Dots/Rods

Breakthrough quantum-dot transistors create a flexible alternative to conventional electronics: Quantum dot logic circuits provide the long-sought building blocks for innovative devices, including printable electronics, flexible displays, and medical diagnostics October 30th, 2020

A quantum material-based diagnostic paint to sense problems before structural failure October 23rd, 2020

Turning a hot spot into a cold spot: Fano-shaped local-field responses probed by a quantum dot October 9th, 2020

Charcoal a weapon to fight superoxide-induced disease, injury: Nanomaterials soak up radicals, could aid treatment of COVID-19 July 2nd, 2020

Solar/Photovoltaic

Multi-institutional team extracts more energy from sunlight with advanced solar panels October 6th, 2020

Layer of nanoparticles could improve LED performance and lifetime August 7th, 2020

May the force be with you: Detecting ultrafast light by its force: From cell phones to solar cells – research has implications for improvements in a wide range of technologies August 7th, 2020

Crystal structure discovered almost 200 years ago could hold key to solar cell revolution July 3rd, 2020

Quantum nanoscience

NIST sensor experts invent supercool mini thermometer November 17th, 2020

CCNY & partners in quantum algorithm breakthrough November 13th, 2020

Smaller than Ever—Exploring the Unusual Properties of Quantum-sized Materials November 13th, 2020

A new candidate material for quantum spin liquids November 12th, 2020

Leave a Reply

Your email address will not be published. Required fields are marked *