Home > Press > Nanopores feel the heat: Researchers at Osaka University use a tiny thermometer to directly monitor changes in temperature when ions pass through a nanopore, which may lead to more efficient DNA sequencing technology
Schematic diagram showing the process of ionic heat dissipation in a nanopore (left). A nanoscale thermometer embedded on one side of the nanopore to detect local temperature changes caused by voltage-driven ionic transport (right).
CREDIT © 2022 M. Tsutsui et al., Ionic heat dissipation in solid-state pores. Science Advances |
Abstract:
Scientists from SANKEN (the Institute of Scientific and Industrial Research) at Osaka University measured the thermal effects of ionic flow through a nanopore using a thermocouple. They found that, under most conditions, both the current and heating power varied with applied voltage as predicted by Ohms law. This work may lead to more advanced nanoscale sensors.
Nanopores feel the heat: Researchers at Osaka University use a tiny thermometer to directly monitor changes in temperature when ions pass through a nanopore, which may lead to more efficient DNA sequencing technology
Osaka, Japan | Posted on February 11th, 2022
Nanopores, which are tiny openings in a membrane so small that only a single DNA strand or virus particle can pass through, are an exciting new platform for building sensors. Often, an electrical voltage is applied between the two side of the membrane to draw the substance to be analyzed through the nanopore. At the same time, charged ions in the solution can be transported, but their effect on the temperature has not been extensively studied. A direct measurement of the thermal effects caused by these ions can help make nanopores more practical as sensors.
Now, a team of researchers at Osaka University have created a thermocouple made of gold and platinum nanowires with a point of contact just 100 nm in size that served as the thermometer. It was used to measure the temperature directly next to a nanopore cut into a 40-nm-thick film suspended on a silicon wafer.
Joule heating occurs when electrical energy is converted into heat by the resistance in a wire. This effect occurs in toasters and electric stoves, and can be thought of as inelastic scattering by the electrons when they collide with the nuclei of the wire. In the case of a nanopore, the scientists found that thermal energy was dissipated in proportion to the momentum of the ionic flow, which is in line with the predictions of Ohms law. When studying a 300-nm-sized nanopore, the researchers recorded the ionic current of a phosphate buffered saline as a function of applied voltage. We demonstrated nearly ohmic behavior over a wide range of experimental conditions, first author Makusu Tsutsui says.
With smaller nanopores, the heating effect became more pronounced, because less fluid from the cooler side could pass through to equalize the temperature. As a result, the heating could cause a non-negligible effect, with nanopores experiencing a temperature increase of a few degrees under standard operating conditions. We expect the development of novel nanopore sensors that can not only identify viruses, but might also be able to deactivate them at the same time, senior author Tomoji Kawai says. The researchers proposed other situations in which the heating can be beneficialfor example, to prevent the nanopore from being clogged by a polymer, or to separate the strands of DNA being sequenced.
####
About Osaka University
Osaka University was founded in 1931 as one of the seven imperial universities of Japan and is now one of Japan’s leading comprehensive universities with a broad disciplinary spectrum. This strength is coupled with a singular drive for innovation that extends throughout the scientific process, from fundamental research to the creation of applied technology with positive economic impacts. Its commitment to innovation has been recognized in Japan and around the world, being named Japan’s most innovative university in 2015 (Reuters 2015 Top 100) and one of the most innovative institutions in the world in 2017 (Innovative Universities and the Nature Index Innovation 2017). Now, Osaka University is leveraging its role as a Designated National University Corporation selected by the Ministry of Education, Culture, Sports, Science and Technology to contribute to innovation for human welfare, sustainable development of society, and social transformation.
For more information, please click here
Contacts:
Saori Obayashi
Osaka University
Office: 81-661-055-886
Copyright © Osaka 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.
Possible Futures
Scientists use DNA to assemble complex nanomaterials: Researchers create DNA nano-chambers with bonds that can control the assembly of targeted nanoparticle structures February 11th, 2022
NGI advances graphene spintronics as 1D contacts improve mobility in nano-scale devices February 11th, 2022
Reusable Catalyst Makes CH Bond Oxidation Using Oxygen Easier and More Efficient February 11th, 2022
Polymer fibers with graphene nanotubes make it possible to heat hard-to-reach, complex-shaped items February 11th, 2022
Nanomedicine
Scientists use DNA to assemble complex nanomaterials: Researchers create DNA nano-chambers with bonds that can control the assembly of targeted nanoparticle structures February 11th, 2022
Polymer fibers with graphene nanotubes make it possible to heat hard-to-reach, complex-shaped items February 11th, 2022
Acceleration of cancer biomarker detection for point of care diagnostics January 28th, 2022
Sensors
Quantum tech in space? Scientists design remote monitoring system for inaccessible quantum devices February 11th, 2022
Pop-up electronic sensors could detect when individual heart cells misbehave December 24th, 2021
Researchers uncover the mechanism of electric field detection in microscale graphene sensors December 24th, 2021
New microscopy method offers 3D tracking of 100 single molecules at once November 19th, 2021
Discoveries
Eyebrow-raising: Researchers reveal why nanowires stick to each other February 11th, 2022
Quantum tech in space? Scientists design remote monitoring system for inaccessible quantum devices February 11th, 2022
NGI advances graphene spintronics as 1D contacts improve mobility in nano-scale devices February 11th, 2022
Reusable Catalyst Makes CH Bond Oxidation Using Oxygen Easier and More Efficient February 11th, 2022
Announcements
University of Oklahoma scientists quantum technology work garners international attention February 11th, 2022
Reusable Catalyst Makes CH Bond Oxidation Using Oxygen Easier and More Efficient February 11th, 2022
Wise-integration and EDOM Technology Announce Channel Partnership for GaN IC Power Semiconductor Deployment February 11th, 2022
Polymer fibers with graphene nanotubes make it possible to heat hard-to-reach, complex-shaped items February 11th, 2022
Interviews/Book Reviews/Essays/Reports/Podcasts/Journals/White papers/Posters
Copper doping enables safer, cost-effective hydrogen peroxide production February 11th, 2022
Eyebrow-raising: Researchers reveal why nanowires stick to each other February 11th, 2022
Quantum tech in space? Scientists design remote monitoring system for inaccessible quantum devices February 11th, 2022
NGI advances graphene spintronics as 1D contacts improve mobility in nano-scale devices February 11th, 2022