Detail publikačního výsledku

Droplet-based differential microcalorimeter for real-time energy balance monitoring

FENG, J.; PODEŠVA, P.; ZHU, H.; PEKÁREK, J.; MAYORGA-MARTINEZ, C.; CHANG, H.; PUMERA, M.; NEUŽIL, P.

Originální název

Droplet-based differential microcalorimeter for real-time energy balance monitoring

Anglický název

Droplet-based differential microcalorimeter for real-time energy balance monitoring

Druh

Článek WoS

Originální abstrakt

Microcalorimeters have been widely used for characterizing molecular interactions in physical, chemical and biological research. Here, we report on a droplet-based micromachined calorimeter for real-time energy balance monitoring. The microcalorimeter was fabricated by a single lithography process and wafer dicing using glass substrate with a diameter and a thickness of approximate to 100 mm and approximate to 100 mu m, respectively. The sample with volume of approximate to 0.5 mu L was placed on the microcalorimeter and covered with mineral oil to avoid evaporation. The microcalorimeter was operated in differential mode having the temperature and power resolution of approximate to 148 mu k and approximate to 42 nW, respectively. With this system, we monitored the energy balance of H2O2 decomposition catalyzed by few self-propelled Pt microrobots. Such a simple microcalorimeter has tremendous potential for chemical and biological research such as monitoring the energy balance of living cells or microorganisms and correlating the energy changes with their activities and status.

Anglický abstrakt

Microcalorimeters have been widely used for characterizing molecular interactions in physical, chemical and biological research. Here, we report on a droplet-based micromachined calorimeter for real-time energy balance monitoring. The microcalorimeter was fabricated by a single lithography process and wafer dicing using glass substrate with a diameter and a thickness of approximate to 100 mm and approximate to 100 mu m, respectively. The sample with volume of approximate to 0.5 mu L was placed on the microcalorimeter and covered with mineral oil to avoid evaporation. The microcalorimeter was operated in differential mode having the temperature and power resolution of approximate to 148 mu k and approximate to 42 nW, respectively. With this system, we monitored the energy balance of H2O2 decomposition catalyzed by few self-propelled Pt microrobots. Such a simple microcalorimeter has tremendous potential for chemical and biological research such as monitoring the energy balance of living cells or microorganisms and correlating the energy changes with their activities and status.

Klíčová slova

Droplet-based ultrasensitive microcalorimeter; Differential mode; Energy balance monitoring; Thermodynamics characterization; H2O2 decomposition

Klíčová slova v angličtině

Droplet-based ultrasensitive microcalorimeter; Differential mode; Energy balance monitoring; Thermodynamics characterization; H2O2 decomposition

Autoři

FENG, J.; PODEŠVA, P.; ZHU, H.; PEKÁREK, J.; MAYORGA-MARTINEZ, C.; CHANG, H.; PUMERA, M.; NEUŽIL, P.

Rok RIV

2021

Vydáno

01.06.2020

Nakladatel

ELSEVIER SCIENCE SA

Místo

LAUSANNE

ISSN

0925-4005

Periodikum

SENSORS AND ACTUATORS B-CHEMICAL

Svazek

312

Číslo

NA

Stát

Švýcarská konfederace

Strany od

1

Strany do

7

Strany počet

7

URL

https://www.sciencedirect.com/science/article/pii/S0925400520303154

BibTex

@article{BUT163972,
  author="FENG, J. and PODEŠVA, P. and ZHU, H. and PEKÁREK, J. and MAYORGA-MARTINEZ, C. and CHANG, H. and PUMERA, M. and NEUŽIL, P.",
  title="Droplet-based differential microcalorimeter for real-time energy balance monitoring",
  journal="SENSORS AND ACTUATORS B-CHEMICAL",
  year="2020",
  volume="312",
  number="NA",
  pages="1--7",
  doi="10.1016/j.snb.2020.127967",
  url="https://www.sciencedirect.com/science/article/pii/S0925400520303154"
}