Size Matters: Problems and Advantages Associated with Highly Miniaturized Sensors

There is no doubt that the recent advances in nanotechnology have made it possible to realize a great variety of new sensors with signal transduction mechanisms utilizing physical phenomena at the nanoscale. Some examples are conductivity measurements in nanowires, deflection of cantilevers and spec...

Full description

Bibliographic Details
Main Author: Andreas B. Dahlin
Format: Article
Language:English
Published: MDPI AG 2012-03-01
Series:Sensors
Subjects:
Online Access:http://www.mdpi.com/1424-8220/12/3/3018/
id doaj-f4bd7a3d3e6341a09a8c976621853e9f
record_format Article
spelling doaj-f4bd7a3d3e6341a09a8c976621853e9f2020-11-24T23:39:30ZengMDPI AGSensors1424-82202012-03-011233018303610.3390/s120303018Size Matters: Problems and Advantages Associated with Highly Miniaturized SensorsAndreas B. DahlinThere is no doubt that the recent advances in nanotechnology have made it possible to realize a great variety of new sensors with signal transduction mechanisms utilizing physical phenomena at the nanoscale. Some examples are conductivity measurements in nanowires, deflection of cantilevers and spectroscopy of plasmonic nanoparticles. The fact that these techniques are based on the special properties of nanostructural entities provides for extreme sensor miniaturization since a single structural unit often can be used as transducer. This review discusses the advantages and problems with such small sensors, with focus on biosensing applications and label-free real-time analysis of liquid samples. Many aspects of sensor design are considered, such as thermodynamic and diffusion aspects on binding kinetics as well as multiplexing and noise issues. Still, all issues discussed are generic in the sense that the conclusions apply to practically all types of surface sensitive techniques. As a counterweight to the current research trend, it is argued that in many real world applications, better performance is achieved if the active sensor is larger than that in typical nanosensors. Although there are certain specific sensing applications where nanoscale transducers are necessary, it is argued herein that this represents a relatively rare situation. Instead, it is suggested that sensing on the microscale often offers a good compromise between utilizing some possible advantages of miniaturization while avoiding the complications. This means that ensemble measurements on multiple nanoscale sensors are preferable instead of utilizing a single transducer entity.http://www.mdpi.com/1424-8220/12/3/3018/sensorbiosensorsizeminiaturizationsurfacenanomicro
collection DOAJ
language English
format Article
sources DOAJ
author Andreas B. Dahlin
spellingShingle Andreas B. Dahlin
Size Matters: Problems and Advantages Associated with Highly Miniaturized Sensors
Sensors
sensor
biosensor
size
miniaturization
surface
nano
micro
author_facet Andreas B. Dahlin
author_sort Andreas B. Dahlin
title Size Matters: Problems and Advantages Associated with Highly Miniaturized Sensors
title_short Size Matters: Problems and Advantages Associated with Highly Miniaturized Sensors
title_full Size Matters: Problems and Advantages Associated with Highly Miniaturized Sensors
title_fullStr Size Matters: Problems and Advantages Associated with Highly Miniaturized Sensors
title_full_unstemmed Size Matters: Problems and Advantages Associated with Highly Miniaturized Sensors
title_sort size matters: problems and advantages associated with highly miniaturized sensors
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2012-03-01
description There is no doubt that the recent advances in nanotechnology have made it possible to realize a great variety of new sensors with signal transduction mechanisms utilizing physical phenomena at the nanoscale. Some examples are conductivity measurements in nanowires, deflection of cantilevers and spectroscopy of plasmonic nanoparticles. The fact that these techniques are based on the special properties of nanostructural entities provides for extreme sensor miniaturization since a single structural unit often can be used as transducer. This review discusses the advantages and problems with such small sensors, with focus on biosensing applications and label-free real-time analysis of liquid samples. Many aspects of sensor design are considered, such as thermodynamic and diffusion aspects on binding kinetics as well as multiplexing and noise issues. Still, all issues discussed are generic in the sense that the conclusions apply to practically all types of surface sensitive techniques. As a counterweight to the current research trend, it is argued that in many real world applications, better performance is achieved if the active sensor is larger than that in typical nanosensors. Although there are certain specific sensing applications where nanoscale transducers are necessary, it is argued herein that this represents a relatively rare situation. Instead, it is suggested that sensing on the microscale often offers a good compromise between utilizing some possible advantages of miniaturization while avoiding the complications. This means that ensemble measurements on multiple nanoscale sensors are preferable instead of utilizing a single transducer entity.
topic sensor
biosensor
size
miniaturization
surface
nano
micro
url http://www.mdpi.com/1424-8220/12/3/3018/
work_keys_str_mv AT andreasbdahlin sizemattersproblemsandadvantagesassociatedwithhighlyminiaturizedsensors
_version_ 1725513172171882496