An integration of zinc oxide (ZnO) nanowires (NWs) onto carbon microfibers (mu C) using electrochemical deposition and thermal oxidation approach has been developed and used as a versatile resistive (oxidizing and reducing) gas sensor This architecture is attractive because it allows mechanical flexibility low cost and large-area fabrication Being structured at both microscale and nanoscale the ZnO nanowires-carbon microfiber (ZnO-mu C) sensor possesses a greater surface area giving rise to a strong and rapid response/recovery time Additionally the ZnO-mu C sensor is simple to manufacture has a very low power consumption (less than 06 mu W) and is prepared without any lithographic process The sensor exhibits excellent oxygen (down to 2 ppm) and hydrogen (down to 4 ppm) sensing characteristics showing a fast response on gas exposure (less than 10 s) and very good reversibility Furthermore the carbon microfiber is as flexible as a fabric is thus the ZnO-mu C sensor could also be used in applications where flexibility is required This architecture can also be expanded to other nanowire materials (CuO Fe(2)O(3) etc) widening the range of detected gases We therefore believe that the integration of nanowires with carbon microfibers has the potential for being the next generation of simple and low cost sensor devices (C) 2010 Elsevier B V All rights reserved
Integrated zinc oxide nanowires/carbon microfiber gas sensors
Tonezzer M;
2010
Abstract
An integration of zinc oxide (ZnO) nanowires (NWs) onto carbon microfibers (mu C) using electrochemical deposition and thermal oxidation approach has been developed and used as a versatile resistive (oxidizing and reducing) gas sensor This architecture is attractive because it allows mechanical flexibility low cost and large-area fabrication Being structured at both microscale and nanoscale the ZnO nanowires-carbon microfiber (ZnO-mu C) sensor possesses a greater surface area giving rise to a strong and rapid response/recovery time Additionally the ZnO-mu C sensor is simple to manufacture has a very low power consumption (less than 06 mu W) and is prepared without any lithographic process The sensor exhibits excellent oxygen (down to 2 ppm) and hydrogen (down to 4 ppm) sensing characteristics showing a fast response on gas exposure (less than 10 s) and very good reversibility Furthermore the carbon microfiber is as flexible as a fabric is thus the ZnO-mu C sensor could also be used in applications where flexibility is required This architecture can also be expanded to other nanowire materials (CuO Fe(2)O(3) etc) widening the range of detected gases We therefore believe that the integration of nanowires with carbon microfibers has the potential for being the next generation of simple and low cost sensor devices (C) 2010 Elsevier B V All rights reservedI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.