Fabrication, structure and hydrogen-gas-sensing properties of multiple networked GaN nanostructure gas sensors

The controlled synthesis of nanostructures with different shapes and morphologies has attracted considerable interest because the sensing properties of nanostructures depend on their structure, shape, phase, size, and size distribution, as well as their composition. This paper compares the responses...

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Published in	Journal of the Korean Physical Society Vol. 66; no. 7; pp. 1062 - 1066
Main Authors	Park, Sunghoon, Kim, Soohyun, Lee, Chongmu
Format	Journal Article
Language	English
Published	Seoul The Korean Physical Society 01.04.2015 한국물리학회
Subjects	Mathematical and Computational Physics Particle and Nuclear Physics Physics Physics and Astronomy Theoretical 물리학 Nanostructure Gas sensor GaN Hydrogen
Online Access	Get full text
ISSN	0374-4884 1976-8524
DOI	10.3938/jkps.66.1062

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Abstract	The controlled synthesis of nanostructures with different shapes and morphologies has attracted considerable interest because the sensing properties of nanostructures depend on their structure, shape, phase, size, and size distribution, as well as their composition. This paper compares the responses of GaN nanostructures with different morphologies to hydrogen. The underlying mechanism for the hydrogen gas sensing of the multiple networked GaN nanowire sensor can be explained based on the well-established surface depletion model. On the other hand, the difference between two different samples, the GaN nanostructure sample synthesized at 1,100 °C and that synthesized at 1,000 °C, could be explained as follows: The major process behind the interaction between the nanostructures and hydrogen is the chemisorption of the dissociated hydrogen on the GaN surface. The chemisorption creates an electron accumulation layer on the GaN surface that enhances its electrical conductance. The GaN nanostructure sample synthesized at 1,100 °C with a higher ammonia flow rate showed a higher response to H 2 gas than that synthesized at 1,000 °C with a lower ammonia flow rate, which might be attributed to the higher surface-to-volume ratio of the former.
AbstractList	The controlled synthesis of nanostructures with different shapes and morphologies has attractedconsiderable interest because the sensing properties of nanostructures depend on their structure,shape, phase, size, and size distribution, as well as their composition. This paper compares theresponses of GaN nanostructures with different morphologies to hydrogen. The underlying mechanismfor the hydrogen gas sensing of the multiple networked GaN nanowire sensor can be explainedbased on the well-established surface depletion model. On the other hand, the difference betweentwo different samples, the GaN nanostructure sample synthesized at 1,100◦C and that synthesizedat 1,000◦C, could be explained as follows: The major process behind the interaction between thenanostructures and hydrogen is the chemisorption of the dissociated hydrogen on the GaN surface. The chemisorption creates an electron accumulation layer on the GaN surface that enhances itselectrical conductance. The GaN nanostructure sample synthesized at 1,100◦C with a higher ammoniaflow rate showed a higher response to H2 gas than that synthesized at 1,000◦C with a lowerammonia flow rate, which might be attributed to the higher surface-to-volume ratio of the former. KCI Citation Count: 1 The controlled synthesis of nanostructures with different shapes and morphologies has attracted considerable interest because the sensing properties of nanostructures depend on their structure, shape, phase, size, and size distribution, as well as their composition. This paper compares the responses of GaN nanostructures with different morphologies to hydrogen. The underlying mechanism for the hydrogen gas sensing of the multiple networked GaN nanowire sensor can be explained based on the well-established surface depletion model. On the other hand, the difference between two different samples, the GaN nanostructure sample synthesized at 1,100 °C and that synthesized at 1,000 °C, could be explained as follows: The major process behind the interaction between the nanostructures and hydrogen is the chemisorption of the dissociated hydrogen on the GaN surface. The chemisorption creates an electron accumulation layer on the GaN surface that enhances its electrical conductance. The GaN nanostructure sample synthesized at 1,100 °C with a higher ammonia flow rate showed a higher response to H 2 gas than that synthesized at 1,000 °C with a lower ammonia flow rate, which might be attributed to the higher surface-to-volume ratio of the former.
Author	Lee, Chongmu Kim, Soohyun Park, Sunghoon
Author_xml	– sequence: 1 givenname: Sunghoon surname: Park fullname: Park, Sunghoon organization: Department of Materials Science and Engineering, Inha University – sequence: 2 givenname: Soohyun surname: Kim fullname: Kim, Soohyun organization: Department of Materials Science and Engineering, Inha University – sequence: 3 givenname: Chongmu surname: Lee fullname: Lee, Chongmu email: cmlee@inha.ac.kr organization: Department of Materials Science and Engineering, Inha University
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Title	Fabrication, structure and hydrogen-gas-sensing properties of multiple networked GaN nanostructure gas sensors
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