Modified metal oxide gas sensors for the detection of clandestine chemistry locations

Clandestine laboratories are locations where chemistry is carried out in secret, often with the intent to produce illegal drugs or other controlled substances. These laboratories are unregulated and not maintained to a good laboratory standard, presenting a risk to first responders, bystanders and t...

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Main Author: Pugh, D. C.
Published: University College London (University of London) 2018
Online Access:http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.747365
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spelling ndltd-bl.uk-oai-ethos.bl.uk-7473652018-08-21T03:23:56ZModified metal oxide gas sensors for the detection of clandestine chemistry locationsPugh, D. C.2018Clandestine laboratories are locations where chemistry is carried out in secret, often with the intent to produce illegal drugs or other controlled substances. These laboratories are unregulated and not maintained to a good laboratory standard, presenting a risk to first responders, bystanders and the environment. Electronic noses based on metal oxide semiconducting (MOS) gas sensors present a potential technology to create devices for the detection of clandestine activity. A range of sensors based on zinc oxide, chromium titanate and vanadium pentoxide have been manufactured and modified using zeolite material and metal ion doping. Sensor fabrication took place using a commercially available screen printer, a 3 x 3 mm alumina substrate containing interdigitated electrodes and a platinum heater track. Allmaterials were modified with the protonated forms of zeolite beta, Y, mordenite and ZSM5, by incorporating these materials into the metal oxide to make up 30 % of the total ink. Zinc oxide was also modified by indium doping; doping levels were set at 0.2, 0.5, 1 and 3-mol % indium. These materials were synthesised using a co-precipitation method. Sensors were exposed to a range of gases at operating temperatures between 250 and 500°C and concentrations between 50 ppb and 80 ppm. All tests were conducted on an in house testing rig, consisting of a 12-port sensing chamber, four mass flow controllers, six solenoid vales and supplies of compressed air and analyte gas. Modification of sensors was found to improve their responsiveness, compared to the control sensors, in almost all cases. This is due to a combination of surface area enhancements, increased adsorption of material and a more accessible microstructure. Machine learning techniques were applied to the sensor data to correctly classify the class of gas observed and to assess the overall sensor performance of each material. A high level of accuracy was achieved in determining the class of gas observed.University College London (University of London)http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.747365http://discovery.ucl.ac.uk/10043630/Electronic Thesis or Dissertation
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description Clandestine laboratories are locations where chemistry is carried out in secret, often with the intent to produce illegal drugs or other controlled substances. These laboratories are unregulated and not maintained to a good laboratory standard, presenting a risk to first responders, bystanders and the environment. Electronic noses based on metal oxide semiconducting (MOS) gas sensors present a potential technology to create devices for the detection of clandestine activity. A range of sensors based on zinc oxide, chromium titanate and vanadium pentoxide have been manufactured and modified using zeolite material and metal ion doping. Sensor fabrication took place using a commercially available screen printer, a 3 x 3 mm alumina substrate containing interdigitated electrodes and a platinum heater track. Allmaterials were modified with the protonated forms of zeolite beta, Y, mordenite and ZSM5, by incorporating these materials into the metal oxide to make up 30 % of the total ink. Zinc oxide was also modified by indium doping; doping levels were set at 0.2, 0.5, 1 and 3-mol % indium. These materials were synthesised using a co-precipitation method. Sensors were exposed to a range of gases at operating temperatures between 250 and 500°C and concentrations between 50 ppb and 80 ppm. All tests were conducted on an in house testing rig, consisting of a 12-port sensing chamber, four mass flow controllers, six solenoid vales and supplies of compressed air and analyte gas. Modification of sensors was found to improve their responsiveness, compared to the control sensors, in almost all cases. This is due to a combination of surface area enhancements, increased adsorption of material and a more accessible microstructure. Machine learning techniques were applied to the sensor data to correctly classify the class of gas observed and to assess the overall sensor performance of each material. A high level of accuracy was achieved in determining the class of gas observed.
author Pugh, D. C.
spellingShingle Pugh, D. C.
Modified metal oxide gas sensors for the detection of clandestine chemistry locations
author_facet Pugh, D. C.
author_sort Pugh, D. C.
title Modified metal oxide gas sensors for the detection of clandestine chemistry locations
title_short Modified metal oxide gas sensors for the detection of clandestine chemistry locations
title_full Modified metal oxide gas sensors for the detection of clandestine chemistry locations
title_fullStr Modified metal oxide gas sensors for the detection of clandestine chemistry locations
title_full_unstemmed Modified metal oxide gas sensors for the detection of clandestine chemistry locations
title_sort modified metal oxide gas sensors for the detection of clandestine chemistry locations
publisher University College London (University of London)
publishDate 2018
url http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.747365
work_keys_str_mv AT pughdc modifiedmetaloxidegassensorsforthedetectionofclandestinechemistrylocations
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