Details

Title

Very Sensitive Optical System with the Concentration and Decomposition Unit for Explosive Trace Detection

Journal title

Metrology and Measurement Systems

Yearbook

2015

Volume

vol. 22

Numer

No 1

Publication authors

Divisions of PAS

Nauki Techniczne

Publisher

Polish Academy of Sciences Committee on Metrology and Scientific Instrumentation

Date

2015[2015.01.01 AD - 2015.12.31 AD]

Identifier

ISSN 0860-8229

References

Triki (2008), Cavity - enhanced absorption spectroscopy with a red LED source for NOx trace analysis, Appl Phys, 41, 195, doi.org/10.1007/s00340-008-2958-x ; Akamatsu (2013), NO and NO sensing properties of WO and Co based gas sensor, Sensors, 10, 12467, doi.org/10.3390/s130912467 ; Lee (2008), Bias modulated highly sensitive NO gas detection using carbon nanotubes, Chem, 21, 129. ; Fine (2010), Metal Oxide Semi - Conductor Gas Sensors in Environmental Monitoring, Sensors, 4, 5469, doi.org/10.3390/s100605469 ; Mizutani (2005), Improvement of electrochemical NO sensor by use of carbon - fluorocarbon gas permeable electrode, Chem, 23, 108. ; Bielecki (2012), Sensors and systems for the detection of explosive devices, Metrol Meas Syst, 1, 3. ; Kosterev (2005), Applications of quartz tuning fork in spectroscopic gas sensing, Rev Sci Instrum, 32, 043105. ; Hargrove (2006), Cavity ringdown spectroscopy of ambient NO with quantification and elimination of interferences, Environ Sci Technol, 38, 7868, doi.org/10.1021/es061287o ; Jasinski (2003), Nanocrystalline undoped ceria oxygen sensor, Chem, 11, 73. ; Hamilton (2011), A quantum cascade laser - based optical feedback cavity - enhanced absorption spectrometer for the simultaneous measurement of CH and O in air, Appl Phys, 42, 879, doi.org/10.1007/s00340-010-4259-4 ; Pan (2015), A fast - response / recovery ZnO hierarchical nanostructure based gas sensor with ultra - high room - temperature output response Available online th September, Chem, 13, 206. ; Singh (2007), Sensors - An effective approach for the detection of explosives, Hazard Mater, 45, 144. ; Yi (2011), Application of a broadband blue laser diode to trace NO detection using off - beam quartz - enhanced photoacoustic spectroscopy, Opt Lett, 34, 481, doi.org/10.1364/OL.36.000481 ; Hagleitner (2002), CMOS single - chip gas detection system comprising capacitive , calorimetric and mass - sensitive microsensors Solid St, IEEE Circ, 16, 1867, doi.org/10.1109/JSSC.2002.804359 ; Castellanos (2009), Patricia Modification of a commercial cavity ring - down spectroscopy NO detector for enhanced sensitivity, Rev Sci Instrum, 39, 113107. ; Oxley (1995), Explosives detection : potential problems, Proc SPIE, 2, 2511. ; Sharma (2013), Enhanced response characteristics of SnO thin film based NO gas sensor integrated with nanoscaled metal oxide clusters, Chem, 14, 181. ; Patimisco (2014), Quartz - Enhanced Photoacoustic Spectroscopy, Review Sensors, 33, 6165, doi.org/10.3390/s140406165 ; Wang (2013), A La based electrochemical sensor using nano - structured NiO sensing electrode for detection of NO, Mater Lett, 25, 109. ; Oprea (2006), Copper phthalocyanine suspended gate field effect transistors for NO detection, Chem, 27, 249. ; Ederth (2006), Comparison of classical and fluctuation - enhanced gas sensing with PdxWO nanoparticle films, Chem, 15, 113. ; Thai (2011), Nanotechnology enables wireless gas sensing, IEEE Microw Mag, 19, 84, doi.org/10.1109/MMM.2011.940594 ; Navale (2014), Room temperature NO sensing properties of polythiophene films, Synthetic Met, 18, 195. ; Keefe (1988), Cavity ring - down optical spectrometer for absorption measurements using pulsed laser source, Rev Sci Instrum, 36, 59. ; Andringa (2013), Real - time NO detection at ppb level with ZnO field - effect transistors, Chem, 28, 181. ; Stacewicz (2012), Cavity Ring Down Spectroscopy : detection of trace amounts of substance, Opto Electron Rev, 44, 53. ; Senesac (2008), Nanosensors for trace explosive detection, Materials Today, 47, 28, doi.org/10.1016/S1369-7021(08)70017-8 ; Zheng (2015), Ppb - level QEPAS NO sensor by use of electrical modulation cancellation method with a high power blue LED, Chem, 35, 208. ; Wang (2013), An amperometric NO sensor based on La electrolyte and nano - structured CuO sensing electrode, J Hazard Mater, 24, 262. ; Williams (1999), Semiconducting oxides as gas - sensitive resistors, Chem, 5, 1. ; Romanini (1997), Cavity ringdown spectroscopy : broad band absolute absorption measurements, Chem Phys Lett, 37, 546, doi.org/10.1016/S0009-2614(97)00407-7 ; Cantalini (1996), Cross sensitivity and stability of NO sensors from WO thin film, Chem, 6, 112. ; Kosterev (2002), Quartz - enhanced photoacoustic spectroscopy, Opt Lett, 31, 1902, doi.org/10.1364/OL.27.001902 ; Zeng (2012), NO - sensing properties of porous WO gas sensor based on anodized sputtered tungsten thin film, Chem, 9, 161. ; Navale (2014), Highly selective and sensitive room temperature NO gas sensor based on polypyrrole thin films, Synthetic Met, 17, 189. ; Jasinski (2006), Solid - state electrochemical gas sensors, Materials Science Poland, 22, 269. ; Karaduman (2014), UV light activated gas sensor for NO detection, Mat Sci Semicon Proc, 12, 28. ; Liu (2012), A survey on gas sensing technology, Sensors, 3, 9635, doi.org/10.3390/s120709635 ; Sayago (2008), Carbon nanotube networks as gas sensors for NO detection, Talanta, 20, 758, doi.org/10.1016/j.talanta.2008.07.025 ; Wu (2014), Simultaneous monitoring of temporal profiles of NO , NO and by incoherent broadband cavity enhanced absorption spectroscopy for atmospheric applications, J Quant Spectrosc Ra, 43, 133. ; Shieh (2002), WO and Ti - O thin - film gas sensors prepared by sol - gel dip - coating, Chem, 7, 75.

DOI

10.1515/mms-2015-0005

×