Title

Current Fluctuation Measurements of Amperometric Gas Sensors Constructed with Three Different Technology Procedures

Journal title

Metrology and Measurement Systems

Yearbook

2016

Volume

vol. 23

Issue

No 4

Authors

Sedlak, Petr ; Kubersky, Petr ; Skarvada, Pavel ; Hamacek, Ales ; Sedlakova, Vlasta ; Majzner, Jiri ; Nespurek, Stanislav ; Sikula, Josef

Keywords

current fluctuations ; noise measurement ; amperometric sensor ; solid polymer electrolyte

Divisions of PAS

Nauki Techniczne

Coverage

531-543

Publisher

Polish Academy of Sciences Committee on Metrology and Scientific Instrumentation

Date

2016.12.15

Type

Artykuły / Articles

Identifier

DOI: 10.1515/mms-2016-0042 ; ISSN 2080-9050, e-ISSN 2300-1941

Source

Metrology and Measurement Systems; 2016; vol. 23; No 4; 531-543

References

Nadherna (2012), A planar , solid - state amperometric sensor for nitrogen dioxide , employing an ionic liquid electrolyte contained in a polymeric matrix, Sens Chem, 40, 161. ; Hassibi (2004), Comprehensive study of noise processes in electrode electrolyte interfaces, Appl Phys, 33, 1074, doi.org/10.1063/1.1755429 ; Sedlakova (2012), Evaluation of piezoresistive ceramic pressure sensors using noise measurements, Inf MIDEM, 15, 109. ; Silvester (2011), Recent advances in the use of ionic liquids for electrochemical sensing, Analyst, 5, 136. ; Smulko (1998), Digital measurement system for electrochemical noise of, Polish Journal Chemistry, 39, 1237. ; Contaret (2011), Physical - based characterization of low frequency responses in metal - oxide gas sensors, IEEE Sensors IEEE Sensors, 24, 141. ; Ayhan (2013), Fluctuation enhanced sensing ( FES ) with a nanostructured , semiconducting metal oxide film for gas detection and classification, Sens Chem, 21, 188. ; Buzzeo (2004), Use of Room Temperature Ionic Liquids in Gas Sensor Design, Anal Chem, 4, 76. ; Sedlakova (2012), Noise in Submicron Metal - Oxide - Semiconductor Field Effect Transistors : Lateral Electron Density Distribution and Active Trap Position, Appl Phys, 37, 51. ; Macku (2015), Analytical fluctuation enhanced sensing by resistive gas sensors, Sens Chem, 22, 213. ; Kubersky (2015), Quantitative fluctuation - enhanced sensing in amperometric NO sensors, Chem Phys, 6, 456. ; Schmera (2002), Fluctuation - enhanced gas sensing by surface acoustic wave devices, Fluct Noise Lett, 19, 02. ; Singh (2011), Stochastic Amperometric Fluctuations as a Probe for Dynamic Adsorption in Nanofluidic Electrochemical Systems J, Am Chem Soc, 12, 133. ; Prasek (2012), Optimization of planar three - electrode systems for redox system detection, Int J Electrochem Sci, 29, 1785. ; Kubersky (2013), Effect of the geometry of a working electrode on the behavior of a planar amperometric NO sensor based on solid polymer electrolyte, Sens Chem, 8, 187. ; Sohn (2013), A Unified Potentiostat for Electrochemical Glucose Sensors, Trans Electr Electron Mater, 36, 273, doi.org/10.4313/TEEM.2013.14.5.273 ; Santo Zarnik (2013), Comparison of the Intrinsic Characteristics of LTCC and Silicon Pressure Sensors by Means of f Noise Measurements, Radioengineering, 17, 227. ; Djurić (2002), Adsorption - desorption noise in micromechanical resonant structures Actuators, Sens Phys, 26, 244, doi.org/10.1016/S0924-4247(01)00834-2 ; Smulko (2005), Gas sensing by thermoelectric voltage fluctuations in SnO nanoparticle films, Sens Chem, 23, 106. ; Ahmadi (2009), Current - Mirror - Based Potentiostats for Three - Electrode Amperometric Electrochemical Sensors IEEE Trans, Circuits Syst Regul Pap, 27, 56. ; Katelhon (2014), Noise Phenomena Caused by Reversible Adsorption in Nanoscale Electrochemical Devices ACS, Nano, 38, 4924. ; Zarnik (2013), Estimation of the longterm stability of piezoresistive LTCC pressure sensors by means of low - frequency noise measurements Actuators, Sens Phys, 16, 199. ; Punter (2013), Bioelectronics for Amperometric Biosensors State of the Art in Biosensors General Aspects ed, InTech, 35. ; Rehman (2012), Ionic liquids as green solvents and electrolytes for robust chemical sensor development, Acc Chem Res, 13, 45. ; Stetter (2008), Amperometric gas sensors a review, Chem Rev, 3, 352, doi.org/10.1021/cr0681039 ; Rogers (2010), Amperometric Gas Detection Using Room Temperature Ionic Liquid Solvents, ECS Trans, 11, 473, doi.org/10.1149/1.3484806 ; Armand (2009), Ionic - liquid materials for the electrochemical challenges of the future, Nat Mater, 10, 621, doi.org/10.1038/nmat2448 ; Kubersky (2015), Towards a fully printed electrochemical NO sensor on a flexible substrate using ionic liquid based polymer electrolyte, Sens Chem, 9, 209. ; Xiong (2014), Amperometric Gas detection : A, Review J Electrochem Sci, 1, 7152. ; Sedlak (2012), Adsorption - desorption noise in QCM gas sensors, Sens Chem, 25, 166. ; Kish (2005), Detecting harmful gases using fluctuation - enhanced sensing with Taguchi sensors, IEEE Sens J, 20, 671, doi.org/10.1109/JSEN.2005.851018