R. Wahab, N. Ahmad, M. Alam, J. Ahmed, Nanorods of ZnO: An effective hydrazine sensor and their chemical properties. Vacuum 165, 290–296 (2019)
Article
ADS
Google Scholar
S.-H. Guo, Z.-Q. Guo, C.-Y. Wang, Y. Shen, W.-H. Zhu, An ultrasensitive fluorescent probe for hydrazine detection and its application in water samples and living cells. Tetrahedron 75, 2642–2646 (2019)
Article
Google Scholar
M. Nemakal, S. Aralekallu, I. Mohammed, S. Swamy, L.K. Sannegowda, Electropolymerized octabenzimidazole phthalocyanine as an amperometric sensor for hydrazine. J. Electroanal. Chem. 839, 238–246 (2019)
Article
Google Scholar
C. Duan, Y. Dong, Q. Sheng, J. Zheng, A high-performance non-enzymatic electrochemical hydrazine sensor based on NiCo2S4 porous sphere. Talanta 198, 23–29 (2019)
Article
Google Scholar
M. George, K.S. Nagaraja, N. Balasubramanian, Spectrophotometric determination of hydrazine. Talanta 75, 27–31 (2008)
Article
Google Scholar
A. Rios, M. Silva, M. Valcarcel, Fluorimetric determination of ammonia, hydrazine and hydroxylamine and their mixtures by differential kinetic methods. Fresenius’ Zeitschrift Für Anal. Chem. 320, 762–768 (1985)
Article
Google Scholar
G.E. Collins, S.L. Rose-Pehrsson, Sensitive, fluorescent detection of hydrazine via derivatization with 2,3-naphthalene dicarboxaldehyde. Anal. Chim. Acta 284, 207–215 (1993)
Article
Google Scholar
G.E. Collins, S. Latturner, S.L. Rose-Pehrsson, Chemiluminescence detection of hydrazine vapor. Talanta 42, 543–551 (1995)
Article
Google Scholar
P. Bravo, F. Isaacs, G. Ramírez, I. Azócar, E. Trollund, M.J. Aguirre, A potentiometric hydrazine sensor: para-Ni-tetraaminophenylporphyrin/Co-cobaltite/SNO2: F modified electrode. J. Coord. Chem. 60, 2499–2507 (2007)
Article
Google Scholar
S. Ganesh, F. Khan, M.K. Ahmed, S.K. Pandey, Potentiometric determination of free acidity in presence of hydrolysable ions and a sequential determination of hydrazine. Talanta 85, 958–963 (2011)
Article
Google Scholar
S. Narasimman, L. Balakrishnan, Z.C. Alex, Highly selective and rapid detection of ethanol using Ni functionalized ZnO nanoflakes coated fiber optic sensor. IEEE Sens. J. 23(1), 344–352 (2023)
Article
ADS
Google Scholar
D. Türkmen, A. Achim Krug, B. Mizaikoff, Monitoring corrosion processes via visible fiber-optic evanescent wave sensor. Chemosensors 8, 76 (2020)
Article
Google Scholar
Z. Zhou, Y. Xu, C. Qiao, L. Liu, Y. Ji, A novel low-cost gas sensor for CO2 detection using polymer-coated fiber Bragg grating. Sens. Actuators B Chem. 332, 129482 (2021)
Article
Google Scholar
J.-F. Masson, Portable and field-deployed surface plasmon resonance and plasmonic sensors. Analyst. 145(11), 3776–3800 (2020)
Article
ADS
Google Scholar
S. Lee, H. Song, H. Ahn, S. Kim, J. Choi, K. Kim, Fiber-optic localized surface plasmon resonance sensors based on nanomaterials. Sensors 21, 819 (2021)
Article
ADS
Google Scholar
S.P. Usha, S.K. Mishra, B.D. Gupta, Fiber optic hydrogen sulfide gas sensors utilizing ZnO thin film/ZnO nanoparticles: a comparison of surface plasmon resonance and lossy mode resonance. Sens. Actuators B Chem. 218, 196–204 (2015)
Article
Google Scholar
H. Miguel, D.V. Ignacio, C.R. Zamarreño, F.J. Arregui, I.R. Matias, Optical fiber refractometers based on lossy mode resonances supported by TiO2 coatings. Appl. Opt. 49, 3980–3985 (2010)
Article
ADS
Google Scholar
C.R. Zamarreño, M. Hernaez, I. Del Villar, I.R. Matias, F.J. Arregui, ITO coated optical fiber refractometers based on resonances in the infrared region. IEEE Sens. J. 10, 365–366 (2010)
Article
ADS
Google Scholar
C.R. Zamarreño, P. Sanchez, M. Hernaez, D. Villar, C. Fernandez-Valdivielso, I.R. Matias, Sensing properties of indium oxide coated optical fiber devices based on lossy mode resonances. IEEE Sens. J. 12, 151–155 (2012)
Article
ADS
Google Scholar
P. Sanchez, C.R. Zamarreño, M. Hernaez, I.R. Matias, F.J. Arregui, Optical fiber refractometers based on Lossy mode resonances by means of SnO2 sputtered coatings. Sens. Actuators B Chem. 202, 154–159 (2014)
Article
Google Scholar
A. Umar, F.A. Harraz, A.A. Ibrahim, T. Almas, R. Kumar, M.S. Al-Assiri, S. Baskoutas, Iron-doped titanium dioxide nanoparticles as potential scaffold for hydrazine chemical sensor applications. Coatings 10, 182 (2020)
Article
Google Scholar
M.M. Rahman, J. Ahmed, A.M. Asiri, K.A. Alamrya, Fabrication of a hydrazine chemical sensor based on facile synthesis of doped NZO nanostructure materials. New J. Chem. 44, 13018 (2020)
Article
Google Scholar
A.A. Ansari, M. Alam, Electrochemical sensitive detection of hydrazine through cobalt-doped cerium oxide nanostructured platform. J. Mater. Sci. Mater. Electron. 32, 13897–13905 (2021)
Article
Google Scholar
A. Pathak, B.D. Gupta, Palladium nanoparticles embedded PPy shell coated CNTs towards a high performance hydrazine detection through optical fiber plasmonic sensor. Sens. Actuators B Chem. 326, 128717 (2021)
Article
Google Scholar
M.N.H. Mia, U. Habiba, M.F. Pervez, H. Kabir, S. Nur, M.F. Hossen, S.K. Sen, M. Khalid Hossain, M.A. Iftekhar, M.M. Mahbubur Rahman, Investigation of aluminum doping on structural and optical characteristics of sol–gel assisted spin coated nano structured zinc oxide thin flms. Appl. Phys. A. 126, 162 (2020)
Article
ADS
Google Scholar
N. Srinatha, P. Raghu, H.M. Mahesh, A. Madhu, S. Hussain, S. Dam, M.R. Suresh Kumar, B. Angadi, Study on the effect of Ni co-doping on structural, micro-structural and optical properties of transparent AZO thin films. Opt. Mater. 113, 110872 (2021)
Article
Google Scholar
A. Prasanth, S.R. Meher, Z.C. Alex, Metal oxide thin films coated evanescent wave based fiber optic VOC sensor. Sens. Actuator A Phys. 338, 113459 (2022)
Article
Google Scholar
F.J. Arregui, I.D. Villar, J.M. Corres, J. Goicoechea, C.R. Zamarreño, C. Elosua, M. Hernaez, P.J. Rivero, A.B. Socorro, A. Urrutia, Fiber-optic lossy mode resonance sensors. Procedia Eng. 87, 3–8 (2014)
Article
Google Scholar
E.I. Golant, K.M. Golant, Fields and modes in thin film coated optical waveguides. in Proceedings of the 2019 PhotonIcs & Electromagnetics Research Symposium-Spring (PIERS-Spring), Rome, Italy, 17–20 June 2019; pp. 725–732.
E.I. Golant, A.B. Pashkovskii, K.M. Golant, Lossy mode resonance in an etched-out optical fiber taper covered by a thin ITO layer. Appl. Opt. 59, 9254–9258 (2020)
Article
ADS
Google Scholar
I.D. Villar, C.R. Zamarreño, M. Hernaez, F.J. Arregui, I.R. Matias, Lossy mode resonance generation with indium-tin-oxide-coated optical fibers for sensing applications. J. Lightwave Technol. 28, 111–117 (2010)
Article
ADS
Google Scholar
S.P. Usha, B.D. Gupta, Performance analysis of zinc oxide-implemented lossy mode resonance-based optical fiber refractive index sensor utilizing thin film/nanostructure. Appl. Opt. 56, 5716–5725 (2017)
Article
ADS
Google Scholar
S. Narasimman, L. Balakrishnan, Z.C. Alex, Clad-modified fiber optic ammonia sensor based on Cu functionalized ZnO nanoflakes. Sens. Actuators A Phys. 316, 112374 (2020)
Article
Google Scholar
S. Narasimman, L. Balakrishnan, Z.C. Alex, Fiber-optic ammonia sensor based on amine functionalized ZnO nanoflakes. IEEE Sens. J. 18(1), 201–208 (2017)
Article
ADS
Google Scholar
M.M. Rahman, M.M. Alam, A.M. Asiri, Selective hydrazine sensor fabrication with facile low-dimensional Fe2O3/CeO2 nanocubes. New J. Chem. 42, 10263–10270 (2018)
Article
Google Scholar
A. Umar, S.H. Kim, R. Kumar, M.S. Al-Assiri, A.E. Al-Salami, A.A. Ibrahim, S. Baskoutas, In-doped ZnO hexagonal stepped nanorods and nanodisks as potential scaffold for highly-sensitive phenyl hydrazine chemical sensors. Materials 10(11), 1337 (2017)
Article
ADS
Google Scholar
M. Jang, D. Jung, J. Lee, S.M. Lee, A. Lee, S. Yim, K.S. An, PVDF-stimulated surface engineering in ZnO for highly sensitive and water-stable hydrazine sensors. Appl. Surf. Sci. 585, 152747 (2022)
Article
Google Scholar
A. Mousavi-Majd, S. Ghasemi, S.R. Hosseini, Zeolitic imidazolate framework derived porous ZnO/Co3O4 incorporated with gold nanoparticles as ternary nanohybrid for determination of hydrazine. J. Alloys Compd. 896, 162922 (2022)
Article
Google Scholar
留言 (0)