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DETECTION OF CIGARETTE SMOKE USING A FIBER MEMBRANE FILMED WITH CARBON NANOPARTICLES AND A FRACTAL CURRENT LAW

ABSTRACT
Cigarette smoke will cause irreversible damage to human health and living environment. It is especially important to accurately detect and effectively prevent cigarette smoke. This paper fabricates a fiber membrane filmed with carbon nanopowders as a smoke sensor. The experiment reveals that the fabricated membrane is sensitive to the smoke, two laws are proposed to model the current change of the sensor. Fractal calculus is used to exactly predict the current property at the initial stage, and a fractal modification of the current law is proposed. The present technology provides an economic way to mass-production of smoke sensors.
KEYWORDS
PAPER SUBMITTED: 2019-04-20
PAPER REVISED: 2019-09-21
PAPER ACCEPTED: 2019-09-22
PUBLISHED ONLINE: 2020-06-21
DOI REFERENCE: https://doi.org/10.2298/TSCI2004469X
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2020, VOLUME 24, ISSUE 4, PAGES [2469 - 2474]
REFERENCES
  1. Cheng, C. Y., et al. Detection of Cigarette Smoke Using a Surface-Acoustic-Wave Gas Sensor with Non-Polymer-Based Oxidized Hollow Mesoporous Carbon Nanospheres, Micromachines, 10 (2019), 4, ID 276
  2. Cheng, C. Y., et al., Detection of Third-Hand Smoke on Clothing Fibers with a Surface Acoustic Wave Gas Sensor, Biomicrofluidics, 10 (2016), 1, ID 011907
  3. Skinner, A. L., et al., StopWatch: The Preliminary Evaluation of a Smartwatch-Based System for Passive Detection of Cigarette Smoking, Nicotine & Tobacco Research, 21 (2019), 2, pp. 257-261
  4. He, Y. B., et al., Research on Multi-Sensor Smoke Detection Method for Aircraft Cargo Compartment, China Safety Science Journal, 29 (2019), 1, pp. 43-48
  5. Zhang, Y. F., et al., Fabrication of Robust and Repairable Superhydrophobic Coatings by an Immersion Method, Chemical Engineering Journal, 369 (2019), Aug., pp. 1-7
  6. He, J. H., Ji, F. Y., Taylor Series Solution for Lane-Emden Equation, Journal of Mathematical Chemistry, 57 (2019), 8, pp. 1932-1934
  7. He, J. H., Sun, C., A Variational Principle for a Thin Film Equation, Journal of Mathematical Chemistry. 57 (2019), 9, pp. 2075-2081
  8. He, J. H., Hamilton's Principle for Dynamical Elasticity, Applied Mathematics Letters, 72 (2017), Oct., pp. 65-69
  9. He, J. H., Variational Principle for the Generalized KdV Burgers Equation with Fractal Derivatives for Shallow Water Waves J. Appl. Comput. Mech., 6 (2020), 4, pp. 735 740
  10. He, J. H., A Modified Li-He's Variational Principle for Plasma, International Journal of Numerical Methods for Heat and Fluid Flow, On-line first, doi.org/10.1108/HFF-06-2019-0523, 2019
  11. He, J. H. Lagrange Crisis and Generalized Variational Principle for 3D unsteady flow, International Journal of Numerical Methods for Heat and Fluid Flow, On-line first, doi.org/10.1108/HFF-07-2019-0577, 2019
  12. Anjum, N., He, J. H., Laplace Transform: Making the Variational Iteration Method Easier, Applied Mathematics Letters, 92 (2019), June, pp. 134-138
  13. He, J. H., et al., Variational Iteration Method for Bratu-Like Equation Arising in Electrospinning, Carbohydrate Polymers, 105 (2014), May, pp. 229-230
  14. Wu, Y., He, J. H., Homotopy Perturbation Method for Nonlinear Oscillators with Coordinate Dependent Mass, Results in Physics, 10 (2018), Sept., pp. 270-271
  15. Liu, Z. J., et al., Hybridization of Homotopy Perturbation Method and Laplace Transformation for the Partial Differential Equations, Thermal Science, 21 (2017), 4, pp. 1843-1846
  16. Adamu, M. Y., Ogenyi, P., New Approach to Parameterized Homotopy Perturbation Method, Thermal Science, 22 (2018), 4, pp. 1865-1870
  17. He, J. H., The Simpler, The Better: Analytical Methods For Nonlinear Oscillators And Fractional Oscillators, Journal of Low Frequency Noise, Vibration and Active Control, 38 (2019), 3-4, pp. 1252-1260
  18. He, J. H. The Simplest Approach to Nonlinear Oscillators, Results in Physics, 15 (2019), 102546
  19. He, J. H., A Tutorial Review on Fractal Spacetime and Fractional Calculus. International Journal of Theoretical Physics, 53 (2014), 11, pp. 3698-3718
  20. He, J. H. Fractal Calculus And Its Geometrical Explanation, Results in Physics, 10 (2018), Sept., pp. 272-276
  21. Li, X. X., et al., A Fractal Modification of the Surface Coverage Model for an Electrochemical Arsenic sensor, Electrochimica Acta, 296 (2019), Feb., pp. 491-493
  22. Liu, H. Y., Liu, et al., A Fractal Rate Model for Adsorption Kinetics at Solid/Solution Interface, Thermal Science, 23 (2019), 4, pp. 2477-2480
  23. Wang, Y., Deng, Q. G., Fractal Derivative Model For Tsunami Travelling, Fractals, 27 (2019), 1, 1950017
  24. Wang, Y., et al., A Variational Formulation for Anisotropic Wave Traveling in a Porous Medium, Fractals, 27 (2019), 4, 1950047
  25. Wang, Y., et al., A Fractal Derivative Model for Snow's Thermal Insulation Property, Thermal Science, 23 (2019), 4, pp. 2351-2354
  26. He, J. H., Ji, F. Y. Two-scale Mathematics and Fractional Calculus for Thermodynamics, Thermal Science, 23 (2019), 4, pp. 2131-2133
  27. Ain, Q. T., He, J. H., On Two-Scale Dimension and Its Applications, Thermal Science, 23 (2019), 3B, pp. 1707-1712
  28. Zhou, C. J., et al., Silkworm-Based Silk Fibers by Electrospinning, Results in Physics, 15 (2019), Dec., 102646
  29. Li, X. X., He, J. H., Nanoscale Adhesion and Attachment Oscillation under the Geometric Potential, Part 1: The Formation Mechanism of Nanofiber Membrane in the Electrospinning, Results in Physics, 12 (2019), Mar., pp. 1405-1410
  30. He, J. H., et al., Review on Fiber Morphology Obtained by the Bubble Electrospinning and Blown Bub-ble Spinning, Thermal Science, 16 (2012), 5, pp. 1263-1279
  31. Zhao, L., et al., Sudden Solvent Evaporation in Bubble Electrospinning for Fabrication of Unsmooth Nanofibers, Thermal Science, 21 (2017), 4, pp. 1827-1832
  32. Liu, L. G., et al., Solvent Evaporation in a Binary Solvent System for Controllable Fabrication of Porous Fibers by Electrospinning, Thermal Science, 21 (2017), 4, pp. 1821-1825
  33. Tian, D., et al., Self-Assembly of Macromolecules in a Long and Narrow Tube, Thermal Science, 22 (2018), 4, pp. 1659-1664
  34. Peng, N. B., et al., A Rachford-Rice Like Equation for Solvent Evaporation in the Bubble Electrospin-ning, Thermal Science, 22 (2018), 4, pp. 1679-1683
  35. Li, Y., et al., Fabrication and Characterization of ZrO2 Nanofibers by Critical Bubble Electrospinning for High-Temperature-Resistant Adsorption and Separation, Adsorption Science & Technology, 37 (2019), 5-6, pp. 425-437
  36. He, C. H., et al., Fangzhu: An Ancient Chinese Nanotechnology for Water Collection from Air: History, Mathematical Insight, Promises and Challenges, Mathematical Methods in the Applied Sciences, On-line first, doi.org/10.1002/mma.6384, 2020
  37. Kurapov, Y., et al., Synthesis of Copper and Silver Nanoparticles by Molecular Beam Method, Micro and Nanosystems, 10 (2018), 2, pp. 148-157

© 2020 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence