Beta Fulltext view is in preview — article structure may vary. Browse all articles
Contents
Nanomedicine & Nanotechnology Open Access Research Article 16 min read

A Survey on Smart Sensors Drivers and Gas Detection Technologies

Tripathi GK*
* Corresponding author
ISSN: 2574-187X  10.23880/nnoa-16000215  Received: January 07, 2022  Published: January 31, 2022
  views
 66 references
 2 figures
 3 tables
PDF
Keywords
Greenhouse Chemoresistiv Recent Developments Sensing Technologies Factors
Abstract

Nowadays, technologies for sensing the presence of gases are being extensively studied and explored for identification or recognition at room or any other temperature. Advanced sensor machinery for gas detection is used in various fields such as greenhouse gas monitoring, chemoresistive, and optical gas sensor, etc. Based on indigenous technical advances and literature investigations, new developments and improvements in sensors proposed to meet the increasing demand of rigorous performance in forthcoming varied applications, are described in the present study. This review paper provides descriptions, evaluation, comparison and evolutions in prevailing pioneering technologies for gas sensing. Various sensing technologies are given, based on the variation of electrical and other properties. Furthermore, this paper focuses on various metal oxides and electrical properties for performance indicators to compare different sensing technologies analyze the factors, temperature, or room temperature several corresponding improved approaches.

Introduction

Recently, researches show that one-dimensional (1D) and two-dimensional (2D) nanostructure semiconducting oxides have several advantages concerning traditional thin- film (prepared by thermal evaporation, spin coater, spray pyrolysis methods etc.) and thick-film (prepared by doctor blade method) sensors such as high surface-to-volume ratio, dimensions comparable to the extension of surface charge region. This segment devoid of majority charge carriers penetrates to a nearly small number of debyes inside the bulk material [1, 2, 3]. Although smart sensing has played a role in life and production, it should be emphasized that there are still many challenges in the development of smart gas sensing corresponding to the various stages of technology [4].

During the past sixty years, different studies have established various branches of gas sensing technology. Important things in the present scenario include the investigation of diverse types of sensors, research about sensing principles, and fabrication techniques [5, 6, 7, 8, 9]. The sensor resistance is usually used as a measure of sensor response, which detects the current or voltage changes. World-level research on smart gas sensing technology is a combination of a gas sensor array and pattern recognition method to detect, analyze, and quantify mixed gases, which can achieve high measurement accuracy of sensitivity of response and recovery time and get smarter conclusions [10, 11, 12, 13, 14]. The developments in sensor technology are consequently based on permanent technical progress in various fields.

The sensors which are the heart of instrumentation systems are ‘smart’ in nature now. A ‘smart sensor’ consists of the identifier/detecting component on a chip along with allied microelectronics for conditionally affecting signal etc. [15, 16]. One of the important features regarding the system of smart sensors facilitates one to provide vital data to the handler with enhanced steadfastness and veracity. Smart sensors normally have their components integrated onto the same printed circuit board (PCB) [17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66]. This level of integration improves both reliability and performance while reducing production testing costs.

This review paper summarizes the relevant researches published and provides a comprehensive study on smart gas sensing technology. Therefore, a lot of research is ongoing to develop new sensing materials and to improve and optimize various elements of established gas sensor types. A fundamental thing is a particular focus devoted to the preparation of gas sensors, technology, drivers and, the preparation of nanomaterials. The applications are discussed in much more detail in the following article.

Requirements of Gas Sensors

Requirements on Oxygen Safety Sensors

Oxygen measuring/monitoring gadgets are proposed to be connected in animals and/or test sites or laboratories to uninterruptedly measure oxygen levels. Too much presence of oxygen or rare case of oxygen at the workplace can at times be dangerous so it becomes important to continuously check the levels of oxygen. Also, the density of air, 1,354 kg/ m3, is the same as that of oxygen. The minimum and the maximum safe level or concentration of oxygen specified by the Occupational Safety and Health Administration (OSHA) is 19.5%, and 23.5% respectively. Oximeters or Oxygen measuring tools are desired at a few locations under the OSHA confined space regulation.

Some of the typical places where trampled gases are observed that potentially create an oxygen-deficient atmosphere are as follows [19, 20, 21, 22, 23, 24, 25]:

  • Magnetic resonance imaging (MRI) rooms (or magnet rooms)
  • Transmission Electron Microscope (TEM) rooms
  • Freezer farms The various requirements can be briefed as follows:
  • reliable response with sufficient accuracy and sensitivity (20.7% at average humidity level)
  • change in the signal to noise ratio
  • robustness including low sensitivity to environmental parameters such as:

- temperature (-20 to 60 °C (safety) - pressure below the 60 kPa (8.7 PSI)

- relative humidity (21 to 100 %),

  • gas flow rate independence,
  • High accuracy
  • Response time <8 sec (63%)

• Lower fouling sensitivity

  • Measures absolute oxygen concentrations without repeated calibrations
  • Better long-term stability
  • Less affected by pressure
  • Not freezing sensitive
  • Small size

Requirements for NH3 Safety Sensors

Ammonia, a naturally occurring gas, exists although the atmosphere. Devices that sense Ammonia along with accompanying detecting instruments are vital in estimating the ecological conditions at locations that use anhydrous ammonia. Formerly, relatively low concentrations, of low- ppb to sub-ppb levels, were sufficiently higher [26, 27, 28]. Ammonia sensors include a long-life version commonly used for process leak detection. The purpose of these detectors is to sense and divulge the occurrence of ammonia in the human environment or property defences and for apparatus control. Applications of sensing devices for ammonia are swiftly improvising with enhanced refrigeration controls [29, 30]. Demonstrates the brief statement of ammonia (NH3) sensor exposure effects on human health at various concentrations (ppm) (Table 1).

Ammonia VaporEffectsRemarksReference
S. No.EffectsRemarksReferenceConcentration (ppm)
105-Octodour thresholda very pungent odour, detectable by humans at concentrations[31]
225noticeable odourirritation and general symptoms[32]
335-50odourousmoderate irritation to the eyes, throat, nose and chest[33]
4100strongAny exposure period[34]
5150very strong odour50% of Immediately Dangerous to Life & Health concentration[35]
6200very strong odourdisagreeable odour and respiratory distress[36]
7300Over powering odourImmediately Dangerous to Life & Health[37]
8400major throat irritationOrdinarily, no serious results following short exposures[38]
8400major throat irritation
9500Throat irritationcold or nasal dryness[38][39]
101000immediate coughingnasal dryness and lungs[40]

Table 1: Summary of anhydrous ammonia sensor exposure effects.

Requirements on NO2 Safety Sensors

Nitrogen dioxide is almost imperceptible to humans. Depending on the temperature, nitrogen dioxide can appear as a colourless solid, a yellow liquid or a reddish-brown gas. It is heavier than air, as well as being acidic, corrosive and oxidizing. Annual mean concentrations of NO2 are highest in urban environments and around major highways [41]. Nitrogen dioxide (NO2), one of the harmful gases to human health, is widespread in surrounding environments. These gas-based sensors are produced to the best quality ethics, giving products that are exceedingly accurate as well as sensitive for the air quality and gas safety also. Nitrogen dioxide sensor technology provides reliable sensors for use in several high accuracy applications. NO2 sensing strong signal levels combined with low ppb (parts per billion) in addition to an operational range of 20ppm (parts per million) [42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56]. Shows the NO2 toxicity level and related health symptoms at high to low concentrations (ppm to ppb) (Table 2).

Sensitivity to environmental parameters at low ppm of NO2 such as [43]:

  • Ttemperature (-20 to 50°C (safety)
  • Operating pressure 1013 hPa±10%
  • Operating humidity (15~90 % RH), - Gas flow rate independence, - Highly accuracy - Response time <25 sec - High sensitivity - Better high stability
NO₂ Level in AirToxic SymptomsReference
15 ppmChronic bronchitis, emphysema[44]
25 ppmNose, Eye and upper respiratory exasperation[44]
35 ppmChronic bronchitis, emphysema[44]
41 ppmMild headache[45]
51 ppmLower respirational irritation, Acute pulmonic oedema; (cough, dyspnea)[45]
61 ppmEye, nose, and upper respiratory irritation[45]
70.2 ppmLower respiratory irritation[46]

Table 2: Nitrogen dioxide, associated Health Indicators and Toxicity levels.

Sensor Technology Drivers

In recent times many countries industry is experiencing shorter innovation cycles, the growing technical complexity of their products, and increased costs in conducting and commercializing research and development. Active trends have important implications for sensor development technology. Semiconductor metal oxide (SMO) play role in sensor technology developments to specific targeted applications. According to the technology business development manager, sensor fusion leads to smarter and better applications, specifically in the field of autonomous movement. Drivers of sensing hardware are accomplished by the Windows Portable Devices (WPD) driver archetypal, that uses on the Windows User Mode Driver Framework (UMDF) [47].

The commission acknowledged three basic sensing drivers to develop new and upgraded sensors and associated constituents [48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66]:

  • Economic (improved, quicker, cheaper);
  • Regulatory, (for example: environmental and safety monitors, automotive emissions control);
  • Unique government requirements, typified by Department of Defence or Department of Energy needs in energy, the environment, and defence.

Smart Gas Sensor setup and calculation

Smart gas sensing technology is a combination of a gas sensor array and pattern recognition method to detect, analyze, and quantify mixed gases or single gas, which can achieve high measurement accuracy and get fast response and recovery time with accuracy [4]. Smart technology is a promising research advanced technique that will broaden the development of a wide range of next-generation smart gas sensor applications aimed at improving the safety (for humans) and leakage or flow control of existing and future safety systems.

The working principle of metal oxide requires divergences in the depletion layer at the boundaries of grain when reducing or oxidizing gases are present. This gives modulations in the energy barriers allowing free charge carriers to cross the barrier and flow [49]. Shows the blocks diagram of the gas sensor setup for different metal oxides/nanomaterials thin film (Figure 1).

Figure 1: Blocks of gas sensor data analysis setup for different nanomaterials thin film [49].
Click to enlarge
Figure 1: Blocks of gas sensor data analysis setup for different nanomaterials thin film [49].
Figure 2: Typical response of a Chemical gas sensor [50].
Click to enlarge
Figure 2: Typical response of a Chemical gas sensor [50].

Shows two standard parameters from the baseline manipulation technique: 4Rs and 4Rf (Figure 2).

  • R0: the initial resistance of a sensor calculated as the average value of its resistance during the first minute of a measurement.
  • Rs: the steady-state resistance calculated as the average value during the latest minute of a measurement.
  • Rf: 10% of response sensor at the end of the acquisition period.

ΔRs means the resistance of the sensor rises from Ro to Rs, which provides information about the response time t (second) and ΔRf shows the resistance of sensor rises from Rf to Ro providing the recovery time t for a fall time (second). The standard procedure is to select the steady-state response means saturation state of each sensor as shown in (Figure 2). The fast response rate and recovery rate of Metal oxide materials to the gas mixture or single gas concentration depend upon the properties of the materials. Gas response sensitivity calculates from the initial resistance (R0) of a sensor and the end of the acquisition period of resistance (Rf).

Rs and Rf (Figure 2) whose expressions are given by [50]:

ΔRs ΔRf

Conclusions

In the present review article, the authors have discus with the major types of gas sensing technologies mentioning some of the developments in their field of research. The recent trends are focusing on investigating advanced technologies and approaches in addition to improving the conventional leading-edge sensor technologies. Research on new semiconductor metal oxide sensing materials, expansion of new sensing machinery, and diminishment of sensor podia yielding equipment with improved delivering output at a decreased cost are also presented. The development of the most popular sensor models, techniques, and approaches, which are widely used to estimate advanced technology and the response of various gas sensors.

References

  1. Wang D, Chu XF, Gong ML (2006) Gas-sensing properties of sensors based on single-crystalline SnO2 nanorods prepared by a simple molten-salt method. Sensors and Actuators B Chemical 117(1): 183-187.
  2. Comini E (2006) Metal oxide nanocrystals for gas sensing. Anal Chim Acta 568(1-2): 28–40.
  3. Shankar N, Yu MF, Vanka SP, Glumac NG (2006) Synthesis of tungsten oxide (WO3) nanorods using carbon nanotubes as templates by hot filament chemical vapour deposition. Materials Letters 60(6): 771-774.
  4. Shaobin F, Farha F, Li Q, Wan Y, Xu Y, et al. (2019) Review on smart gas sensing technology. Sensors 19(17): 3760.
  5. Inta M, Parra V, Dobulans R, Fonavs E, Latvels J, et al. (2007) A novel gas sensor transducer based on phthalocyanine heterojunction devices.  Sensors  7(11): 2984-2996.
  6. Hakim B, Dibi Z (2009) A novel neural network-based technique for smart gas sensors operating in a dynamic environment. Sensors 9(11): 8944-8960.
  7. Woo-Jin H, Kyu-Sik S, Ji-Hyoung R, Dae-Sung L, Sung- Hoon C, et al. (2011) Development of micro-heaters with optimized temperature compensation design for gas sensors. Sensors 11(3): 2580-2591.
  8. Jin H, Wan Q (2009) Gas sensors based on semiconducting metal oxide one-dimensional nanostructures. Sensors 9(12): 9903-9924.
  9. Achmann S, Hagen G, Kita J, Malkowsky IM, Kiener C, et al. (2009) Metal-organic frameworks for sensing applications in the gas phase. Sensors 9(3): 1574-1589.
  10. Gutierrez-Osuna R (2002) Pattern analysis for machine olfaction: A review. IEEE Sensors Journal 2(3): 189-202.
  11. Tingting L, Lv X, Hu Z, Xu A, Feng C, et al. (2019) Semiconductor metal oxides as chemoresistive sensors for detecting volatile organic compounds. Sensors 19(2): 233.
  12. Wei Y, Jiao Y, An D, Li D, Li W, et al (2019) Review of dissolved oxygen detection technology: From laboratory analysis to online intelligent detection. Sensors 19(18): 3995.
  13. Luo J, Dziubla T, Eitel R (2017) A low temperature co-fired ceramic-based microfluidic Clark-type oxygen sensor for real-time oxygen sensing. Sensors and Actuators B: Chemical 240: 392-397.
  14. Singh N, Singh N, Mishra KM, Haque FZ (2016) Photoluminescence Properties of ZnO Micro/ Nanostructures Capped with Various Surfactants. Journal of Advanced Physics 5(2): 184-189.
  15. Singh V R (2005) Smart sensors: Physics, technology and applications. Indian Journal of Pure and Applied Physics 43(1):7-16
  16. Hunter G, Stetter J, Hesketh P, Liu CC (2010) Smart sensor systems.  The Electrochemical Society Interface  19(4): 29-34
  17. McGrath M J, Scanaill C N (2013) Sensor technologies: healthcare, wellness, and environmental applications. Springer Nature.
  18. World Health Organization (2016) Technical Specifications for Oxygen Concentrators: WHO Medical Device Technical Series, World Health Organization.
  19. Drew M C (1990) Sensing soil oxygen,  Plant, Cell & Environment 13(7): 681-693.
  20. Warburton R, Sawtelle RS, Watson A, Wang AQ (2001) Failure prediction for a galvanic oxygen sensor. Sensors and Actuators B-Chemical 72(3): 197-203.
  21. Ramamoorthy R, Dutta PK, Akbar SA (2003) Oxygen sensors: materials, methods, designs and applications. Journal of materials science 38(21): 4271-4282.
  22. Ward JP (2008) Oxygen sensors in context, Biochimica et Biophysica Oxygen sensors in context, Biochimica et Biophysica 1777(1): 1-14.
  23. Carlos L G, Ramos F, Cirera A (2009) YSZ-based oxygen sensors and the use of nanomaterials: a review from classical models to current trends. Journal of Sensors.
  24. Grist SM, Chrostowski L, Cheung KC (2010) Cheung, Optical oxygen sensors for applications in microfluidic cell culture, Sensors 10(10): 9286-9316.
  25. Howell S G, Clarke A D, Shinozuka Y, Kapustin V, McNaughton C S, et al. (2006) Influence of relative humidity upon pollution and dust during ACE‐ Asia: Size distributions and implications for optical properties. Journal of Geophysical Research: Atmospheres 111(D6).
  26. Björn T, Olthuis W, Van Den Berg A (2005) Ammonia sensors and their applications—a review, Sensors and Actuators B: Chemical 107(2): 666-677.
  27. Peter W (1999) Chemistry of the natural atmosphere. 2nd (Edn.), Elsevier.
  28. Yebo NA, Sree SP, Levrau E, Detavernier C, Hens Z, et al. (2012) Selective and reversible ammonia gas detection with nanoporous film functionalized silicon photonic micro-ring resonator.  Optics express  20(11): 11855- 11862.
  29. Srivastava V, Jain K (2015) Mechanism of enhancement in NH 3 sensing for surface-functionalized WO 3 film. RSC advances 5(70): 56993-56997.
  30. Singh N, Pandey V, Singh N, Malik MM, HaqueF Z (2017) Application of TiO2/SnO2 nanoparticles in photoluminescence based fast ammonia gas sensing. Journal of Optics 46(3): 199-203.
  31. Sundblad BM, Larsson BM, Acevedo F, Ernstgård L, Johanson G (2004) Acute respiratory effects of exposure to ammonia on healthy persons. Scand J Work Environ Health 30(4): 313-321
  32. MacEwen JD, Theodore J, Vernot EH (1970) Human exposure to EEL concentrations of monomethylhydrazine. In: Proceedings 1st annual conference on environmental toxicology. pp: 355-363.
  33. Nitu S, Umar A, Singh N, Fouad H, Alothman OY, et al. (2018) Highly sensitive optical ammonia gas sensor based on Sn Doped V2O5Nanoparticles.  Materresbull 108(1): 266-274.
  34. Moos R (2005) A brief overview on automotive exhaust gas sensors based on electroceramics. International Journal of Applied Ceramic Technology 2(5): 401-413.
  35. Silverman J, Bays DW, Cooper SF, Baker SP (2008) Ammonia and carbon dioxide concentrations in disposable and reusable ventilated mouse cages. Journal of the American Association for Laboratory Animal Science 47(2): 57-62.
  36. Singh N, Bamne J, Mishra K M, Singh N, Haque FZ (2021) Photoluminescence and Chemoresistive Gas Sensing: A Comparative Study Using V2O5 Nanostructures for NH3. Emerging Trends in Nanotechnology. pp: 279-307.
  37. Tepper JS, Weiss B, Wood RW (1985) Alterations in behaviour produced by inhaled ozone or ammonia.  Fundamental and Applied Toxicology  5(6): 1110-1118.
  38. World Health Organization (2001)  Biomarkers in Risk Assessment: Validity and Validation-Environmental Health Criteria 222.
  39. Silverman J, Bays DW, Baker SP (2009) Ammonia and carbon dioxide concentrations in disposable and reusable static mouse cages, Lab animal 38(1): 16-23.
  40. Reeb-Whitaker CK, Paigen B, Beamer WG, Bronson RT, Churchill GA, et al. (2001) The impact of reduced frequency of cage changes on the health of mice housed in ventilated cages. Laboratory animals 35(1): 58-73.
  41. Rijnders E, Janssen NA, van Vliet PH, Brunekreef B (2001) Personal and outdoor nitrogen dioxide concentrations in relation to the degree of urbanization and traffic density. Environmental health perspectives 109(3): 411- 417.
  42. Ko G, Kim HY, Ahn J, Park YM, Le KL, et al. (2010) Graphene-based nitrogen dioxide gas sensors.  Current Applied Physics 10(4): 1002-1004.
  43. Su TY, Chen YZ, Wang YC, Tang SY, Shih YC, et al. (2020) Highly sensitive, selective and stable NO2 gas sensors with a ppb-level detection limit on 2D-platinum diselenide films. Journal of Materials Chemistry C 8(14) (2020): 4851-4858.
  44. Elsayed NM (1994) Toxicity of nitrogen dioxide: an introduction, Toxicology 89(3): 161-174.
  45. Brewer A W, C T McElroy, J B Kerr (1973) Nitrogen dioxide concentrations in the atmosphere, Nature  246(5429): 129-133.
  46. Kleinman MT, Bailey RM, Linn WS, Anderson KR, Whynot JD, et al. (1983)Effects of 0.2 ppm nitrogen dioxide on pulmonary function and response to bronchoprovocation in asthmatics. J Toxicol Environ Health 12(4-6): 815-826.
  47. Sheng X, Jian T, Xuejie X, Guoliang X (2013) Sensing as a service: Challenges, solutions and future directions. IEEE Sensors Journal 13(10): 3733-3741.
  48. Hughes RC, Ricco AJ, Butler MA, Martin SJ (1991) Chemical microsensors. Science 254(5028): 74-80.
  49. Degler D (2018) Trends and Advances in the Characterization of Gas Sensing Materials Based on Semiconducting Oxides, Sensors 18(10): 3544.
  50. Nicolae B, Weimar U (2001) Conduction model of metal oxide gas sensor. Journal of electroceramics 7(3): 143- 167.
  51. Tripathi GK, Rathore H, Chavali M, Rathore D (2021) Nanotechnology for Mitigating Impact of COVID-19. Journal of Applied Science, Engineering, Technology, and Education, 3(2), 171-180.
  52. Soni P, Tripathi GK, Bundela P, Khiriya PK, Khare PS, et al. (2021) Flexible Carbon Based Nanoelectronics with Printing Approaches. Letters in Applied NanoBioScience 11: 3728 - 3737.
  53. Prajapati HN, Khiriya PK, Tripathi GK, Bundela P, Khare PS, et al. (2021) Green Synthesis of SnO2/ Carbon Quantum Dots Nanocomposite for Gas Sensing Application. International Journal of Research and Review 8(1): 332-336.
  54. Moradiya MA, Khiriya PK, Tripathi GK, Bundela P, Khare PS (2021) The Investigation of Microwave-Assisted Greener Synthesis of Ag/Ti/Zn Trimetallic Nanoparticles and Carbon Quantum Dots Nanocomposites in the Application of Solar Cell. Letters in Applied NanoBioScience 11(1): 3102-3110.
  55. Soni P, Tripathi GK, Shashank S, Khare PS, Chavali M (2020) Thriving Perspectives of Nanotechnology: A Review. Nanomedicine & Nanotechnology Open Access 5(3): 1 -10.
  56. Sharma I, Tripathi GK, Kant C, Saini KK (2020) Understanding enhanced photoactivity mechanisms of bismuth oxyhalides nanostructures for environmental remediation. ESSENCE Int J Env Rehab Conserv 11(1): 491-509.
  57. Tripathi GK, Khare PS, Saini K (2020) Optical Properties of Bismuth Oxy Chloride (BiOCl) Using Density Functional Theory. Biosci Biotech Res Comm 13(2): 875-881.
  58. Vyas R, Navin K, Tripathi GK, Kurchania R (2021) Structural, magnetic, photocatalytic, and electrochemical studies of the mesoporous Nickel oxide (NiO) nanostructures. Optik 231(40): 166433.
  59. Tripathi GK (2019) Engineered Nanomaterials and Their Properties: A Review. Biosci. Biotech. Res. Comm 12(3) 764-771.
  60. Tripathi GK, Kurchania R (2017) Photocatalytic behavior of BiOX (X= Cl/Br, Cl/I and Br/I) composites/ heterogeneous nanostructures with organic dye. Optical and Quantum Electronics 49(6): 203.
  61. Tripathi G K, Sharma I, Kant C, Pandey R R, Saini K, et al. (2016) Characterization of the photocatalytic activity of bismuth oxychloride nanostructures. Analytical Letters 49(9): 1452-1466.
  62. Tripathi G K, Kurchania R (2016) Effect of doping on structural, optical and photocatalytic properties of bismuth oxychloride nanomaterials. Journal of Materials Science: Materials in Electronics 27(5): 5079-5088.
  63. Sharma I, Tripathi GK, Sharma VK, Tripathi SN, Kurchania R, et al. (2015) One-pot synthesis of three bismuth oxyhalides (BiOCl, BiOBr, BiOI) and their photocatalytic properties in three different exposure conditions. Cogent Chemistry 1(1): 1076371.
  64. Tripathi GK, Saini K, Kurchania R (2015) Synthesis of nanoplate bismuth oxychloride—a visible light active material. Optics and Spectroscopy 119(4): 656-663.
  65. Srivastava P, Jaiswal NK, Tripathi GK (2014) Chlorine sensing properties of zigzag boron nitride nanoribbons. Solid State Communications 185(1): 41-46.
  66. Tripathi GK, Pandey RR, Kant C, Khare PS, Saini K (2013) Synthesis of visible light active biocl photocatalyst for energy and environmental applications. Synthesis 3(1): 167-170.
More from this journal

Cite this article

BibTeX
APA
RIS
@article{tripathi2022,
  title   = {A Survey on Smart Sensors Drivers and Gas Detection
Technologies},
  author  = {Tripathi GK},
  journal = {Nanomedicine & Nanotechnology Open Access},
  year    = {2022},
  volume  = {7},
  number  = {1},
  doi     = {10.23880/nnoa-16000215}
}
Tripathi GK (2022). A Survey on Smart Sensors Drivers and Gas Detection
Technologies. Nanomedicine & Nanotechnology Open Access, 7(1). https://doi.org/10.23880/nnoa-16000215
TY  - JOUR
TI  - A Survey on Smart Sensors Drivers and Gas Detection
Technologies
AU  - Tripathi GK
JO  - Nanomedicine & Nanotechnology Open Access
PY  - 2022
VL  - 7
IS  - 1
DO  - 10.23880/nnoa-16000215
ER  -