Global Actinometer Market 2023-2030

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    An actinometer is a chemical system or physical device which determines the number of photons in a beam integrally or per unit time. This name is commonly applied to devices used in the ultraviolet and visible wavelength ranges.


    For example, solutions of iron(III) oxalate can be used as a chemical actinometer, while bolometers, thermopiles, and photodiodes are physical devices giving a reading that can be correlated to the number of photons detected.


    Chemical actinometry uses the yield from a chemical reaction to calculate radiant flux. A chemical with a known quantum yield and easily studied reaction products are necessary for this method.


    Actinometer is a substance or mixture of substances that undergoes a photochemical reaction and is used as a standard for measuring the light energies involved in photochemical work because the extent of the reaction and the energy of the absorbed light have an easily quantifiable relationship.




    S No Product Name Development
    1 Kosmos 156 The actinometer was made to measure the longwave radiation that leaves the Earth’s atmosphere , the near ultraviolet (UV), visible, and near infrared (IR) solar radiation that leaves the Earth’s atmosphere, as well as the effective radiation temperature of the Earth’s surface and cloud tops. 
    2 4,4′-Dimethylazobenzene as a chemical actinometer Chemical actinometers are a useful instrument in photochemistry because they let you quantify photoreactions by measuring the photon flux of a light source. The most widely used actinometers to date have minor limitations including challenging data processing, parasitic responses, poor stability, or impossibility of reset. 
    3 Ferrioxalate Actinometer The description of the ferrioxalate actinometer methodology that may be used to measure the photon flux in each of our different photoreactors.This ferrioxalate actinometer methodology involves exposing a ferrioxalate (Fe3+) solution to radiation in order to gauge the rate at which Fe2+ is produced. 


    The use of 4,4′-dimethylazobenzene as a chemical actinometer is suggested here. When exposed to radiation at 365 nm, this molecule undergoes a clean and effective E/Z isomerization that approaches 100% conversion. 


    Its characteristics allow for the measurement of photon flux in the UV-visible region using straightforward experimental procedures and data processing, with the potential for reuse following photochemical or thermal reset.


    In diluted H2SO4, ferrioxalate is dissolved.  The methodology should only be used in a completely dark environment because the resultant solution is light-sensitive.


    To create a phenanthroline Fe2+ complex, samples are collected at precise times and combined with a phenanthroline solution and an AcONa (sodium acetate) buffer solution. 


    The next step is to use spectrometry to detect the phenanthroline Fe2+ compound absorption at 510 nm in order to calculate the subsequent Fe2+concentration. Using phenanthroline and a solution of FeSO4, a calibration curve is created.


    The composition of discharges of mixes of tetramethylsilane, sulfur hexafluoride, and helium was examined using conventional and dynamic actinometric optical emission spectroscopies. 


    As an actinometer, argon was present in trace amounts. As a function of the amount of SF6 in the feed, Rs, trends in the plasma concentrations of the species H, CH, Si, F, and CF2 were discovered.


    Dynamic actinometry, which includes observing the relative intensities of plasma species after one of the main feed gases is interrupted, provided information about the respective weights of gas-phase and plasma/polymer-surface reactions in the synthesis of the measured plasma species. These findings lead to the proposed reaction pathways and mechanisms for the generation of these species.


    Medium pressure Hg-based UV lamps and non mercury, pulsed UV lamps emitting polychromatic light are being considered as alternatives to low-pressure, monochromatic UV lamps in light of the increasing acceptance of ultraviolet (UV) irradiation for the disinfection of water and wastewater.


    Traditional fluence measurement techniques, however, were created for monochrome light sources, and they are ineffective for measuring fluence from sources of polychromatic light.


    Mathematical modelling and chemical actinometry (uridine and iodide/iodate) were combined to explore novel methods for estimating the effective germicidal fluence for polychromatic UV sources.Radiometry and actinometric fluence data were compared to microbial biodosimetry.


     The precision of incident and germicidal polychromatic UV fluence measurement was enhanced by combining conventional chemical actinometry with mathematical analysis.


    With or without a mathematical correction, the determination of germicidal fluency by the uridine actinometer fell just outside the 95% confidence interval of the biodosimetry.


    In a similar vein, it was found that an iodide/iodate actinometer could measure incident fluence precisely, and when combined with mathematical adjustments, it could measure germicidal fluence within the 95% confidence interval of the fluence measured by biodosimetry.


    The ability to measure germicidal effective UV fluency from any form of UV lamp using these techniques has the potential to become flexible and practical.




    infographic: Actinometer Market, Actinometer Market Size, Actinometer Market Trends, Actinometer Market Forecast, Actinometer Market Risks, Actinometer Market Report, Actinometer Market Share


    The Global Actinometer market accounted for $XX Billion in 2022 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2023 to 2030.



    1. How many Actinometers are manufactured per annum globally? Who are the sub-component suppliers in different regions?
    2. Cost breakup of a Global Actinometer and key vendor selection criteria
    3. Where is the  Actinometer manufactured? What is the average margin per unit?
    4. Market share of Global Actinometer market manufacturers and their upcoming products
    5. Cost advantage for OEMs who manufacture Global Actinometer in-house
    6. key predictions for next 5 years in Global Actinometer market
    7. Average B-2-B Actinometer market price in all segments
    8. Latest trends in Actinometer market, by every market segment
    9. The market size (both volume and value) of the Actinometer market in 2023-2030 and every year in between?
    10. Production breakup of Actinometer market, by suppliers and their OEM relationship


    Sl no Topic
    1 Market Segmentation
    2 Scope of the report
    3 Abbreviations
    4 Research Methodology
    5 Executive Summary
    6 Introduction
    7 Insights from Industry stakeholders
    8 Cost breakdown of Product by sub-components and average profit margin
    9 Disruptive innovation in the Industry
    10 Technology trends in the Industry
    11 Consumer trends in the industry
    12 Recent Production Milestones
    13 Component Manufacturing in US, EU and China
    14 COVID-19 impact on overall market
    15 COVID-19 impact on Production of components
    16 COVID-19 impact on Point of sale
    17 Market Segmentation, Dynamics and Forecast by Geography, 2023-2030
    18 Market Segmentation, Dynamics and Forecast by Product Type, 2023-2030
    19 Market Segmentation, Dynamics and Forecast by Application, 2023-2030
    20 Market Segmentation, Dynamics and Forecast by End use, 2023-2030
    21 Product installation rate by OEM, 2023
    22 Incline/Decline in Average B-2-B selling price in past 5 years
    23 Competition from substitute products
    24 Gross margin and average profitability of suppliers
    25 New product development in past 12 months
    26 M&A in past 12 months
    27 Growth strategy of leading players
    28 Market share of vendors, 2023
    29 Company Profiles
    30 Unmet needs and opportunity for new suppliers
    31 Conclusion
    32 Appendix
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