Time Characteristics of FEU-175 and FEU-186 Single-Electron Photomultipliers with Jitter of 0.4 ns

F. A. Ermalitsky; Ермалицкий Ф. А.; K. F. Ermalitskaya; Ермалицкая К. Ф.; V. N. Lukyanov; Лукьянов В. Н.; A. N. Vyaznikov; Вязников А. Н.; R. V. Kirpichenko; Кирпиченко Р. В.; G. A. Mamaeva; Мамаева Г. А.; A. E. Radko; Радько А. Е.; M. P. Samtsov; Самцов М. П.; O. A. Filipova; Филипова О. А.

doi:10.31857/S0032816223010147

Time Characteristics of FEU-175 and FEU-186 Single-Electron Photomultipliers with Jitter of 0.4 ns

Authors: Ermalitsky F.A.¹, Ermalitskaya K.F.², Lukyanov V.N.³, Vyaznikov A.N.³, Kirpichenko R.V.³, Mamaeva G.A.³, Radko A.E.¹, Samtsov M.P.¹, Filipova O.A.³
Affiliations:
1. Institute of Applied Physical Problems, Sevchenko Belarusian State University
2. Belarusian State University
3. Central Research Institute Electron
Issue: No 2 (2023)
Pages: 129-136
Section: ЛАБОРАТОРНАЯ ТЕХНИКА
URL: https://rjsvd.com/0032-8162/article/view/670570
DOI: https://doi.org/10.31857/S0032816223010147
EDN: https://elibrary.ru/PVAFCP
ID: 670570

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Abstract

The results from studying the time characteristics (counting, amplitude distributions of single-electron pulses, spread of the signal propagation time (jitter) when exposed to radiation from picosecond diode lasers in the spectral range 405–780 nm) of high-speed photomultipliers FEU-175 and FEU-186 manufactured by AO Central Research Institute Electron (St. Petersburg). FEU-175 and FEU-186, respectively, are equipped with bialkali and multialkali photocathodes; their operating spectral range is 250–650 and 250–800 nm, respectively. Signal amplification is provided by a 14-dynode multiplication system, while the rise time of the PMT impulse response does not exceed 1.5 ns and the jitter is approximately 0.4 ns. PMT data can be used as photodetectors in single-quantum kinetic spectrometers with subnanosecond resolution and in other high-speed optoelectronic recorders.

References

Demas J.N. Exited state lifetime measurements. NY., London: Academy Press, 1983. https://doi.org/10.1016/b978-0-12-208920-6.x5001-0
Lakowicz J.R. Principles of fluorescence spectroscopy. 3rd ed. NY.: Springer, 2006. https://doi.org/10.1007/978-0-387-46312-4
Hamamatsu. Photomultiplier tubes. Hamamatsu Photonics K.K. 2016.
Ветохин С.С., Ермалицкий Ф.А., Мельников С.М., Суханин С.В., Шойтов М.А. // ПТЭ. 1998. № 2. P. 5.
Ермалицкий Ф.А., Радько А.Е., Самцов М.П. // ПТЭ. 2020. № 6. С. 125. https://doi.org/10.31857/S0032816220060051
Воропай Е.С., Ермалицкая К.Ф., Ермалицкий Ф.А., Радько А.Е., Ржеуцкий Н.В., Самцов М.П. // ПТЭ. 2022. № 1. С. 100. https://doi.org/10.31857/S0032816222010232
Воропай Е.С., Ермалицкий Ф.А., Каплевский К.Н., Радько А.Е. // ПТЭ. 2016. № 4. С. 156. https://doi.org/10.7868/S0032816216040157
Dendebera M., Chornodolskyy Ya., Gamernyk R., Antonyak O., Pashuk I., Myagkota S., Gnilitskyi I., Pankratov V., Vistovskyy V., Mykhaylyk V., Grinberg M., Voloshinovskii A. // Journal of Luminescence. 2020. V. 225. P. 117346. https://doi.org/10.1016/j.jlumin.2020.117346
Белько Н.В., Самцов М.П., Тихомиров С.А., Буганов О.В. // Журнал прикладной спектроскопии. 2020. Т. 87. № 5. С. 752. https://doi.org/10.1007/s10812-020-01078-z