Journal of Engineering and Applied Sciences
Year:
2017
Volume:
12
Issue:
11 SI
Page No.
9075 - 9081
References
Baiburin, V.B., Y.P. Volkov, E.M. Il’in and S.V. Semenov, 2002. Tunneling spectroscopy of palladium-barium emitters. Tech. Phys. Lett., 28: 981-982.
Direct Link | Djubua, B.C. and A.N. Korolev, 2011. Modern efficient cathodes. Electron. Ser. 1. Microwave Eng., 1: 5-12.
Djubua, B.C. and O.V. Polivnikova, 2015. Metal-alloyed cold secondary emission cathode. Proceedings of the IEEE International Conference on Vacuum Electronics (IVEC), April 27-29, 2015, IEEE, Beijing, China, ISBN:978-1-4799-7109-1, pp: 1-4.
Djubua, B.C., O.K. Kultashev, A.P. Makarov, O.V. Polivnikova and E.M. Zemchikhin, 2012. Metal alloy cathodes for application in vacuum microwave devices. Proceedings of the IEEE 9th International Conference on Vacuum Electron Sources Conference (IVESC’12), April 24-26, 2012, IEEE, Monterey, California, USA., ISBN:978-1-4673-0368-2, pp: 177-178.
Djubua, B.C., O.K. Kultashov and O.V. Polivnikova, 2008. Emission electronics, nanotechnology, synergetics (on the history of ideas of the cathode technology). Electron. Ser. 1. Microwave Eng., 4: 3-21.
Dobretsov, L.N. and M.V. Gomoyunova, 1966. Emission Electronics. Nauka Publishers, Moscow, Russia, Pages: 564.
Kislitsyn, A.P., 2015. Controlling the emission inhomogeneity of the work surface of a thermocathode during emission tests. Eng. Technol., 4: 90-95.
Komai, M., M. Sasaki, R. Ozawa and S. Yamamoto, 1999. Microscopical analysis of structure and work function of Ba-covered Si (111)-(7×7) surface. Appl. Surf. Sci., 146: 158-161.
Direct Link | Li, I.P. and G.G. Bondarenko, 2012. Application of hydrogen vacuum treatment of palladium powders for production of efficient metal alloy cathodes of self-heated magnetron. Inorg. Mater. Appl. Res., 3: 381-384.
CrossRef | Li, I.P., V.S. Petrov, V.S. Polyakov, A.D. Silaev and N.E. Ledentsova
et al., 2015. Simultaneous activation of the field-emission and secondary-emission cathodes of a magnetron with a nonincandescent launch. Russian Microelectron., 44: 431-435.
CrossRef | Li, S., T. Yan, F. Li, J. Yang and W. Shi, 2016. Experimental study of millimeter magnetrons with cold cathodes. IEEE. Trans. Plasma Sci., 44: 1386-1390.
CrossRef | Direct Link | Lopin, M.I., 2014. Metal-allow cathodes for high-power continuous-wave mode multiple-beam klystrons in the dominant mode of oscillation. Electron. Ser. 1. Microwave Eng., 2: 53-56.
Lozovan, A.A., V.S. Polyakov and I.P. Li, 2014. Effect of ion bombardment on the topography and chemical composition of the surface of PD-BA powder composites. J. Surf. Invest. X-ray Synchrotron Neutron Tech., 8: 1311-1314.
Direct Link | Pashkov, A.N., Y.V. Romanov, R.N. Popov, O.V. Dubinina and M.N. Khabachev, 2011. Modern efficient cathodes. Electron. Ser. 1. Microwave Eng., 4: 72-77.
Pashkov, A.N., Y.V. Romanov, R.N. Popov, O.V. Dubinina and M.N. Khabachev, 2016. Designing a technology for manufacturing cathode alloys based on platinum group metals for high-power vacuum-tube microwave devices. Electron. Ser. 1. Microwave Eng., 532: 73-77.
Polivnikova, O.V. and I.P. Li, 2013. Pressed metal-alloy palladium-barium cathode. Proceedings of the IEEE 14th International Conference on Vacuum Electronics (IVEC’13), May 21-23, 2013, IEEE, Paris, France, ISBN:978-1-4673-5977-1, pp: 1-2.
Swartzentruber, P., T.J. Balk, J.O. Tarter and D. Busbaher, 2014. Direct work function measurement of activated M-type dispenser cathodes. Proceedings of the IEEE International Conference on Vacuum Electronics, April 22-24, 2014, IEEE, Monterey, California, USA., ISBN:978-1-4799-3426-3, pp: 135-136.
Yesaulov, N.P., 2016. Secondary-emission materials and products on their basis for high-power vacuum-tube microwave devices. Electromagn. Waves Electron. Syst., 21: 58-64.