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[n]	N. W. Martirosyan et al., “Preparation and Characterization of BTO-BFO Multiferroic Ceramics as Electrical Controllable Fast Phase Shifting Component”, in Proc. IPAC'22, Bangkok, Thailand, Jun. 2022, pp. 1178-1181. doi:10.18429/JACoW-IPAC2022-TUPOPT069

[n]	J. R. Leibfritz et al., “Status of the Fermilab Electron Cooling Project”, in Proc. EPAC'04, Lucerne, Switzerland, Jul. 2004, paper TUPLT151, pp. 1485-1487. 

[n]	A. Grassellino, “Will SRF Technology Revolutionize Quantum Computing?”, in Proc. SRF'21, East Lansing, MI, USA, Jun.-Jul. 2021, paper FROKNV01, pp.. 

[n]	L. Catani et al., “Cathodic Arc Grown Niobium Films for RF Superconducting Cavity Applications”, in Proc. SRF'05, Ithaca, NY, USA, Jul. 2005, paper TUP62, pp. 385-387. 

[n]	Y. Kalboussi et al., “Material Engineering of ALD- Deposited Multilayer to Improve the Superconducting Performances of RF Cavities Under Intense RF Fields”, in Proc. SRF'21, East Lansing, MI, USA, Jun.-Jul. 2021, paper FROFDV07, pp.. 

[n]	E. Hemsing, A. Gover, and J. B. Rosenzweig, “A Virtual Dielectric Eigenmode Expansion of High-Gain FEL Radiation for Study of Paraxial Wave Mode Coupling”, in Proc. FEL'08, Gyeongju, Korea, Aug. 2008, paper MOCAU01, pp. 167-171. 

For LaTeX

%\cite{Martirosyan:IPAC22-TUPOPT069} \bibitem{Martirosyan:IPAC22-TUPOPT069} N. W. Martirosyan \emph{et al.}, \textquotedblleft{Preparation and Characterization of BTO-BFO Multiferroic Ceramics as Electrical Controllable Fast Phase Shifting Component}\textquotedblright, in \emph{Proc. IPAC’22}, Bangkok, Thailand, Jun. 2022, pp. 1178--1181. \doi{10.18429/JACoW-IPAC2022-TUPOPT069} %\cite{Leibfritz:EPAC04-TUPLT151} \bibitem{Leibfritz:EPAC04-TUPLT151} J. R. Leibfritz \emph{et al.}, \textquotedblleft{Status of the Fermilab Electron Cooling Project}\textquotedblright, in \emph{Proc. EPAC’04}, Lucerne, Switzerland, Jul. 2004, paper TUPLT151, pp. 1485--1487. %\cite{Grassellino:SRF21-FROKNV01} \bibitem{Grassellino:SRF21-FROKNV01} A. Grassellino, \textquotedblleft{Will SRF Technology Revolutionize Quantum Computing?}\textquotedblright, in \emph{Proc. SRF’21}, East Lansing, MI, USA, Jun.-Jul. 2021, paper FROKNV01, pp.. %\cite{Catani:SRF05-TUP62} \bibitem{Catani:SRF05-TUP62} L. Catani \emph{et al.}, \textquotedblleft{Cathodic Arc Grown Niobium Films for RF Superconducting Cavity Applications}\textquotedblright, in \emph{Proc. SRF’05}, Ithaca, NY, USA, Jul. 2005, paper TUP62, pp. 385--387. %\cite{Kalboussi:SRF21-FROFDV07} \bibitem{Kalboussi:SRF21-FROFDV07} Y. Kalboussi \emph{et al.}, \textquotedblleft{Material Engineering of ALD- Deposited Multilayer to Improve the Superconducting Performances of RF Cavities Under Intense RF Fields}\textquotedblright, in \emph{Proc. SRF’21}, East Lansing, MI, USA, Jun.-Jul. 2021, paper FROFDV07, pp.. %\cite{Hemsing:FEL08-MOCAU01} \bibitem{Hemsing:FEL08-MOCAU01} E. Hemsing, A. Gover, and J. B. Rosenzweig, \textquotedblleft{A Virtual Dielectric Eigenmode Expansion of High-Gain FEL Radiation for Study of Paraxial Wave Mode Coupling}\textquotedblright, in \emph{Proc. FEL’08}, Gyeongju, Korea, Aug. 2008, paper MOCAU01, pp. 167--171.

For BibTeX

@inproceedings{martirosyan:ipac22-tupopt069, author = {N. W. Martirosyan and others}, title = {{Preparation and Characterization of BTO-BFO Multiferroic Ceramics as Electrical Controllable Fast Phase Shifting Component}}, booktitle = {Proc. IPAC'22}, pages = {1178--1181}, paper = {TUPOPT069}, venue = {Bangkok, Thailand}, series = {International Particle Accelerator Conference}, number = {13}, publisher = {JACoW Publishing, Geneva, Switzerland}, month = {7}, year = {2022}, issn = {2673-5490}, isbn = {978-3-95-450227-1}, doi = {10.18429/JACoW-IPAC2022-TUPOPT069}, url = {https://jacow.org/IPAC2022/papers/TUPOPT069.pdf}, language = {english} } @inproceedings{leibfritz:epac04-tuplt151, author = {J. R. Leibfritz and others}, title = {{Status of the Fermilab Electron Cooling Project}}, booktitle = {Proc. EPAC'04}, pages = {1485--1487}, paper = {TUPLT151}, venue = {Lucerne, Switzerland}, series = {European Particle Accelerator Conference}, number = {9}, publisher = {JACoW Publishing, Geneva, Switzerland}, month = {9}, year = {2004}, url = {http://accelconf.web.cern.ch/e04/papers/TUPLT151.pdf}, language = {english} } @inproceedings{grassellino:srf21-froknv01, author = {A. Grassellino}, title = {{Will SRF Technology Revolutionize Quantum Computing?}}, booktitle = {Proc. SRF'21}, pages = {}, paper = {FROKNV01}, venue = {East Lansing, MI, USA}, series = {International Conference on RF Superconductivity}, number = {20}, publisher = {JACoW Publishing, Geneva, Switzerland}, month = {10}, year = {2022}, issn = {2673-5504}, isbn = {978-3-95-450233-2}, language = {english} } @inproceedings{catani:srf05-tup62, author = {L. Catani and others}, title = {{Cathodic Arc Grown Niobium Films for RF Superconducting Cavity Applications}}, booktitle = {Proc. SRF'05}, pages = {385--387}, paper = {TUP62}, venue = {Ithaca, NY, USA, Jul. 2005}, publisher = {JACoW Publishing, Geneva, Switzerland}, url = {https://jacow.org/SRF2005/papers/TUP62.pdf}, language = {english} } @inproceedings{kalboussi:srf21-frofdv07, author = {Y. Kalboussi and others}, title = {{Material Engineering of ALD- Deposited Multilayer to Improve the Superconducting Performances of RF Cavities Under Intense RF Fields}}, booktitle = {Proc. SRF'21}, pages = {}, paper = {FROFDV07}, venue = {East Lansing, MI, USA}, series = {International Conference on RF Superconductivity}, number = {20}, publisher = {JACoW Publishing, Geneva, Switzerland}, month = {10}, year = {2022}, issn = {2673-5504}, isbn = {978-3-95-450233-2}, language = {english} } @inproceedings{hemsing:fel08-mocau01, author = {E. Hemsing and A. Gover and J. B. Rosenzweig}, title = {{A Virtual Dielectric Eigenmode Expansion of High-Gain FEL Radiation for Study of Paraxial Wave Mode Coupling}}, booktitle = {Proc. FEL'08}, pages = {167--171}, paper = {MOCAU01}, venue = {Gyeongju, Korea, Aug. 2008}, publisher = {JACoW Publishing, Geneva, Switzerland}, url = {https://jacow.org/FEL2008/papers/MOCAU01.pdf}, language = {english} }

References

• N. W. Martirosyan et al., “Preparation and Characterization of BTO-BFO Multiferroic Ceramics as Electrical Controllable Fast Phase Shifting Component”, in Proc. 13th Int. Particle Accelerator Conf. (IPAC'22), Bangkok, Thailand, Jun. 2022, pp. 1178-1181.
• J. R. Leibfritz et al., “Status of the Fermilab Electron Cooling Project”, in Proc. 9th European Particle Accelerator Conf. (EPAC'04), Lucerne, Switzerland, Jul. 2004, paper TUPLT151, pp. 1485-1487.
• A. Grassellino, “Will SRF Technology Revolutionize Quantum Computing?”, in Proc. 20th International Conference on RF Superconductivity (SRF'21), East Lansing, MI, USA, Jun.-Jul. 2021, paper FROKNV01, pp..
• L. Catani et al., “Cathodic Arc Grown Niobium Films for RF Superconducting Cavity Applications”, in Proc. 12th Int. Conf. RF Superconductivity (SRF'05), Ithaca, NY, USA, Jul. 2005, paper TUP62, pp. 385-387.
• Y. Kalboussi et al., “Material Engineering of ALD- Deposited Multilayer to Improve the Superconducting Performances of RF Cavities Under Intense RF Fields”, in Proc. 20th International Conference on RF Superconductivity (SRF'21), East Lansing, MI, USA, Jun.-Jul. 2021, paper FROFDV07, pp..
• E. Hemsing, A. Gover, and J. B. Rosenzweig, “A Virtual Dielectric Eigenmode Expansion of High-Gain FEL Radiation for Study of Paraxial Wave Mode Coupling”, in Proc. 30th Int. Free Electron Laser Conf. (FEL'08), Gyeongju, Korea, Aug. 2008, paper MOCAU01, pp. 167-171.