Efficient idler broadening via oppositely dual-chirped difference frequency generation

Haizhe Zhong; Bin Hu; Saisai Hu; Shengying Dai; Ying Li; Dianyuan Fan

doi:doi:10.1017/hpl.2020.24

High Power Laser Science and Engineering, 2020, 8 (2): 02000e27, Published Online: Jun. 29, 2020

Efficient idler broadening via oppositely dual-chirped difference frequency generation Download： 515次

Haizhe Zhong Bin Hu Saisai Hu Shengying Dai Ying Li ^*Dianyuan Fan

Author Affiliations

International Collaborative Laboratory of 2D Materials for Optoelectronic Science & Technology of Ministry of Education, Engineering Technology Research Center for 2D Material Information Function Devices and Systems of Guangdong Province, Shenzhen University, Shenzhen518060, China

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Haizhe Zhong, Bin Hu, Saisai Hu, Shengying Dai, Ying Li, Dianyuan Fan. Efficient idler broadening via oppositely dual-chirped difference frequency generation[J]. High Power Laser Science and Engineering, 2020, 8(2): 02000e27.

References

[1] T.Popmintchev,M. C.Chen,D.Popmintchev,P.Arpin,S.Brown,S.Alisauskas,G.Andriukaitis,T.Balciunas,A. D.Mücke,A.Pugzlys,A.Baltuska,B.Shim,S. E.Schrauth,A.Gaeta,C.Hernandez-Garcia,L.Plaja,A.Becker,A.Jaron-Becker,M. M.Murnane, and H. C.Kapteyn,Science336, 1287 (2012).

[2] S.Ghimire and D. A.Reis,Nat. Phys.15, 10 (2019).

[3] H. T.Kim,K. H.Pae,H. J.Cha,I. J.Kim,T. J.Yu,J. H.Sung,S. K.Lee,T. M.Jeong, and J.Lee,Phys. Rev. Lett.111, 165002 (2013).

[4] D.Woodbury,L.Feder,V.Shumakova,C.Gollner,R.Schwartz,B.Miao,F.Salehi,A.Korolov,A.Pugžlys,A.Baltuška, and H. M.Milchberg,Opt. Lett.43, 1131 (2018).

[5] F.Keilmann,C.Gohle, and R.Holzwarth,Opt. Lett.29, 1542 (2004).

[6] S.Cha,J. H.Sung,S.Sim,J.Park,H.Heo,M.Jo, and H.Choi,Nat. Commun.7, 10768 (2016).

[7] K.Zhao,H.Zhong,P.Yuan,G.Xie,J.Wang,J.Ma, and L.Qian,Opt. Lett.38, 2159 (2013).

[8] C.Xi,P.Wang,X.Li, and Z.Liu,High Power Laser Sci. Eng.7, e67 (2019).

[9] N.Ishii,P.Xia,T.Kanai, and J.Itatani,Opt. Express27, 11447 (2019).

[10] G.Cerullo and S. D.Silvestri,Rev. Sci. Instrum.74, 1 (2003).

[11] G.Andriukaitis,T.Balčiūnas,S.Ališauskas,A.Pugžlys,A.Baltuška,T.Popmintchev,M.Chen,M. M.Murnane, and H. C.Kapteyn,Opt. Lett.36, 2755 (2011).

[12] I.Pupeza,D.Sánchez,J.Zhang,N.Lilienfein,M.Seidel,N.Karpowicz,T.Paasch-Colberg,I.Znakovskaya,M.Pescher,W.Schweinberger,V.Pervak,E.Fill,O.Pronin,Z.Wei,F.Krausz,A.Apolonski, and J.Biegert,Nat. Photonics9, 721 (2015).

[13] Q.Zhang,E. J.Takahashi,O. D.Mücke,P.Lu, and K.Midorikawa,Opt. Express19, 7190 (2011).

[14] Y.Fua,B.Xue,K.Midorikawa, and E. J.Takahashi,Appl. Phys. Lett.112, 241105 (2018).

[15] Y.Fu,E. J.Takahashi,Q.Zhang,P.Lu, and K.Midorikawa,J. Opt.17, 124001 (2015).

[16] F.Raoult,A. C. L.Boscheron,D.Husson,C.Rouyer,C.Sauteret, and A.Migus,Opt. Lett.24, 354 (1999).

[17] O.Gobert,G.Mennerat,R.Maksimenka,N.Fedorov,M.Perdrix,D.Guillaumet,C.Ramond,J.Habib,C.Prigent,D.Vernhet,T.Oksenhendler, and M.Comte,Appl. Opt.53, 2646 (2014).

[18] H.Luo,L.Qian,P.Yuan, and H.Zhu,Opt. Express14, 10631 (2006).

[19] Y.Li,Y.Liang,D.Dai,J.Yang,H.Zhong, and D.Fan,Photon. Res.5, 669 (2017).

[20] B. W.Mayer,C. R.Phillips,L.Gallmann, and U.Keller,Opt. Express22, 20798 (2014).

[21] M.Mero and V.Petrov,IEEE Photonics J.9, 3200408 (2017).

[22] S.Witte and K. S. E.Eikema,IEEE J. Sel. Top. Quantum Electron.18, 296 (2011).

[23] O.Gayer,Z.Sacks,E.Galun, and A.Arie,Appl. Phys. B91, 343 (2008).

[24] P.Segonds,B.Boulanger,J.Fève,B.Ménaert,J.Zaccaro,G.Aka, and D.Pelenc,J. Opt. Soc. Am. B21, 765 (2004).

[25] K.Kato,IEEE J. Quantum Electron.30, 2950 (1994).

[26] H.Vanherzeele,J. D.Bierlein, and F. C.Zumsteg,Appl. Opt.27, 3314 (1988).

[27] J.Ma,J.Wang,P.Yuan,G.Xie,K.Xiong,Y.Tu,X.Tu,E.Shi,Y.Zheng, and L.Qian,Optica2, 1006 (2015).

[28] M.Leidinger,S.Fieberg,N.Waasem,F.Kühnemann,K.Buse, and I.Breunig,Opt. Express23, 21690 (2015).

[29] Y.Fu,E. J.Takahashi, and K.Midorikawa,Opt. Lett.40, 5082 (2015).

[30] Y.Yin,J.Li,X.Ren,Y.Wang,A.Chew, and Z.Chang,Opt. Express24, 24989 (2016).

[31] N.Bigler,J.Pupeikis,S.Hrisafov,L.Gallmann,C. R.Phillips, and U.Keller,Opt. Express26, 26750 (2018).

[32] M. Y.Hu,X. Y.Liang,B. Z.Zhao,R. X.Li, and Z. Z.Xu,Jpn. J. Appl. Phys.46, 5148 (2007).

[33] C.Neese,C. R.Phillips,L.Gallmann,M. M.Fejer, and U.Keller,Opt. Lett.35, 2340 (2010).

[34] N. E.Yu,J. H.Ro,M.Cha,S.Kurimura, and T.Taira,Opt. Lett.27, 1046 (2002).

[35] H.Zhong,L.Zhang,Y.Li, and D.Fan,Sci. Rep.5, 10887 (2015).

[36] Y.Li,H. Z.Zhong,J. L.Yang,S. W.Wang, and D. Y.Fan,Opt. Lett.42, 2806 (2017).

[37] V.Petrov and F.Noack,J. Opt. Soc. Am. B12, 2214 (1995).

[38] K.Osvay and I. N.Ross,J. Opt. Soc. Am. B13, 1431 (1996).

[39] S.Sukeert,S. C.Kumar, and M.Ebrahim-Zadeh,Opt. Lett.44, 5796 (2019).

[40] M. K.Reed,M. K.Steiner-Shepard, and D. K.Negus,Opt. Lett.19, 1855 (1994).

[41] A.Shirakawa and T.Kobayashi,Appl. Phys. Lett.72, 147 (1998).

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