Preparation and laser performances of Nd~(3+):GSGG ceramic powder raw materials
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摘要
This paper explores a new laser working material: gallium scandium gadolinium(GSGG), which was successfully prepared by one step co-precipitation method, and the potential properties of this Nd~(3+)doped laser ceramic raw materials were proposed. The size of the prepared powder was uniform and mainly about 65 nm. The GSGG phase could be obtained after a heat-treatment of 1000℃ for 4 h, and the characterized fluorescence decay curves showed that about 1 at.% concentration of Nd~(3+)in Nd~(3+):GSGG precursor presented optimum fluorescence intensity at 1.06 μm waveband.
This paper explores a new laser working material: gallium scandium gadolinium(GSGG), which was successfully prepared by one step co-precipitation method, and the potential properties of this Nd~(3+)doped laser ceramic raw materials were proposed. The size of the prepared powder was uniform and mainly about 65 nm. The GSGG phase could be obtained after a heat-treatment of 1000℃ for 4 h, and the characterized fluorescence decay curves showed that about 1 at.% concentration of Nd~(3+)in Nd~(3+):GSGG precursor presented optimum fluorescence intensity at 1.06 μm waveband.
This paper explores a new laser working material: gallium scandium gadolinium(GSGG), which was successfully prepared by one step co-precipitation method, and the potential properties of this Nd~(3+)doped laser ceramic raw materials were proposed. The size of the prepared powder was uniform and mainly about 65 nm. The GSGG phase could be obtained after a heat-treatment of 1000℃ for 4 h, and the characterized fluorescence decay curves showed that about 1 at.% concentration of Nd~(3+)in Nd~(3+):GSGG precursor presented optimum fluorescence intensity at 1.06 μm waveband.
引文
[1]D.L.Sun,J.Q.Luo,J.Z.Xiao,Q.L.Zhang,H.H.Jiang,S.T.Yin,Y.F.Wang,Appl.Phys.B 92(2008)529-533.
[2]J.Zhang,Y.Gao,J.Xiao,C.Xu,Y.Liu,J.Mater.Sci.Technol.29(2013)225-230.
[3]W.Li,K.Yang,S.Yin,X.Yang,Y.Xu,R.Lupoi,J.Mater.Sci.Technol.34(2018)440-457.
[4]G.A.Bufetova,M.Yu Gusev,I.A.Ivanov,N.S.Neustroev,D.A.Nikolaev,V.F.Seregin,Phys.Wave Phenom.17(2009)77-91.
[5]S.Wang,F.Kuang,Q.Ye,Y.Wang,M.Tang,C.Ge,J.Mater.Sci.Technol.32(2016)583-586.
[6]S.F.Wang,F.Gu,M.K.Lu,C.F.Song,S.W.Liu,D.Xu,D.R.Yuan,Mater.Res.Bull.18(2003)1283-1285.
[7]W.Liu,D.Zhang,Y.Zeng,J.Li,Y.Pan,J.Guo,Ceram.Int.38(2012)6969-6973.
[8]J.Pisarska,W.Ryba-Romanowski,G.Dominiak-Dzik,J.Alloys.Compd.451(2008)223-225.
[9]H.Cai,J.Zhou,T.Feng,Opt.Commun.281(2008)4401-4405.
[10]S.Wang,F.Kuang,D.Zhang,X.Zhou,M.Tang,J.Mater.Sci.Technol.31(2015)1158-1160.
[11]S.G.P.Strohmaier,H.J.Eichler,C.Czeranowsky,B.Ileri,K.Peter-mann,G.Huber,Opt.Commun.275(2007)170-172.
[12]J.Carreaud,R.Boulesteix,A.Ma?tre,Opt.Mater.35(2013)704-711.
[13]D.G.Ahn,K.W.Byun,M.C.Kang,Opt.Mater.26(2010)362-366.
[14]C.Li,F.Zhang,B.Meng,X.Rao,Y.Zhou,Mater.Des.125(2017)180-188.
[15]M.K.Aya,Photonics Lasers Med.4(2015)93-102.
[16]J.Yang,J.Yu,Y.Cui,Y.Huang,Ceram.Int.38(2012)3643-3648.
[17]S.Ding,Q.Zhang,W.Lu,J.Xu,W.Liu,J.Luo,X.Wang,D.Sun,Optik Int.J.Light Electron.Opt.148(2017)136-141.
[18]S.Wang,X.Wang,F.Kallmeyer,J.Chen,H.J.Eichier,Appl.Phys.B 92(2008)43-48.
[19]Y.Nie,M.Zhang,Y.Liu,Y.Zhao,J.Alloys Compd.657(2016)184-191.
[20]A.A.Aboud,H.Al-Kelesh,W.Rouby,A.A.Farghali,M.H.Khedr,J.Mater.Sci.Technol.7(2018)14-20.
[21]S.Sattayapon,G.Aka,P.Loiseau,A.Ikesue,Y.L.Aung,J.Alloys Compd.711(2017)446-454.
[22]R.P.Yavetskiy,S.V.Parkhomenko,I.O.Vorona,A.V.Tolmachev,Ceram.Int.40(2012)3561-3569.
[23]A.S.Attar,E.S.Sichani,S.Sharafi,J.Mater.Sci.Technol.6(2017)108-115.
[24]A.A.Silva-Moreno,M.A.Meneses Nava,O.Barbosa-Garcia,L.A.Diaz-Torres,F.Carrillo Romo,G.Boulon,Opt.Mater.16(2001)221-226.
[25]Z.Zhang,Y.Zhang,C.Wang,Z.Feng,H.Xia,J.Mater.Sci.Technol.33(2017)432-437.
[26]A.Lupei,V.Lupei,A.Ikesue,Opt.Maters 32(2010)1333-1336.
[27]Y.Yang,K.Li,G.Liu,Z.Zhao,J.Mater.Sci.Technol.33(2017)1195-1202.
[2]J.Zhang,Y.Gao,J.Xiao,C.Xu,Y.Liu,J.Mater.Sci.Technol.29(2013)225-230.
[3]W.Li,K.Yang,S.Yin,X.Yang,Y.Xu,R.Lupoi,J.Mater.Sci.Technol.34(2018)440-457.
[4]G.A.Bufetova,M.Yu Gusev,I.A.Ivanov,N.S.Neustroev,D.A.Nikolaev,V.F.Seregin,Phys.Wave Phenom.17(2009)77-91.
[5]S.Wang,F.Kuang,Q.Ye,Y.Wang,M.Tang,C.Ge,J.Mater.Sci.Technol.32(2016)583-586.
[6]S.F.Wang,F.Gu,M.K.Lu,C.F.Song,S.W.Liu,D.Xu,D.R.Yuan,Mater.Res.Bull.18(2003)1283-1285.
[7]W.Liu,D.Zhang,Y.Zeng,J.Li,Y.Pan,J.Guo,Ceram.Int.38(2012)6969-6973.
[8]J.Pisarska,W.Ryba-Romanowski,G.Dominiak-Dzik,J.Alloys.Compd.451(2008)223-225.
[9]H.Cai,J.Zhou,T.Feng,Opt.Commun.281(2008)4401-4405.
[10]S.Wang,F.Kuang,D.Zhang,X.Zhou,M.Tang,J.Mater.Sci.Technol.31(2015)1158-1160.
[11]S.G.P.Strohmaier,H.J.Eichler,C.Czeranowsky,B.Ileri,K.Peter-mann,G.Huber,Opt.Commun.275(2007)170-172.
[12]J.Carreaud,R.Boulesteix,A.Ma?tre,Opt.Mater.35(2013)704-711.
[13]D.G.Ahn,K.W.Byun,M.C.Kang,Opt.Mater.26(2010)362-366.
[14]C.Li,F.Zhang,B.Meng,X.Rao,Y.Zhou,Mater.Des.125(2017)180-188.
[15]M.K.Aya,Photonics Lasers Med.4(2015)93-102.
[16]J.Yang,J.Yu,Y.Cui,Y.Huang,Ceram.Int.38(2012)3643-3648.
[17]S.Ding,Q.Zhang,W.Lu,J.Xu,W.Liu,J.Luo,X.Wang,D.Sun,Optik Int.J.Light Electron.Opt.148(2017)136-141.
[18]S.Wang,X.Wang,F.Kallmeyer,J.Chen,H.J.Eichier,Appl.Phys.B 92(2008)43-48.
[19]Y.Nie,M.Zhang,Y.Liu,Y.Zhao,J.Alloys Compd.657(2016)184-191.
[20]A.A.Aboud,H.Al-Kelesh,W.Rouby,A.A.Farghali,M.H.Khedr,J.Mater.Sci.Technol.7(2018)14-20.
[21]S.Sattayapon,G.Aka,P.Loiseau,A.Ikesue,Y.L.Aung,J.Alloys Compd.711(2017)446-454.
[22]R.P.Yavetskiy,S.V.Parkhomenko,I.O.Vorona,A.V.Tolmachev,Ceram.Int.40(2012)3561-3569.
[23]A.S.Attar,E.S.Sichani,S.Sharafi,J.Mater.Sci.Technol.6(2017)108-115.
[24]A.A.Silva-Moreno,M.A.Meneses Nava,O.Barbosa-Garcia,L.A.Diaz-Torres,F.Carrillo Romo,G.Boulon,Opt.Mater.16(2001)221-226.
[25]Z.Zhang,Y.Zhang,C.Wang,Z.Feng,H.Xia,J.Mater.Sci.Technol.33(2017)432-437.
[26]A.Lupei,V.Lupei,A.Ikesue,Opt.Maters 32(2010)1333-1336.
[27]Y.Yang,K.Li,G.Liu,Z.Zhao,J.Mater.Sci.Technol.33(2017)1195-1202.