optical transition probabilities of er3
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Research ArticleOptical Transition Probabilities of Er3+ Ions inErBa3B9O18 Crystal
Ming He1 Tiezheng Liu2 Junling Xiu1 Yuanguang Tang1 and Zhihua Zhang2
1Department of Physics College of Science Dalian Jiaotong University Dalian 116028 China2Liaoning Key Materials Laboratory for Railway College of Materials Science and Engineering Dalian Jiaotong UniversityDalian 116028 China
Correspondence should be addressed to Ming He hemingdjtueducn
Received 13 October 2014 Revised 24 December 2014 Accepted 24 December 2014
Academic Editor Veer P S Awana
Copyright copy 2015 Ming He et alThis is an open access article distributed under the Creative Commons Attribution License whichpermits unrestricted use distribution and reproduction in any medium provided the original work is properly cited
The optical absorption and emission intensity of luminescent and birefringent crystal ErBa3B9O18
were examined from opticalabsorption data based on Judd-Ofelt theory The three intensity parametersΩ
119905(119905 = 2 4 6) are 310 times 10minus20 087 times 10minus20 and 180 times
10minus20 cm2 respectively From the obtained intensity parameters the radiative probabilities 119860119903 radiative lifetime 120591
119891 fluorescence
branching ratios120573119888 and integrated emission cross sectionssum have been calculated In comparisonwith other Er-doped luminescent
crystals ErBa3B9O18may find application in thin disk laser
1 Introduction
Er3+ activator has attracted much attention for its two laseremissions at 294 120583m (4I
112rarr4I132
) and 154 120583m (4I132
rarr
4I152
)The emissions have potential applications in optocom-munication sensors or lidar system [1ndash3] To now the Er3+ion has exhibited laser operations in various Er3+-dopedcrystals or glasses [4ndash9] For a laser crystal the host materialshould be stable and efficient Sometimes the emissionefficiency can be limited by the relatively low concentrationof luminescent centers because the quenching effect willoccur if the Er3+ ions concentration is too high Hostmaterialdetermines the luminescent efficiency of the laser crystal orphosphor in many cases Thus it is necessary to search fornew materials with higher doping tolerance to enhance theperformance of the laser
Borates are well known for their applications in opticalcommunications nonlinear optics luminescence materialand lasers and so forth [10ndash16] A series of isostructuralcompounds RBa
3B9O18
(R = Y Pr Nd Sm Eu Gd Tb DyHo Er Tm and Yb) [17 18] were found to exhibit good lumi-nescence properties under UV or X-ray excitations Theserare earth alkaline-earth isostructural compounds were firstidentified and structurally characterized by Li et al [19]
They crystallize in centric space group P63m with lattice
parameters of about 119886 = 717 A and 119888 = 1697 AThree O atomsare bonded to one B atom and three BO
3groups form a
planar hexagonal [B3O6]3minus ring [20] The parallel arranged
[B3O6]3minus groups can separate the R3+ ions which makes
the energy migration between two rare earth ions difficultTaking YBa
3B9O18
and ErBa3B9O18
(EBBO) as examplesthe shortest distance of two Y3+ or Er3+ ions is 716-717 Awhich is long enough to limit the energy transfer betweenluminescent centers [20ndash22] So the quenching effect inEBBO is proved to be small and Er3+ may be an efficientluminescent center The transition properties of the opticalcrystals can determine their luminescent performance So weperformed the research on spectroscopic properties of EBBO
2 Experimental
The crystals were grown by a pulling method [21] Anabsorption spectrum was measured for EBBO using a crystalplate with faces (001) and about 04mm thickness [23]The absorption spectrum was measured from ultraviolet toinfrared wavelength by the use of Lambda-900UVndashVISndashNIRspectrophotometer at room temperature
Hindawi Publishing CorporationJournal of SpectroscopyVolume 2015 Article ID 871320 4 pageshttpdxdoiorg1011552015871320
2 Journal of SpectroscopyAb
sorp
tion
18
09
00
Wavelength (nm)0 600 1200 1800
4G112
4F72
4F924I112
4I132
Figure 1The absorption spectra of EBBOcrystalThis figure is from[23] with permission
3 Results and Discussions
The spectrum presented in Figure 1 is measured in the wave-length ranges from 200 to 1700 nm The strong absorptionpeaks related to Er3+ ions transitions can be assigned Theabsorption bands located at 255 376 407 485 519 650 971and 1539 nm corresponding to the transitions from 4I
152to
4D72
4G112
2H112
4F72
4H112
4F92
4I112
and 4I132
respectively These strong absorption peaks show mainlythe eigenmultiplets typically observed in free Er3+ ions atsimilar spectral position due to the weak crystal field for rareearth ions The absorption at 1539 nm is very strong whichindicated that the transition probability of 4I
152rarr4I132
isbig and the integrated emission cross section is expected tobe great
The Judd-Ofelt theory was applied to evaluate the opticaltransition probabilities of Er3+ ions in EBBO Based onJudd-Ofelt theory of the parity-forbidden electric-dipoletransitions of rare earth ions [24 25] the electric andmagnetic dipole line strengths of a transition from initial 119869
119894
level to the terminal 119869119905level are described by
119878ed (119869119894 119869119905) = sum
119905=246
Ω119905
10038161003816100381610038161003816⟨Φ119869119894
10038171003817100381710038171003817119880(119905)10038171003817100381710038171003817
Φ119869119905⟩10038161003816100381610038161003816
2
119878md (119869119894 119869119905) = (ℎ
4120587119898119888)
2
sum
119905=246
Ω119905
10038161003816100381610038161003816⟨Φ119869119894119871 + 2119878Φ119869119905
⟩10038161003816100381610038161003816
2
(1)
where ℎ is Planckrsquos constant 119888 is the speed of light 119898 is themass of electron and ⟨Φ
119869119894119880(119905)Φ119869119905⟩ is the reduced matrix
elements depending on the Er3+ ions In this work the valuesof the squares of the reduced matrix elements are cited fromCarnallrsquos calculations [26] Ω
119905(119905 = 2 4 6) are the three
intensity parameters related to crystal field Magnetic dipoleline strengths are very small compared to electric ones andcan be neglected in the calculation of the parameters exceptfor 4I152
rarr4I132
The value of 119878md is cited from [27] to be
0683 times 10minus20 cm2 because 119878md does not vary with the hostcrystal
Then the measured line strengths 119878meased (119869
119894 119869119905) from the
absorption spectrum can be given by
119878meased (119869
119894 119869119905) =
9119899
(1198992 + 2)2[
3119888ℎ
812058731198902
2119869 + 1
119873119888
2303
120582119889
times int119869119894rarr119869119905
OD (120582) 119889120582 minus 119899119878md]
(2)
where 120582 is the mean wavelength of the absorption bandOD(120582) presents the measured optical density and 119889 is thethickness of the crystal The concentration of Er3+ ions 119873
119888
in ErBa3B9O18
is calculated based on the crystal structureparameter The crystal structure of ErBa
3B9O18
adopts acentric space group P6
3m and the lattice parameters are 119886 =
71817 A and 119888 = 16996 A [21] There are two Er3+ in one unitcell so119873
119888is calculated to be 263 times 1027m3 119899 is the refractive
index which can be obtained by Sellmeierrsquos equation [21] and119890 is the electron charge Table 1 presents the line strengths 119878edof nine absorption peaks of Er3+ in crystal Three intensityparametersΩ
119905(119905 = 2 4 6) were fitted by least-square method
to be 310 times 10minus20 087 times 10minus20 and 180 times 10minus20 cm2From Judd-Ofelt theory the electric-dipole andmagnetic-
dipole contributions 119860ed and 119860md of the total spontaneousemission probability are given by
1198601198691198691015840 = 119860ed + 119860md
=6412058741198902
3ℎ (2119869 + 1) 1205823
[
[
119899 (1198992+ 2)2
9119878ed + 119899
3119878md
]
]
= 1653 + 438 = 2091 (sminus1)
(3)
The luminescence parameters can be calculated from thefollowing equations
1198601198691198691015840 =
6412058741198902
3ℎ (2119869 + 1) 1205823
[
[
119899 (1198992+ 2)2
9119878ed + 119899
3119878md
]
]
1
120591119903
= sum
1198691015840
1198601198691198691015840
120573119888=
1198601198691198691015840
sum1198691015840 1198601198691198691015840
sum
1198691198691015840
=11986011986911986910158401205822
81205871198881198992
(4)
where 120573119888is the fluorescence branch ratio 120591
119903is the radiative
lifetime of a given upper level1198601198691198691015840 is the transition probabil-
ity of spontaneous emission and sum1198691198691015840 is the integrated emis-
sion cross section The calculated results are listed in Table 2The results show that radiative probabilities (209 sminus1) of
4I152
rarr4I132
are comparable to those of ErYAG (211 sminus1)
Journal of Spectroscopy 3
Table 1 Calculated strength parameters for Er3+ in EBBO
Peak Configuration Wavelength (nm) intOD(120582)119889120582 (nm) 119878meas (10minus20 cm2) 119878cal (10
minus20 cm2) Δ1199042
1 4I132
1539 2573 327 276 0262 4I
112971 083 020 080 036
3 4F92
650 209 075 132 0324 4H
112519 535 237 272 012
5 4F72
485 197 094 127 0116 2H
92407 053 029 043 002
7 4G112
376 629 377 350 0088 4D
72255 135 118 085 011
Rms-Δ119904 = 040 times 10minus20 cm2Ω246
= (310 087 180) times 10minus20 cm2
Table 2 The spectral parameters for Er3+ ions in EBBO crystal
Transitions Wavelength (nm) 119860 ed (sminus1) 119860md (s
minus1) 120591119903(120583s) 120573
119888sum1198691198691015840 (10minus18 cm)
4I132 rarr4I152 1539 16528 4376 4783 1 2243
4I112 rarr4I152 971 23332 3733 087 100
4I112 rarr4I132 2778 2585 868 013 1212
4F92 rarr4I152 650 158341 568 090 303
4F92 rarr4I132 1156 6849 004 042
4F92 rarr4I112 1980 10475 006 186
4F92 rarr4I92 3448 259 000 014
4S32 rarr4I132 844 85240 983 083 275
4S32 rarr4I112 1212 6672 007 044
4S32 rarr4I92 1639 9738 010 119
2H92 rarr4I152 407 161662 238 038 121
2H92 rarr4I132 555 204455 049 286
2H92 rarr4I112 703 47728 011 107
2H92 rarr4I92 841 18100 001 006
2H92 rarr4F92 1089 4136 001 022
4G112 rarr4I152 376 1950540
4D72 rarr4I152 255 2254450
4I92 rarr4I132 1739 7216
4H112 rarr4I152 519 542035
4F72 rarr4I152 485 465879
[28] Er119909Y1minus119909
Al3(BO3)4(233 sminus1) [29] and ErLa
2CaB10O19
(262 sminus1) [30] The integrated emission cross section of1539 nm is 224 times 10minus18 cm which indicates that large ampli-fication gains near 154 120583m are expected to be obtained Sothe crystal has the potential to be a laser material withgood chemical and physical properties What is more due tothe high concentrations of Er3+ activators EBBO may findapplications in thin disk laser
4 Conclusion
Thespectroscopic properties of ErBa3B9O18crystal have been
investigated at room temperature The Judd-Ofelt theory hasbeen applied to evaluate the optical transition probabilitiesof Er3+ ions in ErBa
3B9O18 Based on the Judd-Ofelt theory
the intensity parameters obtained by the least-square fittingmethodΩ
119905(119905 = 2 4 6) are 310times 10minus20 087times 10minus20 and 180 times
10minus20 cm2 respectively The radiative probabilities lifetimeand fluorescence branching ratios have been calculatedCompared with other Er-doped laser crystals ErBa
3B9O18
crystal has large integrated emission cross sections and radia-tive probabilities With good chemical and physical proper-ties ErBa
3B9O18may find application in thin disk laser
Conflict of Interests
The authors declare that there is no conflict of interestsregarding the publication of this paper
Acknowledgment
The authors gratefully acknowledge the support from theNational Natural Science Foundation of China (Grant nos51372026 and 51372027)
4 Journal of Spectroscopy
References
[1] Y Ding S Jiang B-C Hwang et al ldquoSpectral properties oferbium-doped lead halotellurite glasses for 15 120583m broadbandamplificationrdquo Optical Materials vol 15 no 2 pp 123ndash1302000
[2] J Breguet A F Umyskov S G Semenkov W Luthy H PWeber and I A Shcherbakov ldquoComparison of threshold energyof selectively excited YAlO
3Er andYAGEr lasersrdquo IEEE Journal
of Quantum Electronics vol 28 no 11 pp 2563ndash2566 1992[3] MYamada ldquoBroadband and gain-flattened amplifier composed
of a 155 [micro sign]m-band and a 158 [micro sign]m-band Er3+-doped fibre amplifier in a parallel configurationrdquoElectronics Letters vol 33 no 8 p 710 1997
[4] V P Gapontsev S M Matitsin A A Isineev and V BKravchenko ldquoErbium glass lasers and their applicationsrdquoOpticsamp Laser Technology vol 14 no 4 pp 189ndash196 1982
[5] J D Bradley J Dinnerman and P F Moulton ldquo3-120583m cw laseroperations in erbium-doped YSGG GGG and YAGrdquo OpticsLetters vol 19 no 15 pp 1143ndash1145 1994
[6] G J Kintz R Allen and L Esterowitz ldquoCW and pulsed28 120583m laser emission from diodeminuspumped Er3+LiYF
4at room
temperaturerdquo Applied Physics Letters vol 50 p 1553 1987[7] H Stange K Peterman G Huber and E W Duczynski
ldquoContinuous wave 16120583m laser action in Er doped garnets atroom temperaturerdquo Applied Physics B vol 49 no 3 pp 269ndash273 1989
[8] F Auzel S Hubert and D Meichenin ldquoMultifrequencyroomminustemperature continuous diode and Arlowast laserminuspumpedEr3+ laser emission between 266 and 285 120583mrdquo Applied PhysicsLetters vol 54 no 8 p 681 1989
[9] N Van Minh N Manh Hung D Thi Xuan Thao M Roef-faers and J Hofkens ldquoStructural and optical properties ofZnWO
4Er3+ crystalsrdquo Journal of Spectroscopy vol 2013 Article
ID 424185 5 pages 2013[10] L Wu X L Chen Q Y Tu et al ldquoPhase relations in the system
Li2O-MgO-B
2O3rdquo Journal of Alloys and Compounds vol 333
no 1-2 pp 154ndash158 2002[11] R C Stoneman and L Esterowitz ldquoEfficient resonantly pumped
28-120583m Er3+GSGG laserrdquo Optics Letters vol 17 no 11 p 8161992
[12] C Chen B Wu A Jiang and G You ldquoA new-type ultravioletSHG crystal 120573-BaB
2O4rdquo Scientia Sinica B vol 28 no 3 pp 235ndash
243 1985[13] M He X L Chen H Okudera and A Simon
ldquo(K1minus119909
Na119909)2Al2B2O7with 0 le 119909 lt 06 a promising nonlinear
optical crystalrdquo Chemistry of Materials vol 17 no 8 pp2193ndash2196 2005
[14] C Chen Y Wu A Jiang et al ldquoNew nonlinear-optical crystalLiB3O5rdquo Journal of the Optical Society of America B vol 6 no
4 pp 616ndash621 1989[15] LWu X L Chen H Li M He Y P Xu and X Z Li ldquoStructure
determination and relative properties of novel cubic boratesMM10158404(BO3)3(M = Li M1015840 = Sr M = Na M1015840 = Sr Ba)rdquo Inorganic
Chemistry vol 44 pp 6409ndash6414 2005[16] C Chen Y Wu and R Li ldquoThe relationship between the
structural type of anionic group and SHG effect in boron-oxygen compoundsrdquoChinese Physics Letters vol 2 no 9 p 3891985
[17] C Duan J Yuan and J Zhao ldquoLuminescence propertiesof efficient X-ray phosphors of YBa
3B9O18 LuBa
3(BO3)3 120572-
YBa3(BO3)3and LuBO
3rdquo Journal of Solid State Chemistry vol
178 no 12 pp 3698ndash3702 2005[18] C Duan J Yuan X Yang et al ldquoLuminescent properties of
REBa3B9O18
(RE = Lu Tb Gd Eu) under VUV excitationrdquoJournal of PhysicsDApplied Physics vol 38 no 19 p 3576 2005
[19] X Z Li C Wang X L Chen et al ldquoSyntheses thermalstability and structure determination of the novel isostructuralRBa3B9O18(R =Y Pr Nd Sm Eu Gd Tb Dy Ho Er Tm Yb)rdquo
Inorganic Chemistry vol 43 no 26 pp 8555ndash8560 2004[20] M He W Y Wang Y P Sun Y P Xu and X L Chen ldquoGrowth
and optical properties of YBa3B9O18Ce crystalsrdquo Journal of
Crystal Growth vol 307 no 2 pp 427ndash431 2007[21] MHe GM CaiW JWangW YWang J Liu andX L Chen
ldquoGrowth and luminescence properties of a novel crystal withlarge birefringence ErBa
3B9O18rdquo Journal of Crystal Growth vol
311 no 4 pp 1234ndash1237 2009[22] M He X L Chen Y P Sun J Liu J T Zhao and C J Duan
ldquoYBa3B9O18 a promising scintillation crystalrdquo Crystal Growth
amp Design vol 7 no 2 pp 199ndash201 2007[23] M He T Z Liu M H Qiu et al ldquoStudy on the optical proper-
ties of ErBa3B9O18crystalsrdquo Physica B Condensed Matter vol
456 pp 100ndash102 2015[24] B R Judd ldquoOptical absorption intensities of rare-earth ionsrdquo
Physical Review vol 127 no 3 pp 750ndash761 1962[25] G S Ofelt ldquoIntensities of crystal spectra of rare-earth ionsrdquoThe
Journal of Chemical Physics vol 37 no 3 p 511 1962[26] W T Carnall P R Fields and K Rajnak ldquoElectronic energy
levels in the trivalent lanthanide aquo ions I Pr3+ Nd3+ Pm3+Sm3+ Dy3+ Ho3+ Er3+ and Tm3+rdquo The Journal of ChemicalPhysics vol 49 p 4424 1968
[27] W T Carnall P R Fields and K Rajnak ldquoElectronic energylevels in the trivalent lanthanide aquo ions I Pr3+ Nd3+ Pm3+Sm3+ Dy3+ Ho3+ Er3+ and Tm3+rdquo The Journal of ChemicalPhysics vol 49 no 10 pp 4414ndash4442 1968
[28] R ReisfeldThe Rare Earths in Modern Sciences and TechnologyPlenum Press New York NY USA 1979
[29] M G Liu B S Lu H F Pan and Q Song ldquoErxY1minusxAl3(BO3)4crystal growth and its spectral propertiesrdquo Acta Optical Sinicavol 8 pp 1079ndash1084 1988
[30] RGuo YWu P Fu and F Jing ldquoOptical transition probabilitiesof Er3+ ions in La
2CaB10O19crystalrdquo Chemical Physics Letters
vol 416 no 1ndash3 pp 133ndash136 2005
Submit your manuscripts athttpwwwhindawicom
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
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Journal of
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Bioinorganic Chemistry and ApplicationsHindawi Publishing Corporationhttpwwwhindawicom Volume 2014
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Analytical ChemistryInternational Journal of
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Quantum Chemistry
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Organic Chemistry International
ElectrochemistryInternational Journal of
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Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
CatalystsJournal of
2 Journal of SpectroscopyAb
sorp
tion
18
09
00
Wavelength (nm)0 600 1200 1800
4G112
4F72
4F924I112
4I132
Figure 1The absorption spectra of EBBOcrystalThis figure is from[23] with permission
3 Results and Discussions
The spectrum presented in Figure 1 is measured in the wave-length ranges from 200 to 1700 nm The strong absorptionpeaks related to Er3+ ions transitions can be assigned Theabsorption bands located at 255 376 407 485 519 650 971and 1539 nm corresponding to the transitions from 4I
152to
4D72
4G112
2H112
4F72
4H112
4F92
4I112
and 4I132
respectively These strong absorption peaks show mainlythe eigenmultiplets typically observed in free Er3+ ions atsimilar spectral position due to the weak crystal field for rareearth ions The absorption at 1539 nm is very strong whichindicated that the transition probability of 4I
152rarr4I132
isbig and the integrated emission cross section is expected tobe great
The Judd-Ofelt theory was applied to evaluate the opticaltransition probabilities of Er3+ ions in EBBO Based onJudd-Ofelt theory of the parity-forbidden electric-dipoletransitions of rare earth ions [24 25] the electric andmagnetic dipole line strengths of a transition from initial 119869
119894
level to the terminal 119869119905level are described by
119878ed (119869119894 119869119905) = sum
119905=246
Ω119905
10038161003816100381610038161003816⟨Φ119869119894
10038171003817100381710038171003817119880(119905)10038171003817100381710038171003817
Φ119869119905⟩10038161003816100381610038161003816
2
119878md (119869119894 119869119905) = (ℎ
4120587119898119888)
2
sum
119905=246
Ω119905
10038161003816100381610038161003816⟨Φ119869119894119871 + 2119878Φ119869119905
⟩10038161003816100381610038161003816
2
(1)
where ℎ is Planckrsquos constant 119888 is the speed of light 119898 is themass of electron and ⟨Φ
119869119894119880(119905)Φ119869119905⟩ is the reduced matrix
elements depending on the Er3+ ions In this work the valuesof the squares of the reduced matrix elements are cited fromCarnallrsquos calculations [26] Ω
119905(119905 = 2 4 6) are the three
intensity parameters related to crystal field Magnetic dipoleline strengths are very small compared to electric ones andcan be neglected in the calculation of the parameters exceptfor 4I152
rarr4I132
The value of 119878md is cited from [27] to be
0683 times 10minus20 cm2 because 119878md does not vary with the hostcrystal
Then the measured line strengths 119878meased (119869
119894 119869119905) from the
absorption spectrum can be given by
119878meased (119869
119894 119869119905) =
9119899
(1198992 + 2)2[
3119888ℎ
812058731198902
2119869 + 1
119873119888
2303
120582119889
times int119869119894rarr119869119905
OD (120582) 119889120582 minus 119899119878md]
(2)
where 120582 is the mean wavelength of the absorption bandOD(120582) presents the measured optical density and 119889 is thethickness of the crystal The concentration of Er3+ ions 119873
119888
in ErBa3B9O18
is calculated based on the crystal structureparameter The crystal structure of ErBa
3B9O18
adopts acentric space group P6
3m and the lattice parameters are 119886 =
71817 A and 119888 = 16996 A [21] There are two Er3+ in one unitcell so119873
119888is calculated to be 263 times 1027m3 119899 is the refractive
index which can be obtained by Sellmeierrsquos equation [21] and119890 is the electron charge Table 1 presents the line strengths 119878edof nine absorption peaks of Er3+ in crystal Three intensityparametersΩ
119905(119905 = 2 4 6) were fitted by least-square method
to be 310 times 10minus20 087 times 10minus20 and 180 times 10minus20 cm2From Judd-Ofelt theory the electric-dipole andmagnetic-
dipole contributions 119860ed and 119860md of the total spontaneousemission probability are given by
1198601198691198691015840 = 119860ed + 119860md
=6412058741198902
3ℎ (2119869 + 1) 1205823
[
[
119899 (1198992+ 2)2
9119878ed + 119899
3119878md
]
]
= 1653 + 438 = 2091 (sminus1)
(3)
The luminescence parameters can be calculated from thefollowing equations
1198601198691198691015840 =
6412058741198902
3ℎ (2119869 + 1) 1205823
[
[
119899 (1198992+ 2)2
9119878ed + 119899
3119878md
]
]
1
120591119903
= sum
1198691015840
1198601198691198691015840
120573119888=
1198601198691198691015840
sum1198691015840 1198601198691198691015840
sum
1198691198691015840
=11986011986911986910158401205822
81205871198881198992
(4)
where 120573119888is the fluorescence branch ratio 120591
119903is the radiative
lifetime of a given upper level1198601198691198691015840 is the transition probabil-
ity of spontaneous emission and sum1198691198691015840 is the integrated emis-
sion cross section The calculated results are listed in Table 2The results show that radiative probabilities (209 sminus1) of
4I152
rarr4I132
are comparable to those of ErYAG (211 sminus1)
Journal of Spectroscopy 3
Table 1 Calculated strength parameters for Er3+ in EBBO
Peak Configuration Wavelength (nm) intOD(120582)119889120582 (nm) 119878meas (10minus20 cm2) 119878cal (10
minus20 cm2) Δ1199042
1 4I132
1539 2573 327 276 0262 4I
112971 083 020 080 036
3 4F92
650 209 075 132 0324 4H
112519 535 237 272 012
5 4F72
485 197 094 127 0116 2H
92407 053 029 043 002
7 4G112
376 629 377 350 0088 4D
72255 135 118 085 011
Rms-Δ119904 = 040 times 10minus20 cm2Ω246
= (310 087 180) times 10minus20 cm2
Table 2 The spectral parameters for Er3+ ions in EBBO crystal
Transitions Wavelength (nm) 119860 ed (sminus1) 119860md (s
minus1) 120591119903(120583s) 120573
119888sum1198691198691015840 (10minus18 cm)
4I132 rarr4I152 1539 16528 4376 4783 1 2243
4I112 rarr4I152 971 23332 3733 087 100
4I112 rarr4I132 2778 2585 868 013 1212
4F92 rarr4I152 650 158341 568 090 303
4F92 rarr4I132 1156 6849 004 042
4F92 rarr4I112 1980 10475 006 186
4F92 rarr4I92 3448 259 000 014
4S32 rarr4I132 844 85240 983 083 275
4S32 rarr4I112 1212 6672 007 044
4S32 rarr4I92 1639 9738 010 119
2H92 rarr4I152 407 161662 238 038 121
2H92 rarr4I132 555 204455 049 286
2H92 rarr4I112 703 47728 011 107
2H92 rarr4I92 841 18100 001 006
2H92 rarr4F92 1089 4136 001 022
4G112 rarr4I152 376 1950540
4D72 rarr4I152 255 2254450
4I92 rarr4I132 1739 7216
4H112 rarr4I152 519 542035
4F72 rarr4I152 485 465879
[28] Er119909Y1minus119909
Al3(BO3)4(233 sminus1) [29] and ErLa
2CaB10O19
(262 sminus1) [30] The integrated emission cross section of1539 nm is 224 times 10minus18 cm which indicates that large ampli-fication gains near 154 120583m are expected to be obtained Sothe crystal has the potential to be a laser material withgood chemical and physical properties What is more due tothe high concentrations of Er3+ activators EBBO may findapplications in thin disk laser
4 Conclusion
Thespectroscopic properties of ErBa3B9O18crystal have been
investigated at room temperature The Judd-Ofelt theory hasbeen applied to evaluate the optical transition probabilitiesof Er3+ ions in ErBa
3B9O18 Based on the Judd-Ofelt theory
the intensity parameters obtained by the least-square fittingmethodΩ
119905(119905 = 2 4 6) are 310times 10minus20 087times 10minus20 and 180 times
10minus20 cm2 respectively The radiative probabilities lifetimeand fluorescence branching ratios have been calculatedCompared with other Er-doped laser crystals ErBa
3B9O18
crystal has large integrated emission cross sections and radia-tive probabilities With good chemical and physical proper-ties ErBa
3B9O18may find application in thin disk laser
Conflict of Interests
The authors declare that there is no conflict of interestsregarding the publication of this paper
Acknowledgment
The authors gratefully acknowledge the support from theNational Natural Science Foundation of China (Grant nos51372026 and 51372027)
4 Journal of Spectroscopy
References
[1] Y Ding S Jiang B-C Hwang et al ldquoSpectral properties oferbium-doped lead halotellurite glasses for 15 120583m broadbandamplificationrdquo Optical Materials vol 15 no 2 pp 123ndash1302000
[2] J Breguet A F Umyskov S G Semenkov W Luthy H PWeber and I A Shcherbakov ldquoComparison of threshold energyof selectively excited YAlO
3Er andYAGEr lasersrdquo IEEE Journal
of Quantum Electronics vol 28 no 11 pp 2563ndash2566 1992[3] MYamada ldquoBroadband and gain-flattened amplifier composed
of a 155 [micro sign]m-band and a 158 [micro sign]m-band Er3+-doped fibre amplifier in a parallel configurationrdquoElectronics Letters vol 33 no 8 p 710 1997
[4] V P Gapontsev S M Matitsin A A Isineev and V BKravchenko ldquoErbium glass lasers and their applicationsrdquoOpticsamp Laser Technology vol 14 no 4 pp 189ndash196 1982
[5] J D Bradley J Dinnerman and P F Moulton ldquo3-120583m cw laseroperations in erbium-doped YSGG GGG and YAGrdquo OpticsLetters vol 19 no 15 pp 1143ndash1145 1994
[6] G J Kintz R Allen and L Esterowitz ldquoCW and pulsed28 120583m laser emission from diodeminuspumped Er3+LiYF
4at room
temperaturerdquo Applied Physics Letters vol 50 p 1553 1987[7] H Stange K Peterman G Huber and E W Duczynski
ldquoContinuous wave 16120583m laser action in Er doped garnets atroom temperaturerdquo Applied Physics B vol 49 no 3 pp 269ndash273 1989
[8] F Auzel S Hubert and D Meichenin ldquoMultifrequencyroomminustemperature continuous diode and Arlowast laserminuspumpedEr3+ laser emission between 266 and 285 120583mrdquo Applied PhysicsLetters vol 54 no 8 p 681 1989
[9] N Van Minh N Manh Hung D Thi Xuan Thao M Roef-faers and J Hofkens ldquoStructural and optical properties ofZnWO
4Er3+ crystalsrdquo Journal of Spectroscopy vol 2013 Article
ID 424185 5 pages 2013[10] L Wu X L Chen Q Y Tu et al ldquoPhase relations in the system
Li2O-MgO-B
2O3rdquo Journal of Alloys and Compounds vol 333
no 1-2 pp 154ndash158 2002[11] R C Stoneman and L Esterowitz ldquoEfficient resonantly pumped
28-120583m Er3+GSGG laserrdquo Optics Letters vol 17 no 11 p 8161992
[12] C Chen B Wu A Jiang and G You ldquoA new-type ultravioletSHG crystal 120573-BaB
2O4rdquo Scientia Sinica B vol 28 no 3 pp 235ndash
243 1985[13] M He X L Chen H Okudera and A Simon
ldquo(K1minus119909
Na119909)2Al2B2O7with 0 le 119909 lt 06 a promising nonlinear
optical crystalrdquo Chemistry of Materials vol 17 no 8 pp2193ndash2196 2005
[14] C Chen Y Wu A Jiang et al ldquoNew nonlinear-optical crystalLiB3O5rdquo Journal of the Optical Society of America B vol 6 no
4 pp 616ndash621 1989[15] LWu X L Chen H Li M He Y P Xu and X Z Li ldquoStructure
determination and relative properties of novel cubic boratesMM10158404(BO3)3(M = Li M1015840 = Sr M = Na M1015840 = Sr Ba)rdquo Inorganic
Chemistry vol 44 pp 6409ndash6414 2005[16] C Chen Y Wu and R Li ldquoThe relationship between the
structural type of anionic group and SHG effect in boron-oxygen compoundsrdquoChinese Physics Letters vol 2 no 9 p 3891985
[17] C Duan J Yuan and J Zhao ldquoLuminescence propertiesof efficient X-ray phosphors of YBa
3B9O18 LuBa
3(BO3)3 120572-
YBa3(BO3)3and LuBO
3rdquo Journal of Solid State Chemistry vol
178 no 12 pp 3698ndash3702 2005[18] C Duan J Yuan X Yang et al ldquoLuminescent properties of
REBa3B9O18
(RE = Lu Tb Gd Eu) under VUV excitationrdquoJournal of PhysicsDApplied Physics vol 38 no 19 p 3576 2005
[19] X Z Li C Wang X L Chen et al ldquoSyntheses thermalstability and structure determination of the novel isostructuralRBa3B9O18(R =Y Pr Nd Sm Eu Gd Tb Dy Ho Er Tm Yb)rdquo
Inorganic Chemistry vol 43 no 26 pp 8555ndash8560 2004[20] M He W Y Wang Y P Sun Y P Xu and X L Chen ldquoGrowth
and optical properties of YBa3B9O18Ce crystalsrdquo Journal of
Crystal Growth vol 307 no 2 pp 427ndash431 2007[21] MHe GM CaiW JWangW YWang J Liu andX L Chen
ldquoGrowth and luminescence properties of a novel crystal withlarge birefringence ErBa
3B9O18rdquo Journal of Crystal Growth vol
311 no 4 pp 1234ndash1237 2009[22] M He X L Chen Y P Sun J Liu J T Zhao and C J Duan
ldquoYBa3B9O18 a promising scintillation crystalrdquo Crystal Growth
amp Design vol 7 no 2 pp 199ndash201 2007[23] M He T Z Liu M H Qiu et al ldquoStudy on the optical proper-
ties of ErBa3B9O18crystalsrdquo Physica B Condensed Matter vol
456 pp 100ndash102 2015[24] B R Judd ldquoOptical absorption intensities of rare-earth ionsrdquo
Physical Review vol 127 no 3 pp 750ndash761 1962[25] G S Ofelt ldquoIntensities of crystal spectra of rare-earth ionsrdquoThe
Journal of Chemical Physics vol 37 no 3 p 511 1962[26] W T Carnall P R Fields and K Rajnak ldquoElectronic energy
levels in the trivalent lanthanide aquo ions I Pr3+ Nd3+ Pm3+Sm3+ Dy3+ Ho3+ Er3+ and Tm3+rdquo The Journal of ChemicalPhysics vol 49 p 4424 1968
[27] W T Carnall P R Fields and K Rajnak ldquoElectronic energylevels in the trivalent lanthanide aquo ions I Pr3+ Nd3+ Pm3+Sm3+ Dy3+ Ho3+ Er3+ and Tm3+rdquo The Journal of ChemicalPhysics vol 49 no 10 pp 4414ndash4442 1968
[28] R ReisfeldThe Rare Earths in Modern Sciences and TechnologyPlenum Press New York NY USA 1979
[29] M G Liu B S Lu H F Pan and Q Song ldquoErxY1minusxAl3(BO3)4crystal growth and its spectral propertiesrdquo Acta Optical Sinicavol 8 pp 1079ndash1084 1988
[30] RGuo YWu P Fu and F Jing ldquoOptical transition probabilitiesof Er3+ ions in La
2CaB10O19crystalrdquo Chemical Physics Letters
vol 416 no 1ndash3 pp 133ndash136 2005
Submit your manuscripts athttpwwwhindawicom
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Inorganic ChemistryInternational Journal of
Hindawi Publishing Corporation httpwwwhindawicom Volume 2014
International Journal ofPhotoenergy
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Carbohydrate Chemistry
International Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Journal of
Chemistry
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Advances in
Physical Chemistry
Hindawi Publishing Corporationhttpwwwhindawicom
Analytical Methods in Chemistry
Journal of
Volume 2014
Bioinorganic Chemistry and ApplicationsHindawi Publishing Corporationhttpwwwhindawicom Volume 2014
SpectroscopyInternational Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
The Scientific World JournalHindawi Publishing Corporation httpwwwhindawicom Volume 2014
Medicinal ChemistryInternational Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Chromatography Research International
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Applied ChemistryJournal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Theoretical ChemistryJournal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Journal of
Spectroscopy
Analytical ChemistryInternational Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Quantum Chemistry
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Organic Chemistry International
ElectrochemistryInternational Journal of
Hindawi Publishing Corporation httpwwwhindawicom Volume 2014
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
CatalystsJournal of
Journal of Spectroscopy 3
Table 1 Calculated strength parameters for Er3+ in EBBO
Peak Configuration Wavelength (nm) intOD(120582)119889120582 (nm) 119878meas (10minus20 cm2) 119878cal (10
minus20 cm2) Δ1199042
1 4I132
1539 2573 327 276 0262 4I
112971 083 020 080 036
3 4F92
650 209 075 132 0324 4H
112519 535 237 272 012
5 4F72
485 197 094 127 0116 2H
92407 053 029 043 002
7 4G112
376 629 377 350 0088 4D
72255 135 118 085 011
Rms-Δ119904 = 040 times 10minus20 cm2Ω246
= (310 087 180) times 10minus20 cm2
Table 2 The spectral parameters for Er3+ ions in EBBO crystal
Transitions Wavelength (nm) 119860 ed (sminus1) 119860md (s
minus1) 120591119903(120583s) 120573
119888sum1198691198691015840 (10minus18 cm)
4I132 rarr4I152 1539 16528 4376 4783 1 2243
4I112 rarr4I152 971 23332 3733 087 100
4I112 rarr4I132 2778 2585 868 013 1212
4F92 rarr4I152 650 158341 568 090 303
4F92 rarr4I132 1156 6849 004 042
4F92 rarr4I112 1980 10475 006 186
4F92 rarr4I92 3448 259 000 014
4S32 rarr4I132 844 85240 983 083 275
4S32 rarr4I112 1212 6672 007 044
4S32 rarr4I92 1639 9738 010 119
2H92 rarr4I152 407 161662 238 038 121
2H92 rarr4I132 555 204455 049 286
2H92 rarr4I112 703 47728 011 107
2H92 rarr4I92 841 18100 001 006
2H92 rarr4F92 1089 4136 001 022
4G112 rarr4I152 376 1950540
4D72 rarr4I152 255 2254450
4I92 rarr4I132 1739 7216
4H112 rarr4I152 519 542035
4F72 rarr4I152 485 465879
[28] Er119909Y1minus119909
Al3(BO3)4(233 sminus1) [29] and ErLa
2CaB10O19
(262 sminus1) [30] The integrated emission cross section of1539 nm is 224 times 10minus18 cm which indicates that large ampli-fication gains near 154 120583m are expected to be obtained Sothe crystal has the potential to be a laser material withgood chemical and physical properties What is more due tothe high concentrations of Er3+ activators EBBO may findapplications in thin disk laser
4 Conclusion
Thespectroscopic properties of ErBa3B9O18crystal have been
investigated at room temperature The Judd-Ofelt theory hasbeen applied to evaluate the optical transition probabilitiesof Er3+ ions in ErBa
3B9O18 Based on the Judd-Ofelt theory
the intensity parameters obtained by the least-square fittingmethodΩ
119905(119905 = 2 4 6) are 310times 10minus20 087times 10minus20 and 180 times
10minus20 cm2 respectively The radiative probabilities lifetimeand fluorescence branching ratios have been calculatedCompared with other Er-doped laser crystals ErBa
3B9O18
crystal has large integrated emission cross sections and radia-tive probabilities With good chemical and physical proper-ties ErBa
3B9O18may find application in thin disk laser
Conflict of Interests
The authors declare that there is no conflict of interestsregarding the publication of this paper
Acknowledgment
The authors gratefully acknowledge the support from theNational Natural Science Foundation of China (Grant nos51372026 and 51372027)
4 Journal of Spectroscopy
References
[1] Y Ding S Jiang B-C Hwang et al ldquoSpectral properties oferbium-doped lead halotellurite glasses for 15 120583m broadbandamplificationrdquo Optical Materials vol 15 no 2 pp 123ndash1302000
[2] J Breguet A F Umyskov S G Semenkov W Luthy H PWeber and I A Shcherbakov ldquoComparison of threshold energyof selectively excited YAlO
3Er andYAGEr lasersrdquo IEEE Journal
of Quantum Electronics vol 28 no 11 pp 2563ndash2566 1992[3] MYamada ldquoBroadband and gain-flattened amplifier composed
of a 155 [micro sign]m-band and a 158 [micro sign]m-band Er3+-doped fibre amplifier in a parallel configurationrdquoElectronics Letters vol 33 no 8 p 710 1997
[4] V P Gapontsev S M Matitsin A A Isineev and V BKravchenko ldquoErbium glass lasers and their applicationsrdquoOpticsamp Laser Technology vol 14 no 4 pp 189ndash196 1982
[5] J D Bradley J Dinnerman and P F Moulton ldquo3-120583m cw laseroperations in erbium-doped YSGG GGG and YAGrdquo OpticsLetters vol 19 no 15 pp 1143ndash1145 1994
[6] G J Kintz R Allen and L Esterowitz ldquoCW and pulsed28 120583m laser emission from diodeminuspumped Er3+LiYF
4at room
temperaturerdquo Applied Physics Letters vol 50 p 1553 1987[7] H Stange K Peterman G Huber and E W Duczynski
ldquoContinuous wave 16120583m laser action in Er doped garnets atroom temperaturerdquo Applied Physics B vol 49 no 3 pp 269ndash273 1989
[8] F Auzel S Hubert and D Meichenin ldquoMultifrequencyroomminustemperature continuous diode and Arlowast laserminuspumpedEr3+ laser emission between 266 and 285 120583mrdquo Applied PhysicsLetters vol 54 no 8 p 681 1989
[9] N Van Minh N Manh Hung D Thi Xuan Thao M Roef-faers and J Hofkens ldquoStructural and optical properties ofZnWO
4Er3+ crystalsrdquo Journal of Spectroscopy vol 2013 Article
ID 424185 5 pages 2013[10] L Wu X L Chen Q Y Tu et al ldquoPhase relations in the system
Li2O-MgO-B
2O3rdquo Journal of Alloys and Compounds vol 333
no 1-2 pp 154ndash158 2002[11] R C Stoneman and L Esterowitz ldquoEfficient resonantly pumped
28-120583m Er3+GSGG laserrdquo Optics Letters vol 17 no 11 p 8161992
[12] C Chen B Wu A Jiang and G You ldquoA new-type ultravioletSHG crystal 120573-BaB
2O4rdquo Scientia Sinica B vol 28 no 3 pp 235ndash
243 1985[13] M He X L Chen H Okudera and A Simon
ldquo(K1minus119909
Na119909)2Al2B2O7with 0 le 119909 lt 06 a promising nonlinear
optical crystalrdquo Chemistry of Materials vol 17 no 8 pp2193ndash2196 2005
[14] C Chen Y Wu A Jiang et al ldquoNew nonlinear-optical crystalLiB3O5rdquo Journal of the Optical Society of America B vol 6 no
4 pp 616ndash621 1989[15] LWu X L Chen H Li M He Y P Xu and X Z Li ldquoStructure
determination and relative properties of novel cubic boratesMM10158404(BO3)3(M = Li M1015840 = Sr M = Na M1015840 = Sr Ba)rdquo Inorganic
Chemistry vol 44 pp 6409ndash6414 2005[16] C Chen Y Wu and R Li ldquoThe relationship between the
structural type of anionic group and SHG effect in boron-oxygen compoundsrdquoChinese Physics Letters vol 2 no 9 p 3891985
[17] C Duan J Yuan and J Zhao ldquoLuminescence propertiesof efficient X-ray phosphors of YBa
3B9O18 LuBa
3(BO3)3 120572-
YBa3(BO3)3and LuBO
3rdquo Journal of Solid State Chemistry vol
178 no 12 pp 3698ndash3702 2005[18] C Duan J Yuan X Yang et al ldquoLuminescent properties of
REBa3B9O18
(RE = Lu Tb Gd Eu) under VUV excitationrdquoJournal of PhysicsDApplied Physics vol 38 no 19 p 3576 2005
[19] X Z Li C Wang X L Chen et al ldquoSyntheses thermalstability and structure determination of the novel isostructuralRBa3B9O18(R =Y Pr Nd Sm Eu Gd Tb Dy Ho Er Tm Yb)rdquo
Inorganic Chemistry vol 43 no 26 pp 8555ndash8560 2004[20] M He W Y Wang Y P Sun Y P Xu and X L Chen ldquoGrowth
and optical properties of YBa3B9O18Ce crystalsrdquo Journal of
Crystal Growth vol 307 no 2 pp 427ndash431 2007[21] MHe GM CaiW JWangW YWang J Liu andX L Chen
ldquoGrowth and luminescence properties of a novel crystal withlarge birefringence ErBa
3B9O18rdquo Journal of Crystal Growth vol
311 no 4 pp 1234ndash1237 2009[22] M He X L Chen Y P Sun J Liu J T Zhao and C J Duan
ldquoYBa3B9O18 a promising scintillation crystalrdquo Crystal Growth
amp Design vol 7 no 2 pp 199ndash201 2007[23] M He T Z Liu M H Qiu et al ldquoStudy on the optical proper-
ties of ErBa3B9O18crystalsrdquo Physica B Condensed Matter vol
456 pp 100ndash102 2015[24] B R Judd ldquoOptical absorption intensities of rare-earth ionsrdquo
Physical Review vol 127 no 3 pp 750ndash761 1962[25] G S Ofelt ldquoIntensities of crystal spectra of rare-earth ionsrdquoThe
Journal of Chemical Physics vol 37 no 3 p 511 1962[26] W T Carnall P R Fields and K Rajnak ldquoElectronic energy
levels in the trivalent lanthanide aquo ions I Pr3+ Nd3+ Pm3+Sm3+ Dy3+ Ho3+ Er3+ and Tm3+rdquo The Journal of ChemicalPhysics vol 49 p 4424 1968
[27] W T Carnall P R Fields and K Rajnak ldquoElectronic energylevels in the trivalent lanthanide aquo ions I Pr3+ Nd3+ Pm3+Sm3+ Dy3+ Ho3+ Er3+ and Tm3+rdquo The Journal of ChemicalPhysics vol 49 no 10 pp 4414ndash4442 1968
[28] R ReisfeldThe Rare Earths in Modern Sciences and TechnologyPlenum Press New York NY USA 1979
[29] M G Liu B S Lu H F Pan and Q Song ldquoErxY1minusxAl3(BO3)4crystal growth and its spectral propertiesrdquo Acta Optical Sinicavol 8 pp 1079ndash1084 1988
[30] RGuo YWu P Fu and F Jing ldquoOptical transition probabilitiesof Er3+ ions in La
2CaB10O19crystalrdquo Chemical Physics Letters
vol 416 no 1ndash3 pp 133ndash136 2005
Submit your manuscripts athttpwwwhindawicom
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Inorganic ChemistryInternational Journal of
Hindawi Publishing Corporation httpwwwhindawicom Volume 2014
International Journal ofPhotoenergy
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Carbohydrate Chemistry
International Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Journal of
Chemistry
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Advances in
Physical Chemistry
Hindawi Publishing Corporationhttpwwwhindawicom
Analytical Methods in Chemistry
Journal of
Volume 2014
Bioinorganic Chemistry and ApplicationsHindawi Publishing Corporationhttpwwwhindawicom Volume 2014
SpectroscopyInternational Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
The Scientific World JournalHindawi Publishing Corporation httpwwwhindawicom Volume 2014
Medicinal ChemistryInternational Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Chromatography Research International
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Applied ChemistryJournal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Theoretical ChemistryJournal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Journal of
Spectroscopy
Analytical ChemistryInternational Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Quantum Chemistry
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Organic Chemistry International
ElectrochemistryInternational Journal of
Hindawi Publishing Corporation httpwwwhindawicom Volume 2014
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
CatalystsJournal of
4 Journal of Spectroscopy
References
[1] Y Ding S Jiang B-C Hwang et al ldquoSpectral properties oferbium-doped lead halotellurite glasses for 15 120583m broadbandamplificationrdquo Optical Materials vol 15 no 2 pp 123ndash1302000
[2] J Breguet A F Umyskov S G Semenkov W Luthy H PWeber and I A Shcherbakov ldquoComparison of threshold energyof selectively excited YAlO
3Er andYAGEr lasersrdquo IEEE Journal
of Quantum Electronics vol 28 no 11 pp 2563ndash2566 1992[3] MYamada ldquoBroadband and gain-flattened amplifier composed
of a 155 [micro sign]m-band and a 158 [micro sign]m-band Er3+-doped fibre amplifier in a parallel configurationrdquoElectronics Letters vol 33 no 8 p 710 1997
[4] V P Gapontsev S M Matitsin A A Isineev and V BKravchenko ldquoErbium glass lasers and their applicationsrdquoOpticsamp Laser Technology vol 14 no 4 pp 189ndash196 1982
[5] J D Bradley J Dinnerman and P F Moulton ldquo3-120583m cw laseroperations in erbium-doped YSGG GGG and YAGrdquo OpticsLetters vol 19 no 15 pp 1143ndash1145 1994
[6] G J Kintz R Allen and L Esterowitz ldquoCW and pulsed28 120583m laser emission from diodeminuspumped Er3+LiYF
4at room
temperaturerdquo Applied Physics Letters vol 50 p 1553 1987[7] H Stange K Peterman G Huber and E W Duczynski
ldquoContinuous wave 16120583m laser action in Er doped garnets atroom temperaturerdquo Applied Physics B vol 49 no 3 pp 269ndash273 1989
[8] F Auzel S Hubert and D Meichenin ldquoMultifrequencyroomminustemperature continuous diode and Arlowast laserminuspumpedEr3+ laser emission between 266 and 285 120583mrdquo Applied PhysicsLetters vol 54 no 8 p 681 1989
[9] N Van Minh N Manh Hung D Thi Xuan Thao M Roef-faers and J Hofkens ldquoStructural and optical properties ofZnWO
4Er3+ crystalsrdquo Journal of Spectroscopy vol 2013 Article
ID 424185 5 pages 2013[10] L Wu X L Chen Q Y Tu et al ldquoPhase relations in the system
Li2O-MgO-B
2O3rdquo Journal of Alloys and Compounds vol 333
no 1-2 pp 154ndash158 2002[11] R C Stoneman and L Esterowitz ldquoEfficient resonantly pumped
28-120583m Er3+GSGG laserrdquo Optics Letters vol 17 no 11 p 8161992
[12] C Chen B Wu A Jiang and G You ldquoA new-type ultravioletSHG crystal 120573-BaB
2O4rdquo Scientia Sinica B vol 28 no 3 pp 235ndash
243 1985[13] M He X L Chen H Okudera and A Simon
ldquo(K1minus119909
Na119909)2Al2B2O7with 0 le 119909 lt 06 a promising nonlinear
optical crystalrdquo Chemistry of Materials vol 17 no 8 pp2193ndash2196 2005
[14] C Chen Y Wu A Jiang et al ldquoNew nonlinear-optical crystalLiB3O5rdquo Journal of the Optical Society of America B vol 6 no
4 pp 616ndash621 1989[15] LWu X L Chen H Li M He Y P Xu and X Z Li ldquoStructure
determination and relative properties of novel cubic boratesMM10158404(BO3)3(M = Li M1015840 = Sr M = Na M1015840 = Sr Ba)rdquo Inorganic
Chemistry vol 44 pp 6409ndash6414 2005[16] C Chen Y Wu and R Li ldquoThe relationship between the
structural type of anionic group and SHG effect in boron-oxygen compoundsrdquoChinese Physics Letters vol 2 no 9 p 3891985
[17] C Duan J Yuan and J Zhao ldquoLuminescence propertiesof efficient X-ray phosphors of YBa
3B9O18 LuBa
3(BO3)3 120572-
YBa3(BO3)3and LuBO
3rdquo Journal of Solid State Chemistry vol
178 no 12 pp 3698ndash3702 2005[18] C Duan J Yuan X Yang et al ldquoLuminescent properties of
REBa3B9O18
(RE = Lu Tb Gd Eu) under VUV excitationrdquoJournal of PhysicsDApplied Physics vol 38 no 19 p 3576 2005
[19] X Z Li C Wang X L Chen et al ldquoSyntheses thermalstability and structure determination of the novel isostructuralRBa3B9O18(R =Y Pr Nd Sm Eu Gd Tb Dy Ho Er Tm Yb)rdquo
Inorganic Chemistry vol 43 no 26 pp 8555ndash8560 2004[20] M He W Y Wang Y P Sun Y P Xu and X L Chen ldquoGrowth
and optical properties of YBa3B9O18Ce crystalsrdquo Journal of
Crystal Growth vol 307 no 2 pp 427ndash431 2007[21] MHe GM CaiW JWangW YWang J Liu andX L Chen
ldquoGrowth and luminescence properties of a novel crystal withlarge birefringence ErBa
3B9O18rdquo Journal of Crystal Growth vol
311 no 4 pp 1234ndash1237 2009[22] M He X L Chen Y P Sun J Liu J T Zhao and C J Duan
ldquoYBa3B9O18 a promising scintillation crystalrdquo Crystal Growth
amp Design vol 7 no 2 pp 199ndash201 2007[23] M He T Z Liu M H Qiu et al ldquoStudy on the optical proper-
ties of ErBa3B9O18crystalsrdquo Physica B Condensed Matter vol
456 pp 100ndash102 2015[24] B R Judd ldquoOptical absorption intensities of rare-earth ionsrdquo
Physical Review vol 127 no 3 pp 750ndash761 1962[25] G S Ofelt ldquoIntensities of crystal spectra of rare-earth ionsrdquoThe
Journal of Chemical Physics vol 37 no 3 p 511 1962[26] W T Carnall P R Fields and K Rajnak ldquoElectronic energy
levels in the trivalent lanthanide aquo ions I Pr3+ Nd3+ Pm3+Sm3+ Dy3+ Ho3+ Er3+ and Tm3+rdquo The Journal of ChemicalPhysics vol 49 p 4424 1968
[27] W T Carnall P R Fields and K Rajnak ldquoElectronic energylevels in the trivalent lanthanide aquo ions I Pr3+ Nd3+ Pm3+Sm3+ Dy3+ Ho3+ Er3+ and Tm3+rdquo The Journal of ChemicalPhysics vol 49 no 10 pp 4414ndash4442 1968
[28] R ReisfeldThe Rare Earths in Modern Sciences and TechnologyPlenum Press New York NY USA 1979
[29] M G Liu B S Lu H F Pan and Q Song ldquoErxY1minusxAl3(BO3)4crystal growth and its spectral propertiesrdquo Acta Optical Sinicavol 8 pp 1079ndash1084 1988
[30] RGuo YWu P Fu and F Jing ldquoOptical transition probabilitiesof Er3+ ions in La
2CaB10O19crystalrdquo Chemical Physics Letters
vol 416 no 1ndash3 pp 133ndash136 2005
Submit your manuscripts athttpwwwhindawicom
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Inorganic ChemistryInternational Journal of
Hindawi Publishing Corporation httpwwwhindawicom Volume 2014
International Journal ofPhotoenergy
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Carbohydrate Chemistry
International Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Journal of
Chemistry
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Advances in
Physical Chemistry
Hindawi Publishing Corporationhttpwwwhindawicom
Analytical Methods in Chemistry
Journal of
Volume 2014
Bioinorganic Chemistry and ApplicationsHindawi Publishing Corporationhttpwwwhindawicom Volume 2014
SpectroscopyInternational Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
The Scientific World JournalHindawi Publishing Corporation httpwwwhindawicom Volume 2014
Medicinal ChemistryInternational Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Chromatography Research International
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Applied ChemistryJournal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
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Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
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Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
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Hindawi Publishing Corporation httpwwwhindawicom Volume 2014
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
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Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Applied ChemistryJournal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Theoretical ChemistryJournal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Journal of
Spectroscopy
Analytical ChemistryInternational Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Journal of
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Quantum Chemistry
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
Organic Chemistry International
ElectrochemistryInternational Journal of
Hindawi Publishing Corporation httpwwwhindawicom Volume 2014
Hindawi Publishing Corporationhttpwwwhindawicom Volume 2014
CatalystsJournal of
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