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Optics Express

Optics Express

  • Editor: C. Martijn de Sterke
  • Vol. 19, Iss. 11 — May. 23, 2011
  • pp: 10131–10137
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ZnGa2O4:Cr3+: a new red long-lasting phosphor with high brightness

Aurélie Bessière, Sylvaine Jacquart, Kaustubh Priolkar, Aurélie Lecointre, Bruno Viana, and Didier Gourier  »View Author Affiliations


Optics Express, Vol. 19, Issue 11, pp. 10131-10137 (2011)
http://dx.doi.org/10.1364/OE.19.010131


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Abstract

ZnGa2O4:Cr3+ is shown to be a new bright red UV excited long-lasting phosphor potentially suitable for in vivo imaging due to its 650 nm-750 nm emission range. Photoluminescence and X-ray excited radioluminescence show the 2E → 4A2 emission lines of both ideal Cr3+ and Cr3+ distorted by a neighboring antisite defect while long-lasting phosphorescence (LLP) and thermally stimulated luminescence (TSL) almost exclusively occur via distorted Cr3+. The most intense LLP is obtained with a nominal Zn deficiency and is related to a TSL peak at 335K. A mechanism for LLP and TSL is proposed, whereby the antisite defect responsible for the distortion at Cr3+ acts as a deep trap.

© 2011 OSA

1. Introduction

Use of luminescent systems for in vivo imaging is of great interest to investigate pathologies in animal models [1

1. V. Ntziachristos, “Fluorescence molecular imaging,” Annu. Rev. Biomed. Eng. 8(1), 1–33 (2006). [CrossRef] [PubMed]

]. Such non-invasive visualization tools offer great advantages in terms of cost and simplicity over expensive techniques at the laboratory scale like micro-Positron Emission Tomography or micro-Magnetic Resonance Imaging. It was recently shown that optical imaging could be advantageously carried out by using as luminescent probe a persistent phosphor emitting in the red/near-infrared part of the spectrum [2

2. Q. le Masne de Chermont, C. Chanéac, J. Seguin, F. Pellé, S. Maîtrejean, J. P. Jolivet, D. Gourier, M. Bessodes, and D. Scherman, “Nanoprobes with near-infrared persistent luminescence for in vivo imaging,” Proc. Natl. Acad. Sci. U.S.A. 104(22), 9266–9271 (2007). [CrossRef] [PubMed]

]. A red/near-infrared emission is necessary for luminescence to pass through the animal tissues since the main components of the tissues strongly absorb ultraviolet (UV)-blue-green and far-infrared parts of the spectrum [3

3. R. Weissleder and V. Ntziachristos, “Shedding light onto live molecular targets,” Nat. Med. 9(1), 123–128 (2003). [CrossRef] [PubMed]

]. By using persistent luminescence nanoparticle the illumination of the animal becomes unnecessary and autofluorescence of the tissues is avoided. UV excitation of the particle is carried out before its injection and therefore is not attenuated by the tissues. The technique was first demonstrated in 2007 with Ca0.2Zn0.9Mg0.9Si2O6:Eu2+,Dy3+,Mn2+ (CZMSO) nanoparticles, from which persistent luminescence was detected in a small animal vasculature for up to one hour after their injection [2

2. Q. le Masne de Chermont, C. Chanéac, J. Seguin, F. Pellé, S. Maîtrejean, J. P. Jolivet, D. Gourier, M. Bessodes, and D. Scherman, “Nanoprobes with near-infrared persistent luminescence for in vivo imaging,” Proc. Natl. Acad. Sci. U.S.A. 104(22), 9266–9271 (2007). [CrossRef] [PubMed]

,4

4. Q. le Masne de Chermont, D. Scherman, M. Bessodes, F. Pellé, S. Maitrejean, J-P. Jolivet, C. Chanéac, D. Gourier, “Nanoparticules à luminescence persistante pour leur utilisation en tant qu'agent de diagnostique destiné à l'imagerie optique in vivo,” CNRS patent, internat. ext. WOEP06067950, WO2007048856, 30/10/2006.

].

In this context we report here on a new red long-lasting phosphorescence (LLP) material potentially suitable for in vivo imaging. ZnGa2O4 is a wide band gap semiconductor which allows doping by luminescent ions such as transition metal ions. Due to its excellent chemical and thermal stability it has been considered as a phosphor of choice for plasma and field emission displays [5

5. I. J. Hsieh, K. T. Chu, C. F. Yu, and M. S. Feng, “Cathodoluminescent characteristics of ZnGa2O4 phosphor grown by radio frequency magnetron sputtering,” J. Appl. Phys. 76(6), 3735–3739 (1994). [CrossRef]

]. ZnGa2O4 shows blue luminescence attributed to self-activated centres when undoped [6

6. I. K. Jeong, H. L. Park, and S. Mho, “Two self-activated optical centers of blue emission in zinc gallate,” Solid State Commun. 105(3), 179–183 (1998). [CrossRef]

,7

7. S. Itoh, H. Toki, Y. Sato, K. Morimoto, and T. Kishino, “The ZnGa2O4 phosphor for low-voltage blue cathodoluminescence,” J. Electrochem. Soc. 138(5), 1509–1512 (1991). [CrossRef]

], intense green emission when doped with Mn2+ [8

8. L. E. Shea, R. K. Datta, and J. J. Brown, “Photoluminescence of Mn2+-activated ZnGa2O4,” J. Electrochem. Soc. 141(7), 1950–1954 (1994). [CrossRef]

] and red luminescence with Cr3+ doping [9

9. P. Dhak, U. K. Gayen, S. Mishra, P. Pramanik, and A. Roy, “Optical emission spectra of chromium doped nanocrystalline zinc gallate,” J. Appl. Phys. 106(6), 063721 (2009). [CrossRef]

]. It crystallizes in the normal spinel structure (space group Oh 7 (Fd3m)) with Zn2+ ions occupying tetrahedral sites (Td) and Ga3+ ions occupying octahedral sites (D3d) [10

10. D. Errandonea, R. S. Kumar, F. J. Manjón, V. V. Ursaki, and E. V. Rusu, “Post-spinel transformations and equation of state in ZnGa2O4: Determination at high pressure by in situ x-ray diffraction,” Phys. Rev. B 79(2), 024103 (2009). [CrossRef]

]. ZnGa2O4 is an ideal host lattice for Cr3+ since the latter presents an ionic radius of 0.62 Å identical to the one of Ga3+ in octahedral coordination [11

11. R. D. Shannon and C. T. Prewitt, “Effective ionic radii in oxides and fluorides,” Acta Crystallogr. B 25(5), 925–946 (1969). [CrossRef]

]. When excited, Cr3+ emits via its 2E → 4A2 transition which gives rise to a far red luminescence with a maximum at 696 nm in the zinc gallate host [9

9. P. Dhak, U. K. Gayen, S. Mishra, P. Pramanik, and A. Roy, “Optical emission spectra of chromium doped nanocrystalline zinc gallate,” J. Appl. Phys. 106(6), 063721 (2009). [CrossRef]

,12

12. H. M. Kahan and R. M. Macfarlane, “Optical and microwave spectra of Cr3+ in the spinel ZnGa2O4,” J. Chem. Phys. 54(12), 5197–5205 (1971). [CrossRef]

]. This wavelength range is totally suitable for in vivo imaging as it corresponds to a transmission maximum for the biological tissues [3

3. R. Weissleder and V. Ntziachristos, “Shedding light onto live molecular targets,” Nat. Med. 9(1), 123–128 (2003). [CrossRef] [PubMed]

].

In this paper we show that ZnGa2O4:Cr3+ powder compares better than CZMSO used up to now for in vivo imaging with UV excitation [2

2. Q. le Masne de Chermont, C. Chanéac, J. Seguin, F. Pellé, S. Maîtrejean, J. P. Jolivet, D. Gourier, M. Bessodes, and D. Scherman, “Nanoprobes with near-infrared persistent luminescence for in vivo imaging,” Proc. Natl. Acad. Sci. U.S.A. 104(22), 9266–9271 (2007). [CrossRef] [PubMed]

]. Mechanism of LLP is investigated by varying the nominal Zn/Ga stoichiometry and by using UV and X-ray excitation to record wavelength-resolved persistent luminescence and thermally stimulated luminescence (TSL).

2. Experimental

The ZnGa2O4:Cr powders were synthesized by a solid state method. Ga2O3 powder (Aldrich 99,99 + %), ZnO powder (Loba-Chemie GR 99%) and CrO3 red flakes (Sisco Research Laboratory AR 99% min.) were mixed in an agate mortar with propan-2-ol. Pellets were prepared from the powder mixtures and fired in air at 1300°C for 6h. All the compounds were nominally doped with 0.5% mol chromium relative to gallium. Three compounds were prepared with various Zn/Ga stoichiometry, their nominal compositions being Zn0.99Ga1.99Cr0.01O4 (Zn-deficient compound, noted Zn-d) ZnGa1.99Cr0.01O4 (stoichiometric compound, noted Zn-s) and Zn1.01Ga1.99Cr0.01O4 (Zn-excess compound, noted Zn-e) respectively. X-ray diffraction of the three compounds evidenced pure ZnGa2O4 crystalline phase with cubic spinel structure (not shown here).

Photoluminescence (PL) spectra were measured at room temperature (RT) on powder pellets with a Varian Cary Eclipse spectrofluorimeter. X-ray excited radioluminescence (XRL), LLP and TSL measurements were run on 1 mm-thick pellets of the powdered samples. For all three experiments light is collected via an optical fiber by a Scientific Pixis 100 CCD camera cooled at −65°C coupled with an Acton SpectraPro 2150i spectrometer for spectral analysis. X-ray excitation is produced by a molybdenum tube operated at 50 kV and 20 mA. UV excitation is produced by a 350 W xenon lamp filtered with a FG UV11 filter to remove visible excitation (bandpass 250-380 nm). In TSL experiments the 1 mm-thick pellet is fixed with a silver glue on the cold finger of a closed cycle helium cryogenerator. UV irradiation is performed at 30 K through a quartz window of the cryostat at 45° angle from the pellet surface and luminescence is detected through a different quartz window at 45° angle from the pellet surface. A heating rate of 10 K/min is applied. Prior to all LLP and TSL experiments the samples were bleached for 20 minutes at 200°C and kept in the dark before the experiment.

3. Results and discussion

Figure 1
Fig. 1 PL spectra excited at 247 nm of Zn-d, Zn-s and Zn-e ZnGa2O4:Cr3+ compounds. Dotted lines show the attribution of Cr3+ lines in ZnGa2O4:Cr3+ at 13K according to Zhang et al. [13].
shows the PL spectra of the Cr3+-doped ZnGa2O4 powders. The spectra display several narrow lines that constitute recognizable features of Cr3+ ion emission in a strong field with octahedral coordination. PL features of ZnGa2O4:Cr3+ at 13K as reported by Zhang et al. [13

13. W. Zhang, J. Zhang, Z. Chen, T. Wang, and S. Zheng, “Spectrum designation and effect of Al substitution on the luminescence of Cr3+ doped ZnGa2O4 nano-sized phosphors,” J. Lumin. 130(10), 1738–1743 (2010). [CrossRef]

] are shown in Fig. 1 as dotted lines. At 13K, these authors report two zero phonon (ZP) lines known as R2 and R1 for the 2E → 4A2 transition of Cr3+. A weak trigonal distortion around Cr3+ splits the 2E level into 2E (Ē) and 2E (2Ā) separated by 40 cm−1 [12

12. H. M. Kahan and R. M. Macfarlane, “Optical and microwave spectra of Cr3+ in the spinel ZnGa2O4,” J. Chem. Phys. 54(12), 5197–5205 (1971). [CrossRef]

] giving rise to the two R lines. R2 and R1 have also been observed at 300K by Kahan et al. [12

12. H. M. Kahan and R. M. Macfarlane, “Optical and microwave spectra of Cr3+ in the spinel ZnGa2O4,” J. Chem. Phys. 54(12), 5197–5205 (1971). [CrossRef]

] with a high-resolution set-up at 14556 cm−1 (687.0 nm) and 14518.8 cm−1 (688.8 nm), respectively. Their position is in total agreement with the feature here observed at 688 nm which we attribute to the unresolved (R2,R1) doublet since our set-up does not allow resolution of these two lines. Since all lines should be red-shifted from 13K (Zhang et al. [12

12. H. M. Kahan and R. M. Macfarlane, “Optical and microwave spectra of Cr3+ in the spinel ZnGa2O4,” J. Chem. Phys. 54(12), 5197–5205 (1971). [CrossRef]

]) to RT (our experiment), the phonon side bands (PSB) of the R lines were identified in the spectra of Fig. 1 at 708 nm, 715 nm and 722 nm for the Stokes PSB and at 670 nm and 680 nm for the Anti-Stokes PSB. The PSB positions are consistent with data from infrared and Raman spectroscopies [13

13. W. Zhang, J. Zhang, Z. Chen, T. Wang, and S. Zheng, “Spectrum designation and effect of Al substitution on the luminescence of Cr3+ doped ZnGa2O4 nano-sized phosphors,” J. Lumin. 130(10), 1738–1743 (2010). [CrossRef]

].

An additional line observed at 695 nm in Fig. 1 is not accounted for by the above mentioned transitions. It therefore originates from another type of Cr3+ ion with perturbed short-range crystalline order relative to the ideal octahedral coordination of the normal spinel. The feature was here observed at 695 nm, i.e. at 147 cm−1 lower energy than the (R2,R1) doublet. According to Mikenda et al. [14

14. W. Mikenda and A. Preisinger, “N-lines in the luminescence spectra of Cr3+-doped spinels: I. Identification of N-lines,” J. Lumin. 26(1-2), 53–66 (1981). [CrossRef]

] a structure-dependent line named N2 for Cr3+ in ZnGa2O4 lies at 134 cm−1 lower energy than R1. We therefore attribute the 695 nm line to the N2 line of Cr3+. After extensive investigation, particularly by Mikenda et al. [15

15. W. Mikenda and A. Preisinger, “N-lines in the luminescence spectra of Cr3+-doped spinels: III. Origins of N-lines,” J. Lumin. 26(1-2), 67–83 (1981). [CrossRef]

17

17. J. Derkosch and W. Mikenda, “N-lines in the luminescence spectra of Cr3+-doped spinels: IV. Excitation spectra,” J. Lumin. 28(4), 431–441 (1981). [CrossRef]

] and Nie et al. [18

18. W. Nie, F. M. Michel-Calendini, C. Linares, G. Boulon, and C. Daul, “New results on optical properties and term-energy calculations in Cr3+-doped ZnAl2O4,” J. Lumin. 46(3), 177–190 (1990). [CrossRef]

], the N2 line of Cr3+ in ZnGa2O4 spinel was established to originate from Cr3+ ions possessing an environment distorted by an antisite defect, located in the first cationic neighbors of Cr3+. Our chromium-doped zinc gallates therefore present two types of doping ions: (i) Cr3+ in an ideal normal spinel environment noted Crn3+ and (ii) Cr3+ in a slightly distorted environment noted Crdis3+. ZnGa2O4 is known to crystallize in an almost normal spinel structure with a few percent inversion [19

19. R. Hill, J. Craig, and G. V. Gibbs, “Systematics of the spinel structure type,” Phys. Chem. Miner. 4(4), 317–339 (1979). [CrossRef]

]. The inversion percentage varies with synthesis conditions and is favored by high temperature synthesis [6

6. I. K. Jeong, H. L. Park, and S. Mho, “Two self-activated optical centers of blue emission in zinc gallate,” Solid State Commun. 105(3), 179–183 (1998). [CrossRef]

,20

20. G. Anoop, K. Mini Krishna, and M. K. Jayaraj, “Influence of a dopant source on the structural and optical properties of Mn doped ZnGa2O4 thin films,” Appl. Phys., A Mater. Sci. Process. 90(4), 711–715 (2008). [CrossRef]

]. The comparison of the three compounds spectra shows that the intensity of the N2 line relative to the R lines increases as the stoichiometry evolves from a nominal zinc deficiency towards a zinc excess. More antisite defects seem therefore present as the Zn/Ga nominal ratio is increased. Considering the two possible antisite defects of opposite charge that can distort the coordination polyhedron of Cr3+, namely ZnGa’ (negatively charged) and GaZn° (positively charged), the position of the N2 line at a photon energy 147 cm−1 below the (R1,R2) line of undistorted Crn3+indicates that the crystal field is smaller for Crdis3+than for Crn3+. This suggests that the neighboring defect is positively charged, as is a Ga3+ ion in Zn2+ site (GaZn°).

LLP was measured after UV excitation to compare the Cr3+-doped zinc gallates to the phosphor previously used for the demonstration of imaging (referred to as CZMSO). This reference phosphor is a silicate of nominal formula Ca0.2Zn0.9Mg0.9Si2O6:Eu2+,Mn2+,Dy3+ described in [2

2. Q. le Masne de Chermont, C. Chanéac, J. Seguin, F. Pellé, S. Maîtrejean, J. P. Jolivet, D. Gourier, M. Bessodes, and D. Scherman, “Nanoprobes with near-infrared persistent luminescence for in vivo imaging,” Proc. Natl. Acad. Sci. U.S.A. 104(22), 9266–9271 (2007). [CrossRef] [PubMed]

]. Both phosphors were excited for 5 minutes with a filtered xenon lamp before their LLP was recorded for up to one hour at an ambient temperature of 30°C. The normalized LLP spectra of the ZnGa2O4:Cr3+ compounds recorded 45 s after the end of the excitation are shown in the inset of Fig. 2
Fig. 2 LLP decays of Zn-d, Zn-s and Zn-e ZnGa2O4:Cr3+ compounds at 705 nm and of the silicate reference at 695 nm recorded at 303 K after 5 minutes UV excitation. Inset: normalized LLP spectra of ZnGa2O4:Cr3+ compounds 45 s after the end of the excitation.
. Due to wide monochromator slits the spectra do not show as resolved lines as in Fig. 1 but they still display the 2E → 4A2 luminescence of Cr3+. LLP decays at the wavelength of emission maximum are compared in the main plot of Fig. 2. The Cr3+-doped zinc gallates showed a highly enhanced intensity relative to CZMSO. As its emission lies in the highest transmission spectral range of the biological tissues, ZnGa2O4:Cr3+ is an excellent new candidate for LLP imaging. Amongst the three ZnGa2O4:Cr3+ materials more intense LLP was obtained as the compound is nominally more Zn-deficient.

With the comparison of the three samples with different Zn/Ga ratio we found that more antisite defects were present close to Cr3+ with increasing Zn/Ga ratio, whereas the LLP was more intense with decreasing Zn/Ga ratio. Decreasing the Zn/Ga ratio favors more Zn vacancies (and thus more hole traps) which may then be responsible for the enhanced LLP. Within this hypothesis the TSL peak D as well as the LLP at RT are due to VZn from which the holes get thermally detrapped to recombine at Crdis3+ site. Further experiments will be carried out in the future to constrain the proposed mechanism.

4. Conclusion

We showed in this work that ZnGa2O4:Cr3+ is a new high-performance red long-lasting phosphor, compared to CZMSO used for demonstrating the technique of LLP in vivo imaging [2

2. Q. le Masne de Chermont, C. Chanéac, J. Seguin, F. Pellé, S. Maîtrejean, J. P. Jolivet, D. Gourier, M. Bessodes, and D. Scherman, “Nanoprobes with near-infrared persistent luminescence for in vivo imaging,” Proc. Natl. Acad. Sci. U.S.A. 104(22), 9266–9271 (2007). [CrossRef] [PubMed]

]. On the contrary to other red LLP materials studied for this application [21

21. A. Lecointre, B. Viana, Q. LeMasne, A. Bessière, C. Chanéac, and D. Gourier, “Red long-lasting luminescence in Clinoenstatite,” J. Lumin. 129(12), 1527–1530 (2009). [CrossRef]

24

24. A. Lecointre, A. Bessière, A. J. J. Bos, P. Dorenbos, B. Viana, and S. Jacquart, “Designing a red persistent luminescence phosphor: the example of YPO4:Pr3+,Ln3+ (Ln = Nd, Er, Ho, Dy),” J. Phys. Chem. C 115(10), 4217–4227 (2011). [CrossRef]

] ZnGa2O4:Cr3+ could be conveniently excited through its bandgap by UV light. After 5 minutes excitation it emitted light around 695 nm via the 2E → 4A2 transition of Cr3+ for a prolonged time. This emission range perfectly matched the optical window of biological tissues and as such may be readily detected across small animal tissues.

In addition to the exciting properties of ZnGa2O4:Cr3+ for imaging, the compound revealed new elements in the field of LLP. Firstly ZnGa2O4 may be an intrinsic persistent phosphor since intense green [25

25. K. Uheda, T. Maruyama, H. Takisawa, and T. Endo, “Synthesis and long-period phosphorescence of ZnGa2O4: Mn2+ spinel,” J. Alloy. Comp. 262–263, 60–64 (1997). [CrossRef]

] and now red LLP were observed in the same host. Furthermore no codoping was necessary to obtain intense persistent luminescence which makes investigation of mechanisms easier and decreases the chances of non-radiative loss. The use of a small dopant concentration (0.5%) and of a similar size dopant as the substituted ion (the ionic radii of Cr3+ and Ga3+ are identical) also reduces the occurrence of defects that constitute potential loss centres. Secondly the use of Cr3+ as both luminescent centre and probe of the local environment appeared as of uttermost use in the investigation of the mechanisms. The very narrow emission lines of Cr3+ ions in Ga3+ sites are so sensitive to chromium environment that the coordination sphere of the luminescent centre Cr3+ can be elucidated. Hence we showed that antisite defects GaZn of the ZnGa2O4 spinel structure were likely to be involved in the charge trapping and recombination processes responsible for LLP in ZnGa2O4:Cr3+. The LLP intensity was singularly improved by decreasing the nominal Zn/Ga ratio, i.e. probably by creating more Zn vacancies that constitute the thermally emptied traps in the LLP mechanism.

References and links

1.

V. Ntziachristos, “Fluorescence molecular imaging,” Annu. Rev. Biomed. Eng. 8(1), 1–33 (2006). [CrossRef] [PubMed]

2.

Q. le Masne de Chermont, C. Chanéac, J. Seguin, F. Pellé, S. Maîtrejean, J. P. Jolivet, D. Gourier, M. Bessodes, and D. Scherman, “Nanoprobes with near-infrared persistent luminescence for in vivo imaging,” Proc. Natl. Acad. Sci. U.S.A. 104(22), 9266–9271 (2007). [CrossRef] [PubMed]

3.

R. Weissleder and V. Ntziachristos, “Shedding light onto live molecular targets,” Nat. Med. 9(1), 123–128 (2003). [CrossRef] [PubMed]

4.

Q. le Masne de Chermont, D. Scherman, M. Bessodes, F. Pellé, S. Maitrejean, J-P. Jolivet, C. Chanéac, D. Gourier, “Nanoparticules à luminescence persistante pour leur utilisation en tant qu'agent de diagnostique destiné à l'imagerie optique in vivo,” CNRS patent, internat. ext. WOEP06067950, WO2007048856, 30/10/2006.

5.

I. J. Hsieh, K. T. Chu, C. F. Yu, and M. S. Feng, “Cathodoluminescent characteristics of ZnGa2O4 phosphor grown by radio frequency magnetron sputtering,” J. Appl. Phys. 76(6), 3735–3739 (1994). [CrossRef]

6.

I. K. Jeong, H. L. Park, and S. Mho, “Two self-activated optical centers of blue emission in zinc gallate,” Solid State Commun. 105(3), 179–183 (1998). [CrossRef]

7.

S. Itoh, H. Toki, Y. Sato, K. Morimoto, and T. Kishino, “The ZnGa2O4 phosphor for low-voltage blue cathodoluminescence,” J. Electrochem. Soc. 138(5), 1509–1512 (1991). [CrossRef]

8.

L. E. Shea, R. K. Datta, and J. J. Brown, “Photoluminescence of Mn2+-activated ZnGa2O4,” J. Electrochem. Soc. 141(7), 1950–1954 (1994). [CrossRef]

9.

P. Dhak, U. K. Gayen, S. Mishra, P. Pramanik, and A. Roy, “Optical emission spectra of chromium doped nanocrystalline zinc gallate,” J. Appl. Phys. 106(6), 063721 (2009). [CrossRef]

10.

D. Errandonea, R. S. Kumar, F. J. Manjón, V. V. Ursaki, and E. V. Rusu, “Post-spinel transformations and equation of state in ZnGa2O4: Determination at high pressure by in situ x-ray diffraction,” Phys. Rev. B 79(2), 024103 (2009). [CrossRef]

11.

R. D. Shannon and C. T. Prewitt, “Effective ionic radii in oxides and fluorides,” Acta Crystallogr. B 25(5), 925–946 (1969). [CrossRef]

12.

H. M. Kahan and R. M. Macfarlane, “Optical and microwave spectra of Cr3+ in the spinel ZnGa2O4,” J. Chem. Phys. 54(12), 5197–5205 (1971). [CrossRef]

13.

W. Zhang, J. Zhang, Z. Chen, T. Wang, and S. Zheng, “Spectrum designation and effect of Al substitution on the luminescence of Cr3+ doped ZnGa2O4 nano-sized phosphors,” J. Lumin. 130(10), 1738–1743 (2010). [CrossRef]

14.

W. Mikenda and A. Preisinger, “N-lines in the luminescence spectra of Cr3+-doped spinels: I. Identification of N-lines,” J. Lumin. 26(1-2), 53–66 (1981). [CrossRef]

15.

W. Mikenda and A. Preisinger, “N-lines in the luminescence spectra of Cr3+-doped spinels: III. Origins of N-lines,” J. Lumin. 26(1-2), 67–83 (1981). [CrossRef]

16.

W. Mikenda, “N-lines in the luminescence spectra of Cr3+-doped spinels: III. Partial spectra,” J. Lumin. 26(1-2), 85–98 (1983). [CrossRef]

17.

J. Derkosch and W. Mikenda, “N-lines in the luminescence spectra of Cr3+-doped spinels: IV. Excitation spectra,” J. Lumin. 28(4), 431–441 (1981). [CrossRef]

18.

W. Nie, F. M. Michel-Calendini, C. Linares, G. Boulon, and C. Daul, “New results on optical properties and term-energy calculations in Cr3+-doped ZnAl2O4,” J. Lumin. 46(3), 177–190 (1990). [CrossRef]

19.

R. Hill, J. Craig, and G. V. Gibbs, “Systematics of the spinel structure type,” Phys. Chem. Miner. 4(4), 317–339 (1979). [CrossRef]

20.

G. Anoop, K. Mini Krishna, and M. K. Jayaraj, “Influence of a dopant source on the structural and optical properties of Mn doped ZnGa2O4 thin films,” Appl. Phys., A Mater. Sci. Process. 90(4), 711–715 (2008). [CrossRef]

21.

A. Lecointre, B. Viana, Q. LeMasne, A. Bessière, C. Chanéac, and D. Gourier, “Red long-lasting luminescence in Clinoenstatite,” J. Lumin. 129(12), 1527–1530 (2009). [CrossRef]

22.

A. Lecointre, A. Bessière, B. Viana, R. Aït Benhamou, and D. Gourier, “Thermally stimulated luminescence of Ca3(PO4)2 and Ca9Ln(PO4)7 (Ln = Pr, Eu, Tb, Dy, Ho, Er, Lu),” Radiat. Meas. 45(3-6), 273–276 (2010). [CrossRef]

23.

A. Lecointre, A. Bessière, B. Viana, and D. Gourier, “Red persistent luminescent silicate nanoparticles,” Radiat. Meas. 45(3-6), 497–499 (2010). [CrossRef]

24.

A. Lecointre, A. Bessière, A. J. J. Bos, P. Dorenbos, B. Viana, and S. Jacquart, “Designing a red persistent luminescence phosphor: the example of YPO4:Pr3+,Ln3+ (Ln = Nd, Er, Ho, Dy),” J. Phys. Chem. C 115(10), 4217–4227 (2011). [CrossRef]

25.

K. Uheda, T. Maruyama, H. Takisawa, and T. Endo, “Synthesis and long-period phosphorescence of ZnGa2O4: Mn2+ spinel,” J. Alloy. Comp. 262–263, 60–64 (1997). [CrossRef]

OCIS Codes
(160.2540) Materials : Fluorescent and luminescent materials
(160.2900) Materials : Optical storage materials
(160.4670) Materials : Optical materials
(160.4760) Materials : Optical properties
(160.6990) Materials : Transition-metal-doped materials
(300.6250) Spectroscopy : Spectroscopy, condensed matter

ToC Category:
Materials

History
Original Manuscript: March 16, 2011
Revised Manuscript: April 28, 2011
Manuscript Accepted: May 5, 2011
Published: May 9, 2011

Citation
Aurélie Bessière, Sylvaine Jacquart, Kaustubh Priolkar, Aurélie Lecointre, Bruno Viana, and Didier Gourier, "ZnGa2O4:Cr3+: a new red long-lasting phosphor with high brightness," Opt. Express 19, 10131-10137 (2011)
http://www.opticsinfobase.org/oe/abstract.cfm?URI=oe-19-11-10131


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References

  1. V. Ntziachristos, “Fluorescence molecular imaging,” Annu. Rev. Biomed. Eng. 8(1), 1–33 (2006). [CrossRef] [PubMed]
  2. Q. le Masne de Chermont, C. Chanéac, J. Seguin, F. Pellé, S. Maîtrejean, J. P. Jolivet, D. Gourier, M. Bessodes, and D. Scherman, “Nanoprobes with near-infrared persistent luminescence for in vivo imaging,” Proc. Natl. Acad. Sci. U.S.A. 104(22), 9266–9271 (2007). [CrossRef] [PubMed]
  3. R. Weissleder and V. Ntziachristos, “Shedding light onto live molecular targets,” Nat. Med. 9(1), 123–128 (2003). [CrossRef] [PubMed]
  4. Q. le Masne de Chermont, D. Scherman, M. Bessodes, F. Pellé, S. Maitrejean, J-P. Jolivet, C. Chanéac, D. Gourier, “Nanoparticules à luminescence persistante pour leur utilisation en tant qu'agent de diagnostique destiné à l'imagerie optique in vivo,” CNRS patent, internat. ext. WOEP06067950, WO2007048856, 30/10/2006.
  5. I. J. Hsieh, K. T. Chu, C. F. Yu, and M. S. Feng, “Cathodoluminescent characteristics of ZnGa2O4 phosphor grown by radio frequency magnetron sputtering,” J. Appl. Phys. 76(6), 3735–3739 (1994). [CrossRef]
  6. I. K. Jeong, H. L. Park, and S. Mho, “Two self-activated optical centers of blue emission in zinc gallate,” Solid State Commun. 105(3), 179–183 (1998). [CrossRef]
  7. S. Itoh, H. Toki, Y. Sato, K. Morimoto, and T. Kishino, “The ZnGa2O4 phosphor for low-voltage blue cathodoluminescence,” J. Electrochem. Soc. 138(5), 1509–1512 (1991). [CrossRef]
  8. L. E. Shea, R. K. Datta, and J. J. Brown, “Photoluminescence of Mn2+-activated ZnGa2O4,” J. Electrochem. Soc. 141(7), 1950–1954 (1994). [CrossRef]
  9. P. Dhak, U. K. Gayen, S. Mishra, P. Pramanik, and A. Roy, “Optical emission spectra of chromium doped nanocrystalline zinc gallate,” J. Appl. Phys. 106(6), 063721 (2009). [CrossRef]
  10. D. Errandonea, R. S. Kumar, F. J. Manjón, V. V. Ursaki, and E. V. Rusu, “Post-spinel transformations and equation of state in ZnGa2O4: Determination at high pressure by in situ x-ray diffraction,” Phys. Rev. B 79(2), 024103 (2009). [CrossRef]
  11. R. D. Shannon and C. T. Prewitt, “Effective ionic radii in oxides and fluorides,” Acta Crystallogr. B 25(5), 925–946 (1969). [CrossRef]
  12. H. M. Kahan and R. M. Macfarlane, “Optical and microwave spectra of Cr3+ in the spinel ZnGa2O4,” J. Chem. Phys. 54(12), 5197–5205 (1971). [CrossRef]
  13. W. Zhang, J. Zhang, Z. Chen, T. Wang, and S. Zheng, “Spectrum designation and effect of Al substitution on the luminescence of Cr3+ doped ZnGa2O4 nano-sized phosphors,” J. Lumin. 130(10), 1738–1743 (2010). [CrossRef]
  14. W. Mikenda and A. Preisinger, “N-lines in the luminescence spectra of Cr3+-doped spinels: I. Identification of N-lines,” J. Lumin. 26(1-2), 53–66 (1981). [CrossRef]
  15. W. Mikenda and A. Preisinger, “N-lines in the luminescence spectra of Cr3+-doped spinels: III. Origins of N-lines,” J. Lumin. 26(1-2), 67–83 (1981). [CrossRef]
  16. W. Mikenda, “N-lines in the luminescence spectra of Cr3+-doped spinels: III. Partial spectra,” J. Lumin. 26(1-2), 85–98 (1983). [CrossRef]
  17. J. Derkosch and W. Mikenda, “N-lines in the luminescence spectra of Cr3+-doped spinels: IV. Excitation spectra,” J. Lumin. 28(4), 431–441 (1981). [CrossRef]
  18. W. Nie, F. M. Michel-Calendini, C. Linares, G. Boulon, and C. Daul, “New results on optical properties and term-energy calculations in Cr3+-doped ZnAl2O4,” J. Lumin. 46(3), 177–190 (1990). [CrossRef]
  19. R. Hill, J. Craig, and G. V. Gibbs, “Systematics of the spinel structure type,” Phys. Chem. Miner. 4(4), 317–339 (1979). [CrossRef]
  20. G. Anoop, K. Mini Krishna, and M. K. Jayaraj, “Influence of a dopant source on the structural and optical properties of Mn doped ZnGa2O4 thin films,” Appl. Phys., A Mater. Sci. Process. 90(4), 711–715 (2008). [CrossRef]
  21. A. Lecointre, B. Viana, Q. LeMasne, A. Bessière, C. Chanéac, and D. Gourier, “Red long-lasting luminescence in Clinoenstatite,” J. Lumin. 129(12), 1527–1530 (2009). [CrossRef]
  22. A. Lecointre, A. Bessière, B. Viana, R. Aït Benhamou, and D. Gourier, “Thermally stimulated luminescence of Ca3(PO4)2 and Ca9Ln(PO4)7 (Ln = Pr, Eu, Tb, Dy, Ho, Er, Lu),” Radiat. Meas. 45(3-6), 273–276 (2010). [CrossRef]
  23. A. Lecointre, A. Bessière, B. Viana, and D. Gourier, “Red persistent luminescent silicate nanoparticles,” Radiat. Meas. 45(3-6), 497–499 (2010). [CrossRef]
  24. A. Lecointre, A. Bessière, A. J. J. Bos, P. Dorenbos, B. Viana, and S. Jacquart, “Designing a red persistent luminescence phosphor: the example of YPO4:Pr3+,Ln3+ (Ln = Nd, Er, Ho, Dy),” J. Phys. Chem. C 115(10), 4217–4227 (2011). [CrossRef]
  25. K. Uheda, T. Maruyama, H. Takisawa, and T. Endo, “Synthesis and long-period phosphorescence of ZnGa2O4: Mn2+ spinel,” J. Alloy. Comp. 262–263, 60–64 (1997). [CrossRef]

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