Red-emitting manganese-doped aluminum nitride phosphor

Cherepy, Nerine J.; Payne, Stephen A.; Harvey, Nicholas M.; Åberg, Daniel; Seeley, Zachary M.; Holliday, Kiel; Tran, Ich C.; Zhou, Fei; Martínez, Henry; Demeyer, Jessica; Drobshoff, A.; Srivastava, A.M.; Camardello, S.J.; Comanzo, H.A.; Schlagel, Deborah L.; Lograsso, Thomas A.

doi:10.1016/j.optmat.2016.02.008

Cited by 32 publications

(18 citation statements)

References 41 publications

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“…Cherepy et al. published recently data on a 600 nm PL band in intentionally Mn doped AlN. They found a corresponding absorption at 4.88 eV and two different lifetimes (one at around

1.25

ms, and the other increasing from 0.29 to 6.30 ms for decreasing Mn concentrations).…”

Section: Discussionmentioning

confidence: 98%

Slow decay of a defect‐related emission band at 2.05 eV in AlN: Signatures of oxygen‐related DX states

Lamprecht

Grund

Bauer

et al. 2016

Physica Status Solidi (b)

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We report on a defect‐related broad emission band at around 2.05 eV in bulk aluminum nitride crystals nominally undoped, but containing high concentrations of carbon, oxygen, and silicon. Time‐resolved photoluminescence spectroscopy yields two different exponential decays of this band: A slower process with 1.5 ms lifetime, and a faster process with a characteristic lifetime below 100 ns, which is activated with around 180 meV energy. The slow decay is ascribed to a spin‐forbidden transition between an oxygen‐related DX− S=1 state and a deep acceptor, which for higher temperatures turns into a donor‐acceptor pair transition between the effective‐mass‐like shallow oxygen donor state to the same deep acceptor. The acceptor is tentatively assigned to carbon or a carbon‐related complex.

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“…Cherepy et al. published recently data on a 600 nm PL band in intentionally Mn doped AlN. They found a corresponding absorption at 4.88 eV and two different lifetimes (one at around

1.25

ms, and the other increasing from 0.29 to 6.30 ms for decreasing Mn concentrations).…”

Section: Discussionmentioning

confidence: 98%

Slow decay of a defect‐related emission band at 2.05 eV in AlN: Signatures of oxygen‐related DX states

Lamprecht

Grund

Bauer

et al. 2016

Physica Status Solidi (b)

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“…In displays with w-LED backlights, narrow-band red (NBR) and narrow-band green (NBG) emission widens the color gamut and allows for a higher brightness by using narrow-band emission that matches the displays’ color filter transmission. A promising candidate for narrow-band red or green emission is Mn 2+ (3d 5 ), and this ion therefore gained huge interest as an activator ion. , The d–d intraconfigurational 4 T 1 – 6 A 1 emission of Mn 2+ is typically in the green/orange spectral region for Mn 2+ in tetrahedral coordination and in the orange/red spectral region in octahedral coordination (higher crystal field strength). Unfortunately, the d–d absorption strength in the blue is extremely low, making singly doped Mn 2+ phosphors unsuitable for (In,Ga)N-based LED excitation.…”

Section: Introductionmentioning

confidence: 99%

Unraveling the Eu²⁺ → Mn²⁺ Energy Transfer Mechanism in w-LED Phosphors

et al. 2020

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Recent research on white light LED (w-LED) phosphors has focused on narrow-band green and red luminescent materials to improve the efficacy of w-LEDs and to widen the color gamut of w-LED-based displays. Mn 2+ is a promising emitter capable of narrow-band emission, either green or red, depending on the local coordination. However, the extremely low absorption coefficients for the spin-and parity-forbidden d−d transitions in Mn 2+ form a serious drawback and require addition of a sensitizer ion such as Ce 3+ or Eu 2+ , with strong absorption in the blue. The performance of the codoped phosphor then critically depends on efficient energy transfer. Despite extensive research, a clear understanding of the Eu 2+ → Mn 2+ and Ce 3+ → Mn 2+ transfer mechanism is lacking. Typically, Dexter exchange interaction or electric dipole−quadrupole coupling are considered. Here we investigate Eu 2+ → Mn 2+ energy transfer in Ba 2 MgSi 2 O 7 and show that the most probable mechanism is exchange interaction with fast (nanoseconds) energy transfer from Eu 2+ to nearest-neighbor Mn 2+ and much slower (>100 ns) transfer to next-nearest neighbors, as expected for exchange interaction. We critically evaluate previous studies where the assignment of dipole−quadrupole interaction was erroneously based on C Mn 8/3 concentration dependence of energy transfer efficiencies. Preferential Eu 2+ −Mn 2+ pair formation is suggested as a mechanism that enhances energy transfer efficiencies.

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“…Despite intense research, alternative red phosphors for lighting applications remain a challenge. No alternative has been found to the original Y2O3:Eu phosphor developed for the first tri-color fluorescent lamp more than 40 years ago [1], though our recent efforts did identify AlN:Mn as a possible option [2]. The red phosphor is particularly demanding, because it must emit within a very narrow energy range due to a sharp decrease in eye sensitivity at longer wavelengths and a poor red color rendering index at shorter wavelengths.…”

Section: Introductionmentioning

confidence: 99%

Increased fluorescence intensity in CaTiO3:Pr3+ phosphor due to NH3 treatment and Nb Co-doping

et al. 2016

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Development of next generation red phosphors for commercial lighting requires understanding of how increased luminescence is achieved by various treatment strategies. In this work, we compare co-doping with Nb to NH3 treatment of CaTiO3:Pr phosphors to reveal a general mechanism responsible for the increased luminescence. The phosphors were synthesized using standard solid-state synthesis techniques and the fluorescence was characterized for potential use in fluorescent lighting, with 254 nm excitation. The lifetime of the fluorescence was determined and used to identify a change in a trap state by the co-doping of Nb 5+ in the phosphor. The oxidation state of the Pr was probed by NEXAFS and revealed that both Nb 5+ co-doping and NH3 treatment reduced the number of nonfluorescing Pr 4+ centers. Calculations were performed to determine the energetically favorable defects. Vacuum annealing was also used to further probe the nature of the trap state. It was determined that NH3 treatments reduce the number of Pr 4+ non-fluorescing centers, while Nb 5+ co-doping additionally reduces the number of excess oxygen trap states that quench the fluorescence.

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Red-emitting manganese-doped aluminum nitride phosphor

Cited by 32 publications

References 41 publications

Slow decay of a defect‐related emission band at 2.05 eV in AlN: Signatures of oxygen‐related DX states

Slow decay of a defect‐related emission band at 2.05 eV in AlN: Signatures of oxygen‐related DX states

Unraveling the Eu²⁺ → Mn²⁺ Energy Transfer Mechanism in w-LED Phosphors

Increased fluorescence intensity in CaTiO3:Pr3+ phosphor due to NH3 treatment and Nb Co-doping

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Red-emitting manganese-doped aluminum nitride phosphor

Cited by 32 publications

References 41 publications

Slow decay of a defect‐related emission band at 2.05 eV in AlN: Signatures of oxygen‐related DX states

Slow decay of a defect‐related emission band at 2.05 eV in AlN: Signatures of oxygen‐related DX states

Unraveling the Eu2+ → Mn2+ Energy Transfer Mechanism in w-LED Phosphors

Increased fluorescence intensity in CaTiO3:Pr3+ phosphor due to NH3 treatment and Nb Co-doping

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Unraveling the Eu²⁺ → Mn²⁺ Energy Transfer Mechanism in w-LED Phosphors