Rb+ cations enable the change of luminescence properties in perovskite (RbxCs1−xPbBr3) quantum dots

Wu, Hao; Yang, Yong; Zhou, Dacheng; Li, Kuangran; Yu, Jianguo; Han, Jin; Li, Zhencai; Long, Zhangwen; Ma, Jiao; Qiu, Jianbei

doi:10.1039/c7nr07776a

Cited by 67 publications

(50 citation statements)

References 35 publications

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“…We introduce Rb + into CsPbBr 3 nanocrystals during synthesis to enlarge the bandgap. Rb‐doping in perovskite QDs and quasi‐2D thin films have been previously reported, where it was found to blue‐shift the absorption and PL properties …”

Section: Peled Electroluminescence Performance Metricsmentioning

confidence: 86%

“…We used these metrics to estimate the limit to Rb + doping of CsPbBr 3 ( t = 0.92) with Rb + to increase the bandgap. Finite Rb + incorporation results in further tilting of the PbX 6 octahedra, reducing the overall orbital overlap and hence opening up the bandgap of CsPbBr 3 while simultaneously reducing the tolerance factor . However, it has been reported that an upper bound of 70% Rb + exists in a mixed cation perovskite QD, as pure RbPbBr 3 does not exist under ambient conditions …”

Section: Peled Electroluminescence Performance Metricsmentioning

confidence: 99%

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Spectrally Tunable and Stable Electroluminescence Enabled by Rubidium Doping of CsPbBr₃ Nanocrystals

Todorovič

Chen

et al. 2019

Advanced Optical Materials

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quantum yields (PLQYs), as well as their tunability through size and composition which enables emission wavelengths that span the full visible spectrum. [1,[10][11][12] In contrast with conventional epitaxially grown semiconductors, solution-processed quantum dots are synthesized at lower temperatures, which enables low-cost device fabrication and compatibility with flexible plastic substrates. In the hot-injection synthesis, metal salt precursors of the form AX and BX 2 are solubilized in a solvent that contains stabilizing ligands, after which the A-site organometallic solution is injected at an elevated temperature into the solution containing BX 2 , and colloidal QDs emerge within seconds. [1,11,13] Perovskite LEDs (PeLEDs) have recently achieved high external quantum efficiencies (EQEs) above 20% in the red and green; but blue PeLEDs have lagged behind their red and green counterparts. [14,15] Low EQEs in blue devices have been attributed to increased degradation pathways through increased defect formation at higher driving voltages; as well as due to lower PLQYs of the initial active layer. [16][17][18] Additionally, PeLED research on deep-blue emission (<470 nm) has been limited. The Rec.2020 standard set by the International Telecommunications Union Radiocommunication (ITU-R) requires blue emitters having emission centered at 467 nm and, by achieving a narrow full-width at halfmaximum (FWHM <25 nm) and minimal red tail, to meet the color coordinate: [(x blue = 0.131, y blue = 0.046)]. [19] In order to achieve blue emission in perovskites, halide mixing and quantum confinement strategies are employed. Blue perovskite QDs have relied on anion mixtures containing both Br − and Cl − within the APbX 3 cubic/orthorhombic nanocrystal, such as in the archetypal CsPbBr 3−x Cl x to obtain the desired emission. [1,11,20] These mixed halide systems have enabled high PLQYs and impressively narrow FWHM of 12 nm in solution for pure CsPbCl 3 , and roughly 25 nm for mixed Br/Cl systems. [10] Utilizing this strategy, Song et al. achieved an EQE of 0.07% at an emission wavelength of 455 nm and a peak brightness of 742 cd m −2 . [20] A record high EQE of 1.9% was reported by Pan et al. at 490 nm, but these devices displayed low luminance. [21] Unfortunately, mixed halide PeLEDs suffer from color instability under operating conditions: phase segregation into pure Cl − and Br − phases occurs under voltage bias. [22] This leads to a red-shift of the electroluminescence (EL) spectra. [22] Perovskite nanocrystals exhibit high photoluminescence quantum yields (PLQYs) and tunable bandgaps from ultraviolet to infrared. However, blue perovskite light-emitting diodes (LEDs) suffer from color instability under applied bias. Developing narrow-bandwidth deep-blue emitters will maximize the color gamut of display technologies. Mixed anion approaches suffer from halide segregation that leads to their spectral instability. Here instead, a mixed cation strategy is employed whereby Rb + is directly incorporated during synthesis into CsPbBr 3...

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Section: Peled Electroluminescence Performance Metricsmentioning

confidence: 86%

Section: Peled Electroluminescence Performance Metricsmentioning

confidence: 99%

Spectrally Tunable and Stable Electroluminescence Enabled by Rubidium Doping of CsPbBr₃ Nanocrystals

Todorovič

Chen

et al. 2019

Advanced Optical Materials

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“…[23][24][25][26] Rb x Cs 1Àx PbBr 3 perovskite quantum dots were found to exhibit high quantum yield (93 %), narrower photoluminescence (PL) emission linewidth (18-27 nm), and excellent wide color gamut coverage. [27][28][29][30][31] However,all-inorganic perovskite RbPbBr 3 structures have still not been realized. Theoretical stability,a si ndicated by the tolerance factor t,s hould be considered carefully for the realization of the all-inorganic RbPbBr 3 perovskite.T he tolerance factor of RbPbBr 3 is about 0.78 (the effective ionic radii of Rb + ,Pb 2+ ,and Br À are 1.61, 1.19, and 1.96 ,r espectively).…”

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confidence: 99%

An All‐Inorganic Perovskite‐Phase Rubidium Lead Bromide Nanolaser

Tang

Dong

et al. 2019

Angew Chem Int Ed

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Rubidium lead halides (RbPbX 3 ), an important class of all-inorganic metal halide perovskites,a re attracting increasing attention for photovoltaic applications.H owever, limited by its lower Goldschmidt tolerance factor t % 0.78, allinorganic RbPbBr 3 has not been reported. Now,t he crystal structure,X-raydiffraction (XRD) pattern, and band structure of perovskite-phase RbPbBr 3 has nowb een investigated. Perovskite-phase RbPbBr 3 is unstable at room temperature and transforms to photoluminescence (PL)-inactive nonperovskite.T he structural evolution and mechanism of the perovskite-non-perovskite phase transition were clarified in RbPbBr 3 .E xperimentally,p erovskite-phase RbPbBr 3 was realized through ad ual-source chemical vapor deposition and annealing process.T hese perovskite-phase microspheres showed strong PL emission at about 464 nm. This new perovskite can serve as ag ain medium and microcavity to achieve broadband (475-540 nm) single-mode lasing with ahigh Qofabout 2100.All-inorganic metal halide perovskites of the form CsPbX 3 (X = Cl, Br,I ), owing to their remarkable properties,a re attracting increasing attention for use in optoelectronic devices such as solar cells,l ight-emitting diodes (LEDs), and semiconductor nanolasers. [1][2][3][4][5][6][7][8][9][10] Such all-inorganic perovskites exhibit superior properties,including improved photo-

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“…After the heat treatment, multiple peaks merge into a wide peak. To prove that Eu 3+ was successfully mixed into the quantum dots, the XRD patterns (Figure F) are then investigated, compared with the undoped quantum dots, the 2θ value of Eu 3+ ‐doped samples shift to larger angle, this is because the Eu 3+ ionic radius is smaller than that of Pb 2+ (98 pm for Pb 2+ , 94.7 pm for Eu 3+ ), crystal lattice constriction occurs, resulting in the diffraction peak shifting to the right in the XRD patterns when Pb 2+ is replaced by Eu 3+ , Which is consistent with the results reported by Wu et al When the mole concentrations of Eu 3+ ions increase continously, the number of Eu‐doped CsPbBr 1.5 I 1.5 QDs peaks disappeared in XRD patterns, which indicates that the ordered perovskite structure has been destroyed. The absorption spectra are displayed in Figure G, with the intervene of Eu 3+ ions, the absorption value of quantum dots reduced in different extents.…”

Section: Resultsmentioning

confidence: 99%

Eu³⁺‐doped CsPbBr_1.5I_1.5 quantum dots glasses: A strong competitor among red fluorescence solid materials

et al. 2018

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CsPbBr1.5I1.5 quantum dots (QDs) glasses are synthesized by traditional melting and thermal treated method, CsPbBr1.5I1.5 QDs glasses show vast potential as red fluorescence component in warm WLED applications due to their moderate emission wavelength as well as good opacity property. However, the quantum yield of QDs glasses is still low, therefore, Eu3+ ions is chosen to introduce into CsPbBr1.5I1.5 QDs, the quantum yield is enhanced to 64.7%. After a sequence of testing operations, we find that 6.5%CsPbBr1.5I1.5:0.28%Eu3+ QDs glasses is a strong competitor among red fluorescence solid materials.

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Rb⁺ cations enable the change of luminescence properties in perovskite (Rb_xCs_1−xPbBr₃) quantum dots

Cited by 67 publications

References 35 publications

Spectrally Tunable and Stable Electroluminescence Enabled by Rubidium Doping of CsPbBr₃ Nanocrystals

Spectrally Tunable and Stable Electroluminescence Enabled by Rubidium Doping of CsPbBr₃ Nanocrystals

An All‐Inorganic Perovskite‐Phase Rubidium Lead Bromide Nanolaser

Eu³⁺‐doped CsPbBr_1.5I_1.5 quantum dots glasses: A strong competitor among red fluorescence solid materials

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Rb+ cations enable the change of luminescence properties in perovskite (RbxCs1−xPbBr3) quantum dots

Cited by 67 publications

References 35 publications

Spectrally Tunable and Stable Electroluminescence Enabled by Rubidium Doping of CsPbBr3 Nanocrystals

Spectrally Tunable and Stable Electroluminescence Enabled by Rubidium Doping of CsPbBr3 Nanocrystals

An All‐Inorganic Perovskite‐Phase Rubidium Lead Bromide Nanolaser

Eu3+‐doped CsPbBr1.5I1.5 quantum dots glasses: A strong competitor among red fluorescence solid materials

Contact Info

Product

Resources

About

Rb⁺ cations enable the change of luminescence properties in perovskite (Rb_xCs_1−xPbBr₃) quantum dots

Spectrally Tunable and Stable Electroluminescence Enabled by Rubidium Doping of CsPbBr₃ Nanocrystals

Spectrally Tunable and Stable Electroluminescence Enabled by Rubidium Doping of CsPbBr₃ Nanocrystals

Eu³⁺‐doped CsPbBr_1.5I_1.5 quantum dots glasses: A strong competitor among red fluorescence solid materials