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Rodrı́guez-Lazcano, Y.; Nataf, Lucie; Rodrı́guez, F.

doi:10.1103/physrevb.80.085115

Cited by 95 publications

(59 citation statements)

References 41 publications

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“…45 In Table II we report the experimental and estimated band values, together with the estimated crystal field at ambient conditions and their pressure coefficients. There can be observed that the obtained pressure derivatives for n1 and n2 are much larger than those obtained previously for tetrahedrally coordinated Mn 2+ , 46 as well as happens for the crystal field. It is interesting to remark that according to the estimated pressure dependence of the crystal field, a spin crossover transition would take place for MnWO 4 at 47 GPa, which is a pressure larger than the transition pressure of the structural transformation known to take place at 25 GPa from Raman studies.…”

Section: Bandscontrasting

confidence: 50%

Pressure effects on the electronic and optical properties ofAWO4wolframites (A =

et al. 2012

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The electronic band-structure and band-gap dependence on the d character of A 2+ cation in AWO 4 wolframitetype oxides is investigated for different compounds (A = Mg, Zn, Cd, and Mn) by means of optical-absorption spectroscopy and first-principles density-functional calculations. High pressure is used to tune their properties up to 10 GPa by changing the bonding distances establishing electronic to structural correlations. The effect of unfilled d levels is found to produce changes in the nature of the band gap as well as its pressure dependence without structural changes. Thus, whereas Mg, Zn, and Cd, with empty or filled d electron shells, give rise to direct and wide band gaps, Mn, with a half-filled d shell, is found to have an indirect band gap that is more than 1.6 eV smaller than for the other wolframites. In addition, the band gaps of MgWO 4 , ZnWO 4 , and CdWO 4 blue-shift linearly with pressure, with a pressure coefficient of approximately 13 eV/GPa. However, the band gap of multiferroic MnWO 4 red-shifts at −22 meV/GPa. Finally, in MnWO 4 , absorption bands are observed at lower energy than the band gap and followed with pressure based on the Tanabe-Sugano diagram. This study allows us to estimate the crystal-field variation with pressure for the MnO 6 complexes and how it affects their band-gap closure.

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Section: Bandscontrasting

confidence: 50%

Pressure effects on the electronic and optical properties ofAWO4wolframites (A =

et al. 2012

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“…Compounds with Mn 2+ in a 20 tetrahedral environment usually give out green emissions [1][2][3][4] , while those with octahedrally coordinated Mn 2+ tend to have orange to red emissions [5][6][7][8] . A well-known kind of Mn 2+ based brilliant green emitters are salt-like compounds constructed by inorganic tetrahalogenomanganate(II) anions and organic 25 cations, 2,[9][10][11] which might be promising light-emitting materials for use in cathode-ray tubes, fluorescent tubes, X-ray imaging screens and radiation detectors.…”

Section: Introductionmentioning

confidence: 99%

“…A well-known kind of Mn 2+ based brilliant green emitters are salt-like compounds constructed by inorganic tetrahalogenomanganate(II) anions and organic 25 cations, 2,[9][10][11] which might be promising light-emitting materials for use in cathode-ray tubes, fluorescent tubes, X-ray imaging screens and radiation detectors. 11 Besides, the crystals of these compounds with non-centrosymmetric space group show fascinating characteristic triboluminescence 2,9,10,12 and pressure- 30 dependent photoluminescence 1,13 . However, most of these compounds are easily hydrolyzed by water in air and their emissions are drastically quenched when the temperature raises up to the point (usually bellow 100℃) at which the solid-solid phase transition or melting occurs 2, 10, 11,14 .…”

Section: Introductionmentioning

confidence: 99%

Intense photo- and tribo-luminescence of three tetrahedral manganese(ii) dihalides with chelating bidentate phosphine oxide ligand

et al. 2015

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Three air-stable tetrahedral manganese(ii) dihalide complexes [MnX2(DPEPO)] (DPEPO = bis[2-(diphenylphosphino)phenyl]ether oxide; X = Cl, Br and I) were prepared. All of the obtained compounds were structurally characterized by single-crystal X-ray diffraction analyses, which reveal that they crystallize in centrosymmetric space groups and feature an isolated mononuclear structure with Mn(2+) in a tetrahedral environment. Interestingly, these complexes show excellent photoluminescent performance in neat solid form, with the highest total quantum yield (Φtotal) of up to 70% recorded for the dibromide complex. Intense green flashes of light could be observed by the naked eye when rubbing the manganese(ii) complexes.

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“…Since the latter are mutually adjacent within [Mn@O 4 N 2 ] octahedra, complex 1 can be considered as cis-isomer. One of the N- (14); O4-Mn1-O1 165.11 (5), N2-Mn1-O2 177.49 (7), N1-Mn1-O3 174.63 (7). 1D structure of CP 2 is represented by zig-zag chains built up by alternating Mn II (NCS) 2 and Mn III (NCS) 3 (Figure 3 and Figure 4) that differ only by middle atom in the ligand chains (CH 2 vs. C=CH 2 , accordingly).…”

Section: Crystal Structuresmentioning

confidence: 99%

“…The classical cases are represented by octahedral (O h ) and tetrahedral (T d ) ligand fields, in which Mn 2+ ion emits in red (610-660 nm) and green (510-560 nm) regions, respectively. [1][2][3] For example, the commonly known halomanganates [MnHal 4 ] 2display green luminescence, [4][5][6][7][8][9][10][11][12][13][14][15] while the complexes of results in formation of mixed-valent chain CP [Mn II Mn III -(L2) 3 (NCS) 5 ] n . Complex [Mn(L4) 2 (NCS) 2 ] and CP [Mn(L6) 2 -(NCS) 2 ] n display unique dual luminescence, i.e.…”

Section: Introductionmentioning

confidence: 99%

Manganese(II) Thiocyanate Complexes with Bis(phosphine Oxide) Ligands: Synthesis and Excitation Wavelength‐Dependent Multicolor Luminescence

et al. 2020

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First examples of luminescent MnII thiocyanate complexes are presented. A series of such compounds has been synthesized via the reaction of Mn(NCS)2 with bis(phosphine oxides), Ph2P(O)–X–(O)PPh2, where X = CH2 (L1), CH2CH2 (L2), CH2CH2CH2 (L3), CH2C(=CH2)CH2 (L4), C(=CH2)C(=CH2) (L5) and C≡C (L6). The L1, L3 and L4 ligands, when reacted with Mn(NCS)2 on air (EtOH/acetone, r.t.), produce chelate complexes [MnII(O^O)2(NCS)2]. Under similar conditions, L5 gives ionic complex [MnII(L5)3][MnII(NCS)4], whereas L6 affords chain coordination polymer (CP) [MnII(L6)2(NCS)2]n. By contrast, ligand L2 results in formation of mixed‐valent chain CP [MnIIMnIII(L2)3(NCS)5]n. Complex [Mn(L4)2(NCS)2] and CP [Mn(L6)2(NCS)2]n display unique dual luminescence, i.e. the intraligand fluorescence (blue band) and MnII‐centered phosphorescence (red band), the ratio of which is largely modulated by excitation wavelength. Through this feature, the luminescence color of these complexes can be smoothly tuned from deep‐blue to red. Complex [Mn(L5)3][Mn(NCS)4] shows MnII‐based phosphorescence only.

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Electronic structure and luminescence of[(CH3)4N]2

Cited by 95 publications

References 41 publications

Pressure effects on the electronic and optical properties ofAWO4wolframites (A =

Pressure effects on the electronic and optical properties ofAWO4wolframites (A =

Intense photo- and tribo-luminescence of three tetrahedral manganese(ii) dihalides with chelating bidentate phosphine oxide ligand

Manganese(II) Thiocyanate Complexes with Bis(phosphine Oxide) Ligands: Synthesis and Excitation Wavelength‐Dependent Multicolor Luminescence

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