2021
DOI: 10.1002/anie.202104231
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Halide Replacement with Complete Preservation of Crystal Lattice in Mixed‐Anion Lanthanide Oxyhalides

Abstract: Ac hallenge in anion control in periodic solids is to preserve the crystal lattice while substituting for different anions of widely varying sizea nd hardness.P ost-synthetic modification routes that place cations or anions in nonequilibrium configurations are promising;h owever,s uch methods remain relatively unexplored for anion placement. Here,w er eport the synthesis of LaOI nanocrystals by an onhydrolytic sol-gel condensation reaction and their transformation into LaOBr,LaOCl, and LaOF nanocrystals along … Show more

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Cited by 13 publications
(11 citation statements)
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“…showed evidence for enormous iodide anion migration in lanthanum oxyiodide‐based solids [10] . The most recent work reports the synthesis of LaOI nanocrystals by a non‐hydrolytic sol‐gel condensation reaction and their transformation into LaOBr, LaOCl, and LaOF nanocrystals using post‐synthetic metathesis reactions with ammonium halides [11] …”
Section: Introductionmentioning
confidence: 99%
“…showed evidence for enormous iodide anion migration in lanthanum oxyiodide‐based solids [10] . The most recent work reports the synthesis of LaOI nanocrystals by a non‐hydrolytic sol‐gel condensation reaction and their transformation into LaOBr, LaOCl, and LaOF nanocrystals using post‐synthetic metathesis reactions with ammonium halides [11] …”
Section: Introductionmentioning
confidence: 99%
“…In this work, we select the layered and mixed-anion LnOCl (Ln = Y, Gd, La) hosts as prototype systems to study the photoluminescence mechanisms, i.e., the excited states involved, energies and relaxation processes, of isolated and paired Bi 3+ (6s 2 ) ions. The mixed-anion rare-earth oxyhalides LnOCl are important hosts for luminescent materials 27,28 and emerge as a family of effective van der Waals dielectrics 29 and Kitaev spin liquid candidates. 30 The photoluminescence of the Bi 3+ activator in a LnOX-type host, X being a halide ion, has been extensively studied in experiments.…”
Section: Introductionmentioning
confidence: 99%
“…Panels A and B of Figure show normalized X-ray absorption near-edge structure (XANES) spectra of double and quadruple molybdates with different La/Dy ratios, respectively. Excitation across the La N 4,5 edge (95–150 eV), corresponding to a 4d → 4f core excitation, reveals characteristic absorption features arising from the excitation of the La 3+ singlet ground state to triplet 3 D 1 (dipole forbidden but observed because of spin–orbit coupling) and singlet 1 P 1 (dipole allowed) states. , The latter feature, labeled the giant resonance, has an anomalously high absorption cross-section stemming from strong 4d–4f overlap and exhibits asymmetric broadening as a result of the short lifetime of the excited state and the activation of non-radiative Auger emission pathways. Spectral features appearing at ca. 106 and 108 eV are a result of exchange splitting caused by the overlap of 4d and 4f wave functions resulting in triakontadipole (Δ l = 5) and octupole (Δ l = 3) higher order multipole transitions upon 4d 10 4f n → 4d 9 4f n +1 core excitation (117 eV; Δ l = 1), respectively. , While these satellite bands are relatively low in intensity in the XANES spectrum, they can be clearly resolved in total-reflection inelastic X-ray scattering measurements …”
mentioning
confidence: 99%
“…Optical luminescence arising from X-ray excitation of the lattice has been probed using X-ray-excited optical luminescence (XEOL) measurements. Two-dimensional ­(2D) XEOL intensity maps in Figure S1A of the Supporting Information reveal the absence of visible emission features in NaLa­(MoO 4 ) 2 samples that do not incorporate Dy 3+ centers. In contrast, visible emission bands (most prominently, 4 F 9/2 → 6 H 15/2 at 480 nm and 4 F 9/2 → 6 H 13/2 at 570 nm) are observed in NaDy­(MoO 4 ) 2 only upon direct excitation at the Dy 3+ N 4,5 edge (ca.…”
mentioning
confidence: 99%
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