2022
DOI: 10.1002/adom.202200059
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Beyond the Energy Gap Law: The Influence of Selection Rules and Host Compound Effects on Nonradiative Transition Rates in Boltzmann Thermometers

Abstract: range from biothermal imaging, [5,6] temperature monitoring in catalysis, [7][8][9][10] microelectronics, [11] or molecular logics [12] to the investigation of fundamental thermodynamic phenomena [13] at the micro-and nanoscale. One of the conceptually simplest ways of optical temperature sensing, also in terms of the required setup, is the exploitation of the luminescence intensity ratio (LIR) of two emission bands due to radiative transitions from two thermally coupled excited levels of an ensemble of non-i… Show more

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Cited by 11 publications
(15 citation statements)
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“…The luminescence spectra of materials doped with Cr 3+ ions result from the d-d electronic transitions. In the case of the transition metal ions of 3d 3 electronic configuration observed for Cr 3+ ions, depending on the crystal field strength of the host material the spectrum is dominated either by narrow band 2 E (g) -4 A 2g emission (strong crystal field) or broad emission band 4 T 2(g) -4 A 2(g) for the weak crystal field. However, in order to develop a ratiometric optical excitation density sensor based on the emission intensity ratio from the 2 E (g) level to that from the 4 T 2(g) level, one should use materials with an intermediate crystal field for which both bands are observed in the spectrum simultaneously (Fig.…”
Section: Resultsmentioning
confidence: 97%
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“…The luminescence spectra of materials doped with Cr 3+ ions result from the d-d electronic transitions. In the case of the transition metal ions of 3d 3 electronic configuration observed for Cr 3+ ions, depending on the crystal field strength of the host material the spectrum is dominated either by narrow band 2 E (g) -4 A 2g emission (strong crystal field) or broad emission band 4 T 2(g) -4 A 2(g) for the weak crystal field. However, in order to develop a ratiometric optical excitation density sensor based on the emission intensity ratio from the 2 E (g) level to that from the 4 T 2(g) level, one should use materials with an intermediate crystal field for which both bands are observed in the spectrum simultaneously (Fig.…”
Section: Resultsmentioning
confidence: 97%
“…As the Cr 3+ content increases, the intensity of the broad 4 T 2(g) -4 A 2(g) band increases relative to the 2 E (g) -4 A 2(g) one. Although such a change may suggest a modification in the crystal field strength with increasing dopant ion concentrations, 42 a careful analysis of the excitation spectra clearly indicates that the positions of the 4 A 2(g) -4 T 2(g) and 4 A 2(g) -4 T 1(g) absorption bands of Cr 3+ ions are independent of the dopant ion concentration. The determined strength of the crystal field (based on eqn (S1)-(S3), ESI †) confirms this observation and Dq/B B 2.48 is obtained for all analyzed dopant concentrations (Fig.…”
Section: Resultsmentioning
confidence: 99%
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