Spotlight on Luminescence Thermometry: Basics, Challenges, and Cutting‐Edge Applications

Brites, Carlos D. S.; Marin, Riccardo; Suta, Markus; Neto, Albano N. Carneiro; Ximendes, Erving; Jaque, Daniel; Carlos, Luı́s D.

doi:10.1002/adma.202302749

Cited by 64 publications

(42 citation statements)

References 415 publications

(699 reference statements)

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“…This observation indicates the unsuitability of the presented approach for precise temperature sensing at higher magnetic fields. With that said, the possibility of implementing nine different thermometric parameters for the Ho III complex allows us to overcome the low sensitivity and high uncertainty under higher applied magnetic fields while enhancing the accuracy of the temperature read‐out [59] . As such, we can adopt the multiparametric thermal read‐out method in conjunction with a multiple regression approach, a novel technique introduced in recent work by Carlos and co‐workers [60] .…”

Section: Methodsmentioning

confidence: 99%

“…With that said, the possibility of implementing nine different thermometric parameters for the Ho III complex allows us to overcome the low sensitivity and high uncertainty under higher applied magnetic fields while enhancing the accuracy of the temperature readout. [59] As such, we can adopt the multiparametric thermal read-out method in conjunction with a multiple regression approach, a novel technique introduced in recent work by Carlos and co-workers. [60] In this approach, a multiple (linear or non-linear) regression can be applied to the different thermometric parameters, providing a self-calibrated readout, and increasing the precision of temperature measurement.…”

Section: Methodsmentioning

confidence: 99%

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Toward Magneto‐Optical Cryogenic Thermometers with High Sensitivity: A Magnetic Circular Dichroism Based Thermometric Approach

Gálico,

Murugesu

2023

Angewandte Chemie

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Remote temperature probing at the cryogenic range is of utmost importance for the advancement of future quantum technologies. Despite the notable achievements in luminescent thermometers, accurately measuring temperatures below 10 K remains a challenging endeavor. In this study, we propose a novel magneto‐optical thermometric approach based on the magnetic‐circular dichroism (MCD) technique, which offers unprecedented capabilities for meticulous temperature variation analysis at cryogenic temperatures. The inherent temperature sensitivity of the MCD C‐term, in conjunction with both positive and negative signals, enables highly sensitive magneto‐optical temperature probing. Additionally, a groundbreaking relative thermal sensitivity value of 95.3% K‐1 at 2.54 K can be achieved using a mononuclear lanthanide complex, [[Ho(acac)3(phen)], in the presence of a 0.25 T applied magnetic field and using a combination of multiparametric thermal read‐out with multiple regression. These results unequivocally demonstrate the viability and effectiveness of our methodology for cryogenic temperature sensing.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Toward Magneto‐Optical Cryogenic Thermometers with High Sensitivity: A Magnetic Circular Dichroism Based Thermometric Approach

Gálico,

Murugesu

2023

Angewandte Chemie

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“…One potential source of artifacts is the optical instrumentation used to perform the luminescence measurements, such as spectral distortions caused by high numerical aperture objective lenses or noise from the CCD sensor used to record spectra. , The resulting temperature errors reported in these cases ranged from less than one degree up to tens of degrees. Optical misalignment can also introduce artifacts.…”

Section: Emerging Areasmentioning

confidence: 99%

“…This review complements several other recent reviews on luminescence thermometry, some of which specifically focus on biological applications − and some of which also cover a subset of nonbiological applications. − ,− While a number of existing reviews provide excellent summaries of the different luminescent probes and signals that can be exploited for thermometry, here we largely focus on the applications enabled by these techniques. We also omit coverage of thermographic phosphors used primarily for combustion and industrial manufacturing applications, which are typically applied as paints or thin film coatings and have been reviewed elsewhere, , and focus on luminescent nanomaterial-based thermometry.…”

Section: Introductionmentioning

confidence: 97%

“…Finally, we discuss emerging areas such as the identification and mitigation of artifacts that can distort luminescence thermometry signals and the resulting temperature measurements, the application of advanced data analysis and machine learning (ML) methods to luminescence thermometry, and particle-to-particle uniformity of luminescence thermometry signals and the use of batch calibration procedures. Several of the emerging areas we cover were also highlighted in a very recent comprehensive review, 4 underscoring the growing importance of these topics within the luminescence thermometry community. We end by summarizing the current status of the field and offer a perspective on future research directions.…”

Section: Introductionmentioning

confidence: 99%

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Luminescence Thermometry Beyond the Biological Realm

Harrington,

Ye,

Signor

et al. 2023

ACS Nanosci. Au

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As the field of luminescence thermometry has matured, practical applications of luminescence thermometry techniques have grown in both frequency and scope. Due to the biocompatibility of most luminescent thermometers, many of these applications fall within the realm of biology. However, luminescence thermometry is increasingly employed beyond the biological realm, with expanding applications in areas such as thermal characterization of microelectronics, catalysis, and plasmonics. Here, we review the motivations, methodologies, and advances linked to nonbiological applications of luminescence thermometry. We begin with a brief overview of luminescence thermometry probes and techniques, focusing on those most commonly used for nonbiological applications. We then address measurement capabilities that are particularly relevant for these applications and provide a detailed survey of results across various application categories. Throughout the review, we highlight measurement challenges and requirements that are distinct from those of biological applications. Finally, we discuss emerging areas and future directions that present opportunities for continued research.

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Erbium‐Induced Boost in Self‐Trapped Exciton Emission of Double Perovskites for Highly Sensitive Multimodal and Multiplexed Optical Thermography

Li,

Cheng,

Chen

et al. 2024

Adv Funct Materials

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Self‐trapped excitons (STEs) of lead‐free perovskites have aroused tremendous interest in remote optical thermometry due to strong exciton–phonon coupling and large Stokes shifts. Herein, a bright multimodal and multiplexed optical thermometer is constructed with high sensitivity (Sr) and self‐calibrating ability based on Cs2NaInCl6:Er3+ double perovskite, allowing for fast and simplified reading via mobile devices. Intriguingly, Er3+ doping not only shows the characteristic green emissions but also introduces nanoelectronic domains through a new localized valance band maximum and breaks the symmetry of In3+ site, which facilitates the generation of more STEs. The temperature‐sensitive blue emission of STEs and temperature‐insensitive green emission of Er3+ endow multimodal optical thermometry including time‐resolved and ratiometric readout schemes with a maximum Sr of 3.8% K−1, where an upconversion primary thermometry serves as a reference to calibrate other modes. Meanwhile, the designed thermometers show robust photostability, repeatability, and structural stability for long‐time working and storage. In addition, the remarkable thermochromic phenomenon from blue to green enables a quick color‐multiplexed thermography on a smartphone, which is utilized to capture real‐time 2D thermal imaging of microelectronic devices. This work demonstrates the great potential of lead‐free double perovskite for low‐cost and portable optical thermometry.

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Spotlight on Luminescence Thermometry: Basics, Challenges, and Cutting‐Edge Applications

Cited by 64 publications

References 415 publications

Toward Magneto‐Optical Cryogenic Thermometers with High Sensitivity: A Magnetic Circular Dichroism Based Thermometric Approach

Toward Magneto‐Optical Cryogenic Thermometers with High Sensitivity: A Magnetic Circular Dichroism Based Thermometric Approach

Luminescence Thermometry Beyond the Biological Realm

Erbium‐Induced Boost in Self‐Trapped Exciton Emission of Double Perovskites for Highly Sensitive Multimodal and Multiplexed Optical Thermography

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