High-Quantum-Yield Upconverting Er<sup>3+</sup>/Yb<sup>3+</sup>-Organic–Inorganic Hybrid Dual Coatings for Real-Time Temperature Sensing and Photothermal Conversion

Caixeta, Fábio José; Bastos, Ana R. N.; Botas, Alexandre M. P.; Rosa, Leonardo Cruz da; Souza, Vítor S.; Borges, Fernanda Hediger; Neto, Albano N. Carneiro; Ferrier, Alban; Goldner, Philippe; Carlos, Luís D.; Gonçalves, Rogéria Rocha; Ferreira, Rute A. S.

doi:10.1021/acs.jpcc.0c03874

Cited by 36 publications

(18 citation statements)

References 87 publications

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“…Recently, there has also been progress in reverting this scheme and performing thermometry by detecting a reference emission from the same excited level upon dual excitation from two thermally coupled ground levels 24 – 26 . Luminescence (nano)thermometry has been demonstrated to be both a precise and accurate technique for probing fundamental thermodynamic phenomena at the micro- and nanoscale 27 – 29 and helps to assess the local temperature fluctuations in tissue 30 – 35 or in chemical reactors 36 – 40 . Currently, there has been observable progress on how to implement and standardize this technique for applications 41 – 45 , the connected limitations 46 , 47 , or how to couple temperature sensing with other functionalities such as single-molecule magnetism 48 , 49 and (meso-)porous materials 50 , 51 , e.g., theranostics 52 .…”

Section: Introductionmentioning

confidence: 99%

One ion to catch them all: Targeted high-precision Boltzmann thermometry over a wide temperature range with Gd3+

Zhang

et al. 2021

Light Sci Appl

110

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Ratiometric luminescence thermometry with trivalent lanthanide ions and their 4fn energy levels is an emerging technique for non-invasive remote temperature sensing with high spatial and temporal resolution. Conventional ratiometric luminescence thermometry often relies on thermal coupling between two closely lying energy levels governed by Boltzmann’s law. Despite its simplicity, Boltzmann thermometry with two excited levels allows precise temperature sensing, but only within a limited temperature range. While low temperatures slow down the nonradiative transitions required to generate a measurable population in the higher excitation level, temperatures that are too high favour equalized populations of the two excited levels, at the expense of low relative thermal sensitivity. In this work, we extend the concept of Boltzmann thermometry to more than two excited levels and provide quantitative guidelines that link the choice of energy gaps between multiple excited states to the performance in different temperature windows. By this approach, it is possible to retain the high relative sensitivity and precision of the temperature measurement over a wide temperature range within the same system. We demonstrate this concept using YAl3(BO3)4 (YAB):Pr3+, Gd3+ with an excited 6PJ crystal field and spin-orbit split levels of Gd3+ in the UV range to avoid a thermal black body background even at the highest temperatures. This phosphor is easily excitable with inexpensive and powerful blue LEDs at 450 nm. Zero-background luminescence thermometry is realized by using blue-to-UV energy transfer upconversion with the Pr3+−Gd3+ couple upon excitation in the visible range. This method allows us to cover a temperature window between 30 and 800 K.

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Section: Introductionmentioning

confidence: 99%

One ion to catch them all: Targeted high-precision Boltzmann thermometry over a wide temperature range with Gd3+

Zhang

et al. 2021

Light Sci Appl

110

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“…[ 17–20 ] However, some recent works raise concerns on the reliability of the technique caused by experimental artifices. [ 21–28 ] One solution to overcome these limitations is the use of primary thermometers characterized by a well‐established equation (e.g., Varshni's law for semiconductor nanoparticles [ 21,29 ] or Boltzmann distribution when using intensity ratio between two thermally coupled levels [ 13,30–35 ] ), where all parameters are known without the need of a prior calibration. Nonetheless, the theoretical knowledge of the mechanism behind the emission dependence on the temperature is unattainable in most cases, disabling the a priori building of a primary thermometer.…”

Section: Introductionmentioning

confidence: 99%

Customized Luminescent Multiplexed Quick‐Response Codes as Reliable Temperature Mobile Optical Sensors for eHealth and Internet of Things

Ramalho

Dias

et al. 2021

Advanced Photonics Research

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Internet of things (IoT) and health are two fields that have the potential to grow together. From their connection arises the concept of eHealth which refers essentially to the use of information and communication technologies in healthcare services. [1,2] This concept benefits from the advances of intelligent and integrated technological systems that are expected to live in and onto our bodies in different forms of flexible wearables. [3,4] Healthcare assisted by portable and wireless technologies is often termed mobile health (mHealth), [5,6] in which smartphones stand out as the most used ones. The combination of eHealth and mHealth enables monitoring and health tracking, providing vital information for remote medicine analysis (or in point of care) and successfully detecting health abnormalities. [7] Moreover, eHealth and mHealth can mitigate the lack of infrastructural or human resources in underprivileged regions. [1] Requisites for eHealth and mHealth medical devices are being designed for customized in-home care toward continuous and noninvasive monitoring. [8] Among the vital signals, body temperature stands out as the easiest and typically monitored one by common persons to infer the health condition. The pandemic scenario exacerbated such need for sense in real time through sustainable and multifunctional labels of body temperature and the fast tracking of people information (e.g., COVID-19 test results, places visited).The near-infrared (NIR) thermal cameras are one of the main devices used due to the fast response times and noninterference to electromagnetic fields in the working environment. Nonetheless, ambient conditions (e.g., stray light, reflected radiation, flame, or gas steam) may lead to temperature uncertainty of up to 1-8%. [9] In addition, the temperature readout requires human resources, being time-consuming and error prone, and people tracking is not possible to be done simultaneously. The recent reports on mobile optical sensing mediated by smartphones appear as an intriguing strategy to enable large-scale sensing and tracking mediated by the user. [10] Very few works address simultaneously sensing and tracking, [10][11][12][13] most of the reports focused only on temperature sensing, though photographic records from the luminescent materials recorded with a

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“…[ 47,53–58 ] The solution lies in primary thermometers, characterized by a well‐established state‐equation that directly relates a particular measured value to the absolute temperature without the need for calibration. So far, only a few primary luminescent thermometers have been reported, [ 43,53,58–65 ] most of which based on the intensity ratio between two thermally coupled electronic levels, for instance, the Er 3+ 2 H 11/2 and 4 S 3/2 levels. In this case, the thermometric parameter is based exclusively upon the validity of the Boltzmann distribution.…”

Section: Optical Temperature Sensors Overviewmentioning

confidence: 99%

“…[ 46,55,59,66–89 ] The S r values for primary luminescent thermometers are shown in Figure 3b. [ 43,53,58–64 ] Noticeable, only one example refers to smartphone‐based luminescence thermometry, and presents the largest S r value. [ 59 ]…”

Section: Optical Temperature Sensors Overviewmentioning

confidence: 99%

mOptical Sensing for the Internet of Things: A Smartphone‐Controlled Platform for Temperature Monitoring

Ramalho

Carlos

André³

et al. 2021

Advanced Photonics Research

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Sensors play a key role on the Internet of Things (IoT), providing monitoring inside and outside the networks in a multitude of parameters. A fundamental parameter to sense is temperature, being essential to acquire knowledge on the best way to include thermal sensing into the communications networks. Despite that the temperature measurement in the optical domain is well known for its advantages compared with the electric one, its incorporation in the IoT is a challenge due to the lack of affordable strategies able to convert optical into an electronic signal in a cost‐effective way. The coupling of such optical sensors to smartphones appears as an exciting strategy for mobile optical (mOptical) sensing. Herein, advances in optical temperature sensors for mOptical sensing are reviewed and the chronological mechanistic context of waveguided and nonguided optical signal sensors is outlined. A new path for advances in photonics research is traced, established by the incorporation of smartphones as a tool in science and engineering that foresees new designs for mOptical temperature sensor toward IoT.

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High-Quantum-Yield Upconverting Er³⁺/Yb³⁺-Organic–Inorganic Hybrid Dual Coatings for Real-Time Temperature Sensing and Photothermal Conversion

Cited by 36 publications

References 87 publications

One ion to catch them all: Targeted high-precision Boltzmann thermometry over a wide temperature range with Gd3+

One ion to catch them all: Targeted high-precision Boltzmann thermometry over a wide temperature range with Gd3+

Customized Luminescent Multiplexed Quick‐Response Codes as Reliable Temperature Mobile Optical Sensors for eHealth and Internet of Things

mOptical Sensing for the Internet of Things: A Smartphone‐Controlled Platform for Temperature Monitoring

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High-Quantum-Yield Upconverting Er3+/Yb3+-Organic–Inorganic Hybrid Dual Coatings for Real-Time Temperature Sensing and Photothermal Conversion

Cited by 36 publications

References 87 publications

One ion to catch them all: Targeted high-precision Boltzmann thermometry over a wide temperature range with Gd3+

One ion to catch them all: Targeted high-precision Boltzmann thermometry over a wide temperature range with Gd3+

Customized Luminescent Multiplexed Quick‐Response Codes as Reliable Temperature Mobile Optical Sensors for eHealth and Internet of Things

mOptical Sensing for the Internet of Things: A Smartphone‐Controlled Platform for Temperature Monitoring

Contact Info

Product

Resources

About

High-Quantum-Yield Upconverting Er³⁺/Yb³⁺-Organic–Inorganic Hybrid Dual Coatings for Real-Time Temperature Sensing and Photothermal Conversion