Notes on thermometric artefacts by Er3+ luminescence band interference | Semantic Scholar (2024)

21 Citations

Upconverting nanoparticles as primary thermometers and power sensors
    J. MartinsA. Skripka L. Carlos

    Materials Science, Physics

    Frontiers in Photonics

  • 2022

Luminescence thermometry is a spectroscopic technique for remote temperature detection based on the thermal dependence of the luminescence of phosphors, presenting numerous applications ranging from

  • 3
  • PDF
Photonic Artifacts in Ratiometric Luminescence Nanothermometry
    Sander J. W. VonkThomas P. van SwietenArio CocinaF. Rabouw

    Physics, Materials Science

    Nano letters

  • 2023

Ongoing developments in science and technology require temperature measurements at increasingly higher spatial resolutions. Nanocrystals with temperature-sensitive luminescence are a popular

  • 12
  • PDF
Primary Luminescent Nanothermometers for Temperature Measurements Reliability Assessment
    J. MartinsA. BastosR. FerreiraXin WangGuanying ChenL. Carlos

    Materials Science, Physics

    Advanced Photonics Research

  • 2021

The potential applications in disparate fi elds led to a rapid evolution of luminescence thermometry. In particular, luminescent thermometry based on trivalent lanthanide ions (Ln 3 þ ) has become

  • 38
Spotlight on Luminescence Thermometry: Basics, Challenges, and Cutting‐Edge Applications
    C. BritesRiccardo Marin L. Carlos

    Physics, Materials Science

    Advanced materials

  • 2023

Luminescence (nano)thermometry is a remote sensing technique that relies on the temperature dependency of the luminescence features (e.g., bandshape, peak energy or intensity, and excited state

  • 65
2D Thermal Maps Using Hyperspectral Scanning of Single Upconverting Microcrystals: Experimental Artifacts and Image Processing.
    A. R. PessoaJ. A. GalindoY. E. Serge-CorrealesA. M. AmaralSidney J. L. RibeiroL. de S. Menezes

    Physics, Materials Science

  • 2022

Whereas lanthanide-based upconverting particles are promising candidates for several micro- and nanothermometry applications, understanding spatially varying effects related to their internal

  • 7
An Optical Multiplexing Method Using Upconversion Nanoparticles with Tunable P–I Relationship
    Xinyu ChenYuyang Gu Wei Feng

    Physics, Materials Science

    Advanced Optical Materials

  • 2022

Optical multiplexing is of great value in information acquisition due to its excellent signal encoding ability. However, the number of encoding channels is often limited by instruments or luminescent

  • 2
Influence of the Non-Thermally Coupled Three-Photon Band on the Performance of Y2O3: Yb3+/Er3+ Single-Particle Nanothermometers
    A. R. PessoaJ. A. Galindo A. M. Amaral

    Materials Science, Physics

    2023 Conference on Lasers and Electro-Optics…

  • 2023

Nanoscale temperature sensing is increasingly being explored to study physical-chemical processes at the nanoscale. Since direct contact thermometers, like thermistors, are usually not suitable for

Mapping Elevated Temperatures with a Micrometer Resolution Using the Luminescence of Chemically Stable Upconversion Nanoparticles
    T. P. SwietenTijn van Omme Catalysis

    Materials Science, Physics

    ACS applied nano materials

  • 2021

The experiments reveal distortions in the luminescence spectra that are intrinsic to high-resolution measurements of samples with nanoscale photonic inhom*ogeneities and present a procedure to correct them, which will improve the accuracy of nanothermometry not only in micro- and nanoelectronics but also in other fields with photonically inhom*ogeneous substrates.

  • 50
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Impact of Noise and Background on Measurement Uncertainties in Luminescence Thermometry
    Thomas P. van SwietenA. MeijerinkF. Rabouw

    Materials Science, Physics

    ACS photonics

  • 2022

Materials with temperature-dependent luminescence can be used as local thermometers when incorporated in, for example, a biological environment or chemical reactor. Researchers have continuously

  • 36
  • PDF
Luminescence Thermometry Beyond the Biological Realm
    Benjamin HarringtonZiyang YeLaura SignorAndrea D. Pickel

    Physics, Materials Science

    ACS nanoscience Au

  • 2024

The motivations, methodologies, and advances linked to nonbiological applications of luminescence thermometry are reviewed, with expanding applications in areas such as thermal characterization of microelectronics, catalysis, and plasmonics.

  • 4
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15 References

Upconversion luminescence of NaYF4: Yb3+, Er3+ for temperature sensing
    Shaoshuai ZhouK. Deng M. Yin

    Materials Science

  • 2013
  • 243
Lanthanide upconversion luminescence at the nanoscale: fundamentals and optical properties.
    A. NadortJ. ZhaoE. Goldys

    Materials Science, Physics

    Nanoscale

  • 2016

This review discusses how the understanding of photophysical processes enabled a strategic influence over the optical properties of upconversion especially in rationally designed materials.

  • 236
  • PDF
Environmental and Excitation Power Effects on the Ratiometric Upconversion Luminescence Based Temperature Sensing Using Nanocrystalline NaYF4 :Yb3+ ,Er3.
    I. HyppänenNiina PeräläR. ArppeM. SchäferlingT. Soukka

    Environmental Science, Materials Science

    Chemphyschem : a European journal of chemical…

  • 2017

The LIR value is demonstrated to be unaffected by the excitation intensity in the studied range, which is essential, considering the application feasibility of the LIR method as temperature sensor, where the effective excitation power density depends on the sample matrix and the distance excitation light travels in the sample.

  • 35
Excitation efficiency determines the upconversion luminescence intensity of β-NaYF4:Er3+,Yb3+ nanoparticles in magnetic fields up to 70 T.
    A. BorodziukM. Baranowski Ł. Kłopotowski

    Physics, Materials Science

    Nanoscale

  • 2020

This work shows that the magnetic field impacts the luminescence only via a Zeeman-driven detuning between the excitation laser and the absorption transition, and proposes a phenomenological model, which qualitatively reproduces the experimental results.

  • 7
Comparative study on the up- and down-conversion optical ratiometric thermometry in one phosphor
    Leipeng LiFeng QinYangdong ZhengZhiguo Zhang

    Materials Science, Physics

    Materials Research Express

  • 2019

There is a long history of using the Er3+ ion’s 2H11/2/4S3/2–4I15/2 transitions for ratiometric thermal sensing. As demonstrated previously, these two transitions can be triggered via up- and

  • 2
Ratiometric upconversion nanothermometry with dual emission at the same wavelength decoded via a time-resolved technique
    Xiaochen QiuQianwen ZhouXingjun ZhuZugen WuWei FengFuyou Li

    Engineering, Materials Science

    Nature Communications

  • 2020

Improved accuracy is shown by using emission at the same wavelength, but different luminescent lifetimes decoded by a time-resolved technique, which improved the temperature monitoring ability and thermal resolution and sensitivity.

  • 178
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Time-resolved universal temperature measurements using NaYF4:Er3+,Yb3+ upconverting nanoparticles in an electrospray jet
    Kristina ShresthaArwa A. AlaulamieAli Rafiei MiandashtiH. Richardson

    Materials Science, Physics

    Beilstein journal of nanotechnology

  • 2018

The findings of this paper provide a foundation for time-resolved temperature measurements using NaYF4:Er3+,Yb3+ upconverting nanoparticles and can be used to understand temperature-dependent reactions such as protein unfolding inside microjet/microdroplets and microfluidic systems.

Excitation power dependent population pathways and absolute quantum yields of upconversion nanoparticles in different solvents.
    C. WürthMartin KaiserStefan WilhelmB. GrauelT. HirschU. Resch‐Genger

    Chemistry, Materials Science

    Nanoscale

  • 2017

The potential of excitation power density (P)-dependent studies of upconversion luminescence intensities, slope factors, and absolute quantum yields of popular β-NaYF4:20% Yb3+,2% Er3+ UCNPs of different surface chemistries in organic solvents, D2O, and water is demonstrated to gain deeper insight into the UC mechanism including population and deactivation pathways particularly of the red emission.

  • 84
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NaYF4:Er3+,Yb3+/SiO2 Core/Shell Upconverting Nanocrystals for Luminescence Thermometry up to 900 K
    R. GeitenbeekP. T. PrinsWiebke AlbrechtA. van BlaaderenBert M WeckhuysenA. Meijerink

    Materials Science, Physics

    The journal of physical chemistry. C…

  • 2017

The present results open avenues for the development of a new class of highly stable nanoprobes by applying a silica coating around a wide variety of lanthanide-doped NPs.

  • 168
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Apparent self-heating of individual upconverting nanoparticle thermometers
    Andrea D. PickelAyelet TeitelboimEmory M ChanN. BorysP. J. SchuckChris Dames

    Physics, Materials Science

    Nature Communications

  • 2018

It is reported that the common “ratiometric” thermometry signal of individual NaYF4:Yb3+,Er3+ nanoparticles unexpectedly increases with excitation intensity, implying a temperature rise over 50 K if interpreted as thermal.

  • 81
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    Notes on thermometric artefacts by Er3+ luminescence band interference | Semantic Scholar (2024)

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