2021
DOI: 10.1111/jace.17880
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NIR‐I/III afterglow induced by energy transfers between Er and Cr codoped in ZGGO nanoparticles for potential bioimaging

Abstract: Herein, Cr3+ and Er3+ codoped zinc gallogermanate (ZGGO) nanoparticles with average size of ~60 nm was synthesized via a hydrothermal path. It was found that near infrared (NIR)‐III (~1540 nm) afterglow was realized in ZGGO:Cr3+,Er3+ nanoparticles based on the successive energy transfer (ET) from Cr3+ to Er3+ after the stoppage of low‐dose (60 mSv) X‐ray irradiation. Meanwhile, the upconverted afterglow at 696 nm was produced via the ET from Er3+ to Cr3+ under different NIR light (808, 980, and 1532 nm) irradi… Show more

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Cited by 14 publications
(5 citation statements)
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“…The ultra‐long afterglow displayed by the particles shows the path and direction for the research of developing new Tb 3+ ‐doped nanomaterials. Yang et al [66] . synthesized Cr 3+ and Er 3+ co‐doped zinc gallogermanate (Abbreviated as ZGGO : Cr 3+ ,Er 3+ ) nanoparticles with particle sizes are around ~60 nm via hydrothermal method with an annealing process in the ambient of vacuum.…”
Section: Synthetic Methodsmentioning
confidence: 99%
See 1 more Smart Citation
“…The ultra‐long afterglow displayed by the particles shows the path and direction for the research of developing new Tb 3+ ‐doped nanomaterials. Yang et al [66] . synthesized Cr 3+ and Er 3+ co‐doped zinc gallogermanate (Abbreviated as ZGGO : Cr 3+ ,Er 3+ ) nanoparticles with particle sizes are around ~60 nm via hydrothermal method with an annealing process in the ambient of vacuum.…”
Section: Synthetic Methodsmentioning
confidence: 99%
“…The ultra-long afterglow displayed by the particles shows the path and direction for the research of developing new Tb 3 + -doped nanomaterials. Yang et al [66] synthesized Cr 3 + and Er 3 + co-doped zinc gallogermanate (Abbreviated as ZGGO : Cr 3 + ,Er 3 + ) nanoparticles with particle sizes are around ~60 nm via hydrothermal method with an annealing process in the ambient of vacuum. The effective energy transfer from Cr 3 + to Er 3 + was realized by the co-doping of Cr 3 + and Er 3 + , and the results demonstrated the excellent PersL of Er 3 + in NIR-III.…”
Section: Hydrothermal/solvothermal Methodsmentioning
confidence: 99%
“…154,155 Therefore, they have a considerable influence on the timing and intensity of the afterglow. 156 Co-dopants generally emit no or very weak luminescence. 157 The duration and intensity of the afterglow emission are closely related to the properties of the co-dopants, such as valence states, energy levels structure, optical electronegativity, doping content, and treatment temperature.…”
Section: Co-dopantsmentioning
confidence: 99%
“…8 Furthermore, based on the PET from transition metal (TM) ions to RE ions, ZGGO:Cr 3+ ,Nd 3+ and ZGGO:Cr 3+ ,Er 3+ NIR-II persistent luminescence nanoparticles with emission at 1067 and 1530 nm were developed. 9,10 However, for the aforementioned nanoparticles, the narrow-band emissions and relatively poor luminescence performance of RE ions have limited their biomedical applications. 11 Fortunately, Ni 2+ ions (TM ions)-doped gallate-based luminescence materials exhibited wideband emission (1000-1700 nm) originating from d-d electron transitions and excellent persistent luminescence performance.…”
Section: Introductionmentioning
confidence: 99%
“…prepared Eu 2+ , Dy 3+ , and Er 3+ co‐doped SrAl 2 O 4 persistent luminescence materials with NIR‐II emission at 1530 nm by means of the persistent energy transfer (PET) between RE ions 8 . Furthermore, based on the PET from transition metal (TM) ions to RE ions, ZGGO:Cr 3+ ,Nd 3+ and ZGGO:Cr 3+ ,Er 3+ NIR‐II persistent luminescence nanoparticles with emission at 1067 and 1530 nm were developed 9,10 . However, for the aforementioned nanoparticles, the narrow‐band emissions and relatively poor luminescence performance of RE ions have limited their biomedical applications 11 …”
Section: Introductionmentioning
confidence: 99%