The growing demand for spectroscopy applications in the areas of agriculture, retail and healthcare has led to extensive research on infrared light sources. The ability of phosphors to absorb blue light from commercial LED and convert the excitation energy into long-wavelength infrared luminescence is crucial for the design of cost-effective and high-performance phosphor-converted infrared LEDs. However, the lack of ideal blue-pumped short-wave infrared (SWIR) phosphors with an emission peak longer than 900 nm greatly limits the development of SWIR LEDs using light converter technology. Here we have developed a series of SWIR-emitting materials with high luminescence efficiency and excellent thermal stability by co-doping Cr3+-Yb3+ ion pairs into Lu0.2Sc0.8BO3 host materials. Benefitting from strong light absorption of Cr3+ in the blue waveband and very efficient Cr3+→Yb3+ energy transfer, the as-synthesized Lu0.2Sc0.8BO3:Cr3+,Yb3+ phosphor emits intense SWIR light in the 900–1200 nm from Yb3+ under excitation with blue light at ~460 nm. The optimized phosphor presents an internal quantum yield of 73.6% and the SWIR luminescence intensity at 100 °C can still keep 88.4% of the starting value at 25 °C. SWIR LED prototype device based on Lu0.2Sc0.8BO3:Cr3+,Yb3+ phosphor exhibits exceptional luminescence performance, delivering SWIR radiant power of 18.4 mW with 9.3% of blue-to-SWIR power conversion efficiency and 5.0% of electricity-to-SWIR light energy conversion efficiency at 120 mA driving current. Moreover, under the illumination of high-power SWIR LED, covert information identification and night vision lighting have been realized, demonstrating a very bright prospect for practical applications.
Infrared-emitting
phosphor-converted light-emitting diodes (LEDs)
are desirable light sources for a very wide range of applications
such as spectroscopy analysis, nondestructive monitoring, covert information
identification, and night-vision surveillance. The most important
aspect of infrared emitters for spectroscopy is to cover the widest
possible wavelength range of emitted light. However, developing ultrabroad-band
infrared emitters based on converter technology is still a challenging
task due to the lack of suitable phosphor materials that emit in a
wide wavelength range upon excitation from blue-emitting chips. Herein,
this work demonstrates Cr3+-activated Mg2SiO4 infrared phosphors with a super wide infrared spectral range
of 600 to 1400 nm and high internal quantum yield up to 80.4% upon
460 nm excitation. Site-selective occupancy of Cr3+ emitters
in two different Mg sites in the Mg2SiO4 lattice
results in two distinct broad emission bands peaking at 760 and 970
nm, both of which contribute to the ultrabroad-band infrared luminescence
with a full width at half maximum (FWHM) of 419 nm. This is by far
the broadest infrared emission to the best of our knowledge. On this
basis, an ultrabroad-band infrared LED prototype has been fabricated
by the combination of the Mg2SiO4:Cr3+ phosphor with a blue LED chip, which shows great potential for imaging
and sensing applications. This work demonstrates that site-selective
occupancy control of Cr ions is an effective strategy for developing
ultrabroad-band Cr3+-doped phosphors.
Photostimulated luminescence (PSL) materials have attracted considerable attention in many important fields, varying from radiation dosimetry and biomedical imaging to security encryption and optical data storage. Nevertheless, monochromatic light illumination...
Luminescence Boltzmann thermometry is becoming one of the most trustworthy methods for locally measuring temperature in noncontact mode. In this work, we report a comprehensive spectroscopic study of the Cr3+...
Persistent phosphors emitting in the narrowband ultraviolet-B (NB-UVB) spectral region have aroused significant interest, owing to their special self-illuminating feature in realizing many advanced technological applications under excitation-free conditions, such as dermatological therapy and invisible optical tagging. Here, we focus our discussion on a new Gd 3+ -doped persistent phosphor, Sr 2 P 2 O 7 :Gd 3+ , which exhibits long-lasting NB-UVB persistent luminescence peaking at 312 nm for more than 24 h after charging by an X-ray beam. The NB-UVB light emission from the charged Sr 2 P 2 O 7 :Gd 3+ phosphor can be clearly detected by a UVB camera in bright indoor environment. More importantly, the enhancement of NB-UVB afterglow intensity and decay time can be observed under continuous photostimulation of polychromic indoor ambient light. Furthermore, applying charged Sr 2 P 2 O 7 :Gd 3+ phosphors as invisible optical taggants, clear and interference-free recognition of the encrypted message and location of different objects have been realized due to the lack of UVB light in bright indoor environment. The as-prepared Sr 2 P 2 O 7 :Gd 3+ persistent phosphor is expected to offer new directional solutions for the development and application of ultraviolet luminescence technology.
Bismuth-based fluoride nanocrystalline materials are becoming an emerging class of host matrixes for luminescent lanthanide ions (Ln3+). However, the synthesis of morphology-controlled bismuth-based fluoride nanocrystals still remains a challenging work....
Narrowband ultraviolet-B (NB-UVB) luminescent materials are characterized by high photon energy, narrow spectral width, and visible-blind emission, thus holding great promise for photochemistry and photomedicine. However, most NB-UVB phosphors developed so far are photoluminescent, where continuous external excitation is needed. Herein, we realize NB-UVB persistent luminescence (PersL) in an indoor-lighting environment by exploiting the interaction between self-trapped/defecttrapped excitons and Gd 3+ emitters in ScPO 4 . The phosphor shows a self-luminescing feature with a peak maximum at 313 nm with a time duration of >24 h after ceasing Xray irradiation, which can be clearly imaged by an UVB camera in a bright environment. Spectroscopic and theoretical approaches reveal that thermo-and photo-stimulations of energies trapped at intrinsic lattice defects followed by energy transfer to Gd 3+ emitters account for the emergence of the afterglow. The present results can initiate more exploration of NB-UVB PersL phosphors for emerging applications in secret optical tagging and phototherapy.
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