Abstract:heterojunctions have been constructed and demonstrated for controlling optical, [1] electrical, [2] mechanical [3] and magnetic characteristics. [4] In particular, semiconductor heterojunctions as the core of light-emitting diodes (LEDs) have played vital roles in electric-driven lighting and display devices. The electric potential of a semiconductor heterojunction has a strong positive effect on charge carrier transport at the interface and can tune/ control the behaviors of light emitting. [5] The advance… Show more
“…Among these, some typical oxysulfides notably enriched the color of ML emission due to its good acceptance for a large number of activators (Zhang et al, 2013 , 2015 ). It is proved that some new oxysulfide semiconductors that doped with luminescent ions, for instance, transitional metals and lanthanide ions doped CaZnOS (Huang, 2016 ; Huang et al, 2017 ; Du et al, 2019 ), SrZnOS (Chen et al, 2020 ), and BaZnOS (Li et al, 2016 ) single compounds as well as CaZnOS-ZnS heterojunctions (Peng et al, 2020 ) show novel ML performances that result in diverse applications. Meanwhile, some oxysulfides, such as Gd 2 O 2 S-based luminescent material (Büchele et al, 2015 ), has been commercialized and confirmed to be good X-ray phosphors.…”
Under the excitation of ultraviolet, X-ray, and mechanical stress, intense orange luminescence (Mn 2+ , 4 T 1 → 6 A 1) can be generated in Mn 2+-doped SrZn 2 S 2 O crystal in orthorhombic space group of Pmn2 1. Herein, the multiple energy conversion in SrZn 2 S 2 O:Mn 2+ , that is, photoluminescence (PL), X-ray-induced luminescence, and mechanoluminescence, is investigated. Insight in luminescence mechanisms is gained by evaluating the Mn 2+ concentration effects. Under the excitation of metal-to-ligand charge-transfer transition, the most intense PL is obtained. X-ray-induced luminescence shows similar features with PL excited by band edge UV absorption due to the same valence band to conduction band transition nature. Benefiting much from trap levels introduced by Mn 2+ impurities, the quenching behavior mechanoluminescence is more like the directly excited PL from Mn 2+ d-d transitions. Interestingly, this concentration preference leads to varying degrees of spectral redshift in each mode luminescence. Further, SrZn 2 S 2 O:Mn 2+ exhibits a good linear response to the excitation power, which makes it potential candidates for applications in X-ray radiation detection and mechanical stress sensing.
“…Among these, some typical oxysulfides notably enriched the color of ML emission due to its good acceptance for a large number of activators (Zhang et al, 2013 , 2015 ). It is proved that some new oxysulfide semiconductors that doped with luminescent ions, for instance, transitional metals and lanthanide ions doped CaZnOS (Huang, 2016 ; Huang et al, 2017 ; Du et al, 2019 ), SrZnOS (Chen et al, 2020 ), and BaZnOS (Li et al, 2016 ) single compounds as well as CaZnOS-ZnS heterojunctions (Peng et al, 2020 ) show novel ML performances that result in diverse applications. Meanwhile, some oxysulfides, such as Gd 2 O 2 S-based luminescent material (Büchele et al, 2015 ), has been commercialized and confirmed to be good X-ray phosphors.…”
Under the excitation of ultraviolet, X-ray, and mechanical stress, intense orange luminescence (Mn 2+ , 4 T 1 → 6 A 1) can be generated in Mn 2+-doped SrZn 2 S 2 O crystal in orthorhombic space group of Pmn2 1. Herein, the multiple energy conversion in SrZn 2 S 2 O:Mn 2+ , that is, photoluminescence (PL), X-ray-induced luminescence, and mechanoluminescence, is investigated. Insight in luminescence mechanisms is gained by evaluating the Mn 2+ concentration effects. Under the excitation of metal-to-ligand charge-transfer transition, the most intense PL is obtained. X-ray-induced luminescence shows similar features with PL excited by band edge UV absorption due to the same valence band to conduction band transition nature. Benefiting much from trap levels introduced by Mn 2+ impurities, the quenching behavior mechanoluminescence is more like the directly excited PL from Mn 2+ d-d transitions. Interestingly, this concentration preference leads to varying degrees of spectral redshift in each mode luminescence. Further, SrZn 2 S 2 O:Mn 2+ exhibits a good linear response to the excitation power, which makes it potential candidates for applications in X-ray radiation detection and mechanical stress sensing.
“…[ 16 ] In order to achieve continuous optogenetic stimulation, lanthanide‐doped CaZnOS crystals were selected as the candidate materials, which could generate sustainable ML through a piezophotonic effect, in which the photonic excitation was established by mechanically induced tribo/piezoelectric potential in the CaZnOS ( Figure a,b). [ 17 ] As an added benefit, the CaZnOS crystals can host a variety of dopants, such as manganese and lanthanides, for the delivery of tunable ML spectra (Figure 1b). The excitation energy was extracted by dopant ions in the CaZnOS host, wherein characteristic emission peaks at different wavelengths were generated (Figure 1c; Figure S1d, Supporting Information).…”
Mechanoluminescence (ML) is characterized by photon emission under mechanical action, which is promising for biomedical applications, such as stress sensing and artificial skin. However, the use of ML in deep tissues has encountered a bottleneck due to the need for contact excitation. In this paper, a magneto‐luminescence microdevice (MLMD) is devised to realize optical emission through non‐contact excitation of a rotating magnetic field. The MLMD is composed of ML materials (lanthanide‐doped CaZnOS crystals) and a magnet bar, in which the magnet bar can collect excitation energy of the magnetic field and then drive the ML materials to emit light by rotational motion. The optical emission of the MLMD is used to remotely stimulate two optogenetic models at different tissue depths, including subcutaneous photodynamic therapy of tumor and neuromodulation of behaving mice. This work establishes an innovative approach to achieve remote control of light delivery, which is expected to inspire new applications in biomedicine.
“…Interestingly, in 2020, Peng et al.’s research work has reached this goal to some extent. Herein, a new class of heterojunctioned ZnS/CaZnOS piezophotonic system with remarkable ML performance in both intensity and reproducibility was demonstrated ( Figure 4 ) ( Peng et al., 2020 ). ZnS and CaZnOS were prepared by controlling the ratio of CaCO 3 and ZnS, and they accommodate Mn 2+ and lanthanide ions (such as Tm 3+ , Yb 3+ , and Pr 3+ NIR luminescent ions), respectively.…”
Section: Known Nir Mechanoluminescent Crystalsmentioning
confidence: 99%
“… Figure 4 Scheme of proposed mechanism for mechanical-to-optical energy conversion in the piezophotonic semiconductor heterojunction Scheme of proposed mechanism for mechanical-to-optical energy conversion in the piezophotonic semiconductor heterojunction: electronic transition in the ML process is facilitated by band offsets at the heterojunction interface region (indicated by the red frame). Reproduced with permission from ( Peng et al., 2020 ). Copyright 2020 WILEY.…”
Section: Known Nir Mechanoluminescent Crystalsmentioning
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
