The development of
materials with outstanding performance for sensitive
and selective detection of multiple analytes is essential for the
development of human health and society. Luminescent metal–organic
frameworks (LMOFs) have controllable surface and pore sizes and excellent
optical properties. Therefore, a variety of LMOF-based sensors with
diverse detection functions can be easily designed and applied. Furthermore,
the introduction of energy transfer (ET) into LMOFs (ET-LMOFs) could
provide a richer design concept and a much more sensitive and accurate
sensing performance. In this review, we focus on the recent five years
of advances in ET-LMOF-based sensing materials, with an emphasis on
photochemical and photophysical mechanisms. We discuss in detail possible
energy transfer processes within a MOF structure or between MOFs and
guest materials. Finally, the possible sensing applications of the
ET-LMOF-based sensors are highlighted.
Scintillators are critical for high-energy radiation
detection
across a wide array of potential applications, from medical radiography
and safety inspections all the way to space exploration. However,
constrained by their current shortcomings, including high-temperature
and complex fabrication as well as inherent brittleness and fragility
among thick films and bulk crystals, traditional scintillators are
finding it difficult to meet the rising demand for cost-effective,
ecofriendly, and flexible X-ray detection. Here, we describe the development
of high-performance and flexible X-ray scintillators based on films
of Cu-doped Cs2AgI3 that exhibit ultrahigh X-ray
sensitivity. The materials exhibit a high scintillation light yield
of up to 82 900 photons/MeV and a low detection limit of 77.8
nGy/s, which is approximately 70 times lower than the dosage for a
standard medical examination. Moreover, richly detailed X-ray images
of biological tissue and electronic components with a high spatial
resolution of 16.2 lp/mm were obtained using flexible, large-area,
solution-processed scintillation screens.
Copper-based halide scintillators have attracted considerable interest because of their high light yields, low detection limits, low toxicity, and moderate fabrication conditions. Here, we synthesized two Cu(I) iodide inks, comprising zero-dimensional Cu 4 I 6 (L 1 ) 2 nanoparticles (L 1 = 1-propyl-1,4-diazabicyclo[2.2.2]octan-1-ium) and one-dimensional Cu 4 I 6 (L 2 ) 2 nanorods (L 2 = 4-dimethylamino-1-ethylpyridinium) for X-ray imaging application. The Cu 4 I 6 (L 1 ) 2 nanoparticles and Cu 4 I 6 (L 2 ) 2 nanorods exhibited broadband green and yellow emission with an ultrahigh photoluminescence quantum yield of 95.3% and 92.2%, respectively. Consequently, the two Cu(I) iodide ink-based X-ray screens exhibited low detection limits of 96.4 and 102.1 nGy s −1 , respectively, which are approximately 55 times lower than the dose required for standard medical diagnosis (5.5 μGy s −1 ). Importantly, both the scintillation screens exhibited extraordinary X-ray imaging resolutions exceeding 30 lp mm −1 , more than double those of the conventional CsI:Tl and Ga 2 O 2 S:Tb scintillators. This study provides a new avenue for exploring high-resolution X-ray imaging screens on the basis of Cu-based halide ink for medical radiography and nondestructive detection.
Organic solid deposition control (OSDC) is a live oil test capable of simulating the production conditions of oil streams and can generate asphaltene deposits under production system conditions. OSDC can also simulate gas lift conditions because the producers are looking for artificial lift methods to produce oil from low-energy reservoirs. In this paper, we present the first compositional study on the OSDC deposits under gas lift conditions and compare it to C7 asphaltenes from the same crude oil precipitated in the laboratory, by use of ultra-high-resolution Fourier transform ion cyclotron resonance mass spectrometry. Furthermore, deposits collected from chemically treated fluids were also studied. The negative-ion mass spectra of OSDC deposits from untreated crude oil and asphaltene inhibitor (AI)-treated crude oil are richer in acidic species, such as the O
x
and S
x
O
y
polar classes, relative to the parent crude oil. The molecular-weight differences for treated deposits relative to the untreated sample may help explain the deposition tendency in the tests. We infer that a correlation of field asphaltene deposition tendency with laboratory screening tests is essential for the advancement of asphaltene research.
Mixed-matrix membranes (MMMs) based on luminescent metal−organic frameworks (MOFs) and emissive polymers with the combination of their unique advantages have great potential in separation science, sensing, and light-harvesting applications. Here, we demonstrate MMMs for the field of highspeed visible-light communication (VLC) using a very efficient energy transfer strategy at the interface between a MOF and an emissive polymer. Our steady-state and ultrafast time-resolved experiments, supported by high-level density functional theory calculations, revealed that efficient and ultrafast energy transfer from the luminescent MOF to the luminescent polymer can be achieved. The resultant MMMs exhibited an excellent modulation bandwidth of around 80 MHz, which is higher than those of most wellestablished color-converting phosphors commonly used for optical wireless communication. Interestingly, we found that the efficient energy transfer further improved the light communication data rate from 132 Mb/s of the pure polymer to 215 Mb/s of MMMs. This finding not only showcases the promise of the MMMs for high-speed VLC but also highlights the importance of an efficient and ultrafast energy transfer strategy for the advancement of data rates of optical wireless communication.
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