Conjugated polymers have chemically tuneable opto-electronic properties and are easily processed, making them attractive materials for photonics applications. Conjugated polymer lasers, in a variety of resonator geometries such as microcavity, micro-ring, distributed feedback and photonic bandgap structures, have been fabricated using a range of coating and imprinting techniques. Currently, one-dimensional nanowires are emerging as promising candidates for integrated, subwavelength active and passive photonic devices. We report the first observation of optically pumped lasing in single conjugated polymer nanowires. The waveguide and resonator properties of each wire are characterized in the far optical field at room temperature. The end faces of the nanowire are optically flat and the nanowire acts as a cylindrical optical cavity, exhibiting axial Fabry-Pérot mode structure in the emission spectrum. Above a threshold incident pump energy, the emission spectrum collapses to a single, sharp peak with an instrument-limited line width that is characteristic of single-mode excitonic laser action.
Extensive research has been pursued to develop low-cost and high-performance functional inorganic-organic hybrid materials for clean/renewable energy related applications. While great progress has been made in the recent years, some key challenges remain to be tackled. One major issue is the generally poor stability of these materials, which originates from relatively fragile/weak bonds between inorganic and organic constituents. Herein, we report a unique "all-in-one" (AIO) approach in constructing robust structures with desired properties. Such approach allows formation of both ionic and coordinate bonds within a molecular cluster, which greatly enhances structural stability while maintaining the molecular identity of the cluster and its high luminescence. The novel AIO structures are composed of various anionic (CuI) clusters and cationic N-ligands. They exhibit high luminescence efficiency, significantly improved chemical, thermal and moisture stability, and excellent solution processability. Both temperature dependent photoluminescence experiments and DFT calculations are performed to investigate the luminescence origin and emission mechanism of these materials, and their suitability as energy-saving LED lighting phosphors is assessed. This study offers a new material designing strategy that may be generalized to many other material classes.
Integration of organic/inorganic hybrid perovskites with metallic or semiconducting phases of 2D MoS nanosheets via solution processing is demonstrated. The results show that the collection of charge carriers is strongly dependent on the electronic properties of the 2D MoS with metallic MoS showing high responsivity and the semiconducting phase exhibiting high on/off ratios.
The synthesis, structure, internal morphology, and optical characteristics of melt‐processed polyfluorene nanowires are presented. Single wires can act as nanoscale active optical waveguides, allowing locally excited photoluminescence to propagate along a wire axis prior to out‐coupling at the tips (see image). The nanowire waveguide loss mechanisms and their physical origins are investigated.
The authors have designed and synthesized a family of high-performance inorganic-organic hybrid phosphor materials composed of extended and robust networks of one, two, and three dimensions. Following a bottomup solution-based synthetic approach, these structures are constructed by connecting highly emissive Cu 4 I 4 cubic clusters via carefully selected ligands that form strong CuN bonds. They emit intensive yellow-orange light with high luminescence quantum efficiency, coupled with large Stokes shift, which greatly reduces self-absorption. They also demonstrate exceptionally high framework-and photostability, comparable to those of commercial phosphors. The high stabilities are the result of significantly enhanced CuN bonds, as confirmed by the density functional theory (DFT) binding energy and electron density calculations. Possible emission mechanisms are analyzed based on the results of theoretical calculations and optical experiments. Two-component white phosphors obtained by blending blue and yellow emitters reach an internal quantum yield as high as 82% and correlated color temperature as low as 2534 K. The performance level of this subfamily exceeds all other types of Cu-I based hybrid systems. The combined advantages make them excellent candidates as alternative rare-earth element-free phosphors for possible use in energy-efficient lighting devices.
Inorganic semiconductor materials
are best known for their superior
physical properties, as well as their structural rigidity and stability.
However, the poor solubility and solution-processability of these
covalently bonded network structures has long been a serious drawback
that limits their use in many important applications. Here, we present
a unique and general approach to synthesize robust, solution-processable,
and highly luminescent hybrid materials built on periodic and infinite
inorganic modules. Structure analysis confirms that all compounds
are composed of one-dimensional anionic chains of copper iodide (Cu
m
I
m+2
2–) coordinated to cationic organic ligands via Cu–N bonds.
The choice of ligands plays an important role in the coordination
mode (μ1-MC or μ2-DC) and Cu–N
bond strength. Greatly suppressed nonradiative decay is achieved for
the μ2-DC structures. Record high quantum yields
of 85% (λex = 360 nm) and 76% (λex = 450 nm) are obtained for an orange-emitting 1D-Cu4I6(L
6). Temperature dependent PL
measurements suggest that both phosphorescence and thermally activated
delayed fluorescence contribute to the emission of these 1D-AIO compounds,
and that the extent of nonradiative decay of the μ2-DC structures is much less than that of the μ1-DC
structures. More significantly, all compounds are remarkably soluble
in polar aprotic solvents, distinctly different from previously reported
CuI based hybrid materials made of charge-neutral Cu
m
X
m
(X = Cl, Br, I), which are totally
insoluble in all common solvents. The greatly enhanced solubility
is a result of incorporation of ionic bonds into extended covalent/coordinate
network structures, making it possible to fabricate large scale thin
films by solution processes.
The recent pandemic of the novel coronavirus disease 2019 (COVID‐19) has caused huge worldwide disruption due to the lack of available testing locations and equipment. The use of optical techniques for viral detection has flourished in the past 15 years, providing more reliable, inexpensive, and accurate detection methods. In the current minireview, optical phenomena including fluorescence, surface plasmons, surface‐enhanced Raman scattering (SERS), and colorimetry are discussed in the context of detecting virus pathogens. The sensitivity of a viral detection method can be dramatically improved by using materials that exhibit surface plasmons or SERS, but often this requires advanced instrumentation for detection. Although fluorescence and colorimetry lack high sensitivity, they show promise as point‐of‐care diagnostics because of their relatively less complicated instrumentation, ease of use, lower costs, and the fact that they do not require nucleic acid amplification. The advantages and disadvantages of each optical detection method are presented, and prospects for applying optical biosensors in COVID‐19 detection are discussed.
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