From Molecular Design and Materials Construction to Organic Nanophotonic Devices

Zhang, Chuang; Yan, Yongli; Zhao, Yong; Yao, Jiannian

doi:10.1021/ar500192v

Cited by 132 publications

(123 citation statements)

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“…At a cellular level, CT is responsible for a range of chemical and biochemical transformations, and is essential for life on Earth to exist [1][2][3][4][5]. In addition to its vital role in living systems, CT resides at the heart of energy conversion, transduction and storage [6][7][8][9][10][11][12][13], and provides signal transduction for devices integral to our modern lifestyles [14,15]. For more than a century, the key importance of CT has sustained the ever-growing scientific interest in it.…”

Section: Introductionmentioning

confidence: 99%

Building blocks for bioinspired electrets: molecular-level approach to materials for energy and electronics

Larsen

Espinoza

Hartman

et al. 2015

Pure and Applied Chemistry

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In biology, an immense diversity of protein structural and functional motifs originates from only 20 common proteinogenic native amino acids arranged in various sequences. Is it possible to attain the same diversity in electronic materials based on organic macromolecules composed of non-native residues with different characteristics? This publication describes the design, preparation and characterization of non-native aromatic β-amino acid residues, i.e. derivatives of anthranilic acid, for polyamides that can efficiently mediate hole transfer. Chemical derivatization with three types of substituents at two positions of the aromatic ring allows for adjusting the energy levels of the frontier orbitals of the anthranilamide residues over a range of about one electronvolt. Most importantly, the anthranilamide residues possess permanent electric dipoles, adding to the electronic properties of the bioinspired conjugates they compose, making them molecular electrets.

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Section: Introductionmentioning

confidence: 99%

Building blocks for bioinspired electrets: molecular-level approach to materials for energy and electronics

Larsen

Espinoza

Hartman

et al. 2015

Pure and Applied Chemistry

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“…In recent years, functional organic nanomaterials have attracted increasing research interest, due to their potential use in optoelectronics [1,2], nonlinear optics [3,4], and photonics [5,6].…”

Section: Introductionmentioning

confidence: 99%

Sharp and bright photoluminescence emission of single-crystalline diacetylene nanoparticles

Kim

Park

et al. 2016

Journal of the Korean Physical Society

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Amorphous nanoparticles (NPs) of diacetylene (DA) molecules were prepared by using a reprecipitation method. After crystallization through solvent-vapor annealing process, the highly crystalline DA NPs show different structural and optical characteristics compared with the amorphous DA NPs. The single crystal structure of DA NPs was confirmed by high-resolution transmission electron microscopy (HR-TEM) and wide angle X-ray scattering (WAXS). The luminescence color and photoluminescence (PL) characteristics of the DA NPs were measured using color charge-coupled device (CCD) images and high-resolution laser confocal microscope (LCM). The crystalline DA NPs emit bright green light emission compared with amorphous DA NPs and the main PL peak of the crystalline DA NPs exhibits relative narrow and blue shift phenomena due to enhanced interaction between DA molecular in the nano-size crystal structure.

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“…Spatially PL resolved spectra confirm that Ln-MOF microrods exhibit an optical waveguide effect with loww aveguide loss coefficient (0.012 % 0.033 dB mm À1 )d uring propagation. [10] During the past decade,o nedimensional (1D) nano-/micro-sized systems including wires, tubes,r ods and belts have captured broad attention because of their novel physical/chemical properties,a nd wide applications in nano-and microdevices. [6] Owing to the forbidden f-f transitions, trivalent lanthanide cations usually have weak light absorption, [7] and thus make the direct lanthanide excitation inefficient.…”

mentioning

confidence: 99%

“…[6] Owing to the forbidden f-f transitions, trivalent lanthanide cations usually have weak light absorption, [7] and thus make the direct lanthanide excitation inefficient. [12] Up to now,r esearch on waveguides has focused on inorganic semiconductors, [13] organic chromophores, [10,14] and polymers. [8] During the ligand-to-metal energy-transfer process,i ti so fs ignificance to select suitable organic linkers with high molar absorption coefficient and appropriate energy level in the target Ln-MOFs.…”

mentioning

confidence: 99%

“…[11] Recently,t he use of nano-to micro-sized waveguides have attracted considerable interest for their possible application as basic components in optical communication systems. [12] Up to now,r esearch on waveguides has focused on inorganic semiconductors, [13] organic chromophores, [10,14] and polymers. [15] In theory,L n-MOFs can potentially serve as idealized models to develop new optical waveguide systems due to the following reasons: 1) the design of organic chromophores and different trivalent lanthanide cations can give rise to high emission quantum yields and tunable emission colors;2 )the well-organization and ordered assembly of ligands and lanthanide cations could decrease the optical loss;3 )the metal-organic hybrids can usually enhance the photostability relative to the pristine organic units.However,much less attention has been paid on Ln-MOFs-based optical waveguide to date,probably because of the lack of suitable low-dimensional Ln-MOFs micro/ nanostructures.…”

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confidence: 99%

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Lanthanide Metal–Organic Framework Microrods: Colored Optical Waveguides and Chiral Polarized Emission

et al. 2017

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Lanthanide metal-organic frameworks (Ln-MOFs) have received mucha ttention owing to their structural tunability and widely photofunctional applications.H owever, successful examples of Ln-MOFs with well-defined photonic performances at micro-/nanometer size are still quite limited. Herein, self-assemblies of 1,3,5-benzenetricarboxylic acid (BTC) and lanthanide ions affordi sostructural crystalline Ln-MOFs.T b-BTC,E u@Tb-BTC,a nd Eu-BTC have 1D microrod morphologies,h igh photoluminescence (PL) quantum yields,a nd different emission colors (green, orange,a nd red). Spatially PL resolved spectra confirm that Ln-MOF microrods exhibit an optical waveguide effect with loww aveguide loss coefficient (0.012 % 0.033 dB mm À1 )d uring propagation. Furthermore,t hese microrods feature both linear and chiral polarized photoemission with high anisotropy.Lanthanide metal-organic frameworks (Ln-MOFs) have attracted great attention because of their unique crystal structures, [1] fascinating photophysical properties (such as sharp emission band and high quantum yields), coupled with potential applications in biomedical imaging, [2] anti-counterfeiting tags, [3] optical fiber lasers, [4] sensors, [5] and light emitting devices. [6] Owing to the forbidden f-f transitions, trivalent lanthanide cations usually have weak light absorption, [7] and thus make the direct lanthanide excitation inefficient. This problem can be possibly overcome in Ln-MOFs with the aid of organic sensitizer through the so-called antenna effect. [8] During the ligand-to-metal energy-transfer process,i ti so fs ignificance to select suitable organic linkers with high molar absorption coefficient and appropriate energy level in the target Ln-MOFs.In general, the photonic properties of molecular materials not only depend on intra/inter-molecular excited-state (exciton) processes (such as exciton generation, migration, conversion/transfer,r ecombination and dissociation), [9] but also on the shape,size and dimension of their solid-state structures that strongly influence the optical behaviors by reflecting, refracting,a nd diffracting. [10] During the past decade,o nedimensional (1D) nano-/micro-sized systems including wires, tubes,r ods and belts have captured broad attention because of their novel physical/chemical properties,a nd wide applications in nano-and microdevices. [11] Recently,t he use of nano-to micro-sized waveguides have attracted considerable interest for their possible application as basic components in optical communication systems. [12] Up to now,r esearch on waveguides has focused on inorganic semiconductors, [13] organic chromophores, [10,14] and polymers. [15] In theory,L n-MOFs can potentially serve as idealized models to develop new optical waveguide systems due to the following reasons: 1) the design of organic chromophores and different trivalent lanthanide cations can give rise to high emission quantum yields and tunable emission colors;2 )the well-organization and ordered assembly of ligands and lanthanide cations could decrease the ...

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From Molecular Design and Materials Construction to Organic Nanophotonic Devices

Cited by 132 publications

References 61 publications

Building blocks for bioinspired electrets: molecular-level approach to materials for energy and electronics

Building blocks for bioinspired electrets: molecular-level approach to materials for energy and electronics

Sharp and bright photoluminescence emission of single-crystalline diacetylene nanoparticles

Lanthanide Metal–Organic Framework Microrods: Colored Optical Waveguides and Chiral Polarized Emission

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