Spontaneous emission from radiative chiral nematic liquid crystals at the photonic band-gap edge: An investigation into the role of the density of photon states near resonance

Mavrogordatos, Themistoklis K.; Morris, Stephen M.; Wood, Simon; Coles, H. J.; Wilkinson, Timothy D.

doi:10.1103/physreve.87.062504

Cited by 12 publications

(2 citation statements)

References 14 publications

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“…Photons in the frequency range of the PBG are completely excluded so that atoms within such materials are unable to spontaneously absorb and re‐emit light in this region; this has obvious beneficial implications for producing highly efficient lasers. [ 6 ] The PBG is an optical cavity that is known to modulate the photoluminescence (PL) intensity efficiently. As the photon density of states (DOS) is higher at the band edges of a PC than at its center, the photon dwell time is increased at the edges, enhancing the spontaneous emission intensity.…”

Section: Introductionmentioning

confidence: 99%

Efficient Fluorescence Utilization and Photon Density of States‐Driven Design of Liquid Crystal Lasers

Qu,

Hu,

et al. 2024

Laser & Photonics Reviews

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Liquid‐crystal random lasers (LCRLs) represent a burgeoning field in soft‐matter photonics, holding promise for ushering in an era of ultrathin, versatile laser sources. Such lasers encompass a multitude of remarkable features, including wide‐band tunability, large coherence area and, in some cases, multidirectional emission. In this paper, an LCRL is developed by doping a laser dye, pyrromethene 597 (PM597), into cholesteric LC, but achieving a wide‐range wavelength‐controllable (560–720 nm) bandgap lasing through voltage control. Bandgap lasing intriguingly occurs in media with extremely low dye gain, which is mainly contributed by the extremely high photon density of states (DOS) at the edge of the LC bandgap. In addition, the utilization rate of the fluorescence spectrum (550–750 nm) of laser dye PM597 is as high as 80%. The multivariate linear regression model is used to characterize the inherent relationship between the lasing intensity emitted by LC and the photon DOS, fluorescence quantum yield, and internal scattering under specific pumping energy. This model shows the potential to predict the critical conditions of laser emission accurately and provides the capability to design and fabricate large‐scale multifunctional responsive photonic crystals using a simple fabrication procedure.

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Section: Introductionmentioning

confidence: 99%

Efficient Fluorescence Utilization and Photon Density of States‐Driven Design of Liquid Crystal Lasers

Qu,

Hu,

et al. 2024

Laser & Photonics Reviews

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“…In these applications understanding the underlying physics of spontaneous emission of emitters embedded in LC is crucial, notably at criticality. Some numerical [37] and theoretical [38] studies on spontaneous emission in LC do exist, but to the best of our knowledge none of them investigate the role of LC phase transitions on quantum emission, which is precisely the crucial element for recent applications, as discussed above.…”

Section: Introductionmentioning

confidence: 99%

Spontaneous emission in inertial and dissipative nematic liquid crystals: the role of critical phenomena

Nascimento

Pinheiro

Neto

2021

J. Phys.: Condens. Matter

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We develop a rigorous, field-theoretical approach to the study of spontaneous emission in inertialand dissipative nematic liquid crystals, disclosing an alternative application of the massive Stueck-elberg gauge theory to describe critical phenomena in these systems. This approach allows one notonly to unveil the role of phase transitions in the spontaneous emission in liquid crystals but also to make quantitative predictions for quantum emission in realistic nematics of current scientific andtechnological interest in the field of metamaterials. Specifically, we predict that one can switchon and off quantum emission in liquid crystals by varying the temperature in the vicinities of thecrystalline-to-nematic phase transition, for both the inertial and dissipative cases. We also predictfrom first principles the value of the critical exponent that characterizes such a transition, whichwe show not only to be independent of the inertial or dissipative dynamics, but also to be in goodagreement with experiments. We determine the orientation of the dipole moment of the emitterrelative to the nematic director that inhibits spontaneous emission, paving the way to achieve direc-tionality of the emitted radiation, a result that could be applied in tuneable photonic devices suchas metasurfaces and tuneable light sources.

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Mechanochromism of Structural‐Colored Materials

Chen

Hong

2020

Advanced Optical Materials

135

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In comparison with pigmentary colors, structural colors are with superior chemical stability and are resistant to photobleaching, making them promising candidates for color displays. What is more, the use of toxic dyes can be avoided by utilizing structural-colored materials to display various hues. Structural colors are widespread in nature and observed in opals, [3] beetles, [4] tropical fish, [5] peacock feathers, [6] chameleons, and similar iridescent materials. [7-9] Along with the growing understanding of the morphology and mechanism of natural structural-colored materials, their artificial counterparts have been manufactured with improved performance and functions consequently. Emerging structural-colored materials can be divided into three main categories according to their nanoscale architectures: photonic crystals (PCs), [10] liquid crystals (LCs), [11] and photonic glass. [12] Due to their ability to modulate visible light, the structural-colored materials have been applied in diverse domains such as optical waveguides, [13-16] luminescence enhancement, [17-19] photo electric devices, [20,21] photocatalysts, [22,23] anti-counterfeiting technologies, [24-26] and chemical and biological sensing. [27-29] With ingenious designs of nanostructures, a variety of responsiveness has been obtained on the structural-colored materials, corresponding to varying stimuli such as temperature, [30-32] solvent, [27] gases, [28] magnetic fields, [33] and external forces. [10-12] Among them, the mechanical responsive structural colors are able to visualize invisible stress in the materials, providing effective indicators for mechanical stimuli such as stretching, compression, or bending. Such mechanochromism can be directly achieved by the deformation-induced changes in periodic lattice constants of the structural-colored materials. [34,35] Recently developed mechanochromic structuralcolored materials have extended the responsive functions from conventional mechanical stimuli to complex signals such as electric stimuli. [10] In addition, although the color shift is a predominant method to achieve mechanochromic behavior, [34-36] increasing efforts have been made to develop mechanochromism based on polarization and transparence. [11,37,38] As one of the rapidly developing intelligent materials with multiresponse, [34,39,40] mechanochromic structural-colored materials have become promising in various applications, such as mechanical sensing, [11,41] colorful displays, [10,42] anti-counterfeiting, [26,37] and healthcare materials. [43,44] In this review, we summarize recent advances in mechanochromic structural-colored materials as shown in Figure 1.

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Spontaneous emission from radiative chiral nematic liquid crystals at the photonic band-gap edge: An investigation into the role of the density of photon states near resonance

Cited by 12 publications

References 14 publications

Efficient Fluorescence Utilization and Photon Density of States‐Driven Design of Liquid Crystal Lasers

Efficient Fluorescence Utilization and Photon Density of States‐Driven Design of Liquid Crystal Lasers

Spontaneous emission in inertial and dissipative nematic liquid crystals: the role of critical phenomena

Mechanochromism of Structural‐Colored Materials

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