Photonic Materials Research Articles

Optical Binding of Metal Nanoparticles Self‐Reinforced by Plasmonic Surface Lattice Resonances

AbstractOptical binding of metal nanoparticles (NPs) provides a promising way to create tunable photonic materials and devices, where the ultrastrong interparticle interaction is generally attributed to the localized surface plasmon resonances of NPs. Here, it is revealed that the optical binding of metal NPs can be self‐reinforced by the plasmonic surface lattice resonances (PSLRs) associated with the discrete NP arrays. Through simulations and experiments, it is demonstrated that PSLRs can spontaneously arise in optically bound gold NP chains with just a few NPs when they are relatively large, e.g., 150 nm in diameter. Additionally, the PSLRs are enhanced by increasing the chain length, leading to stronger optical binding stiffness. These results reveal a previously unidentified factor that contributes to the ultrastrong optical binding of metal NPs. More importantly, this study presents a prospect for building freestanding and reconfigurable NP arrays that naturally support PLSRs for sensing and other applications.

In Situ Ultra-Small- and Small-Angle X-ray Scattering Study of ZnO Nanoparticle Formation and Growth through Chemical Bath Deposition in the Presence of Polyvinylpyrrolidone.

ZnO inverse opals combine the outstanding properties of the semiconductor ZnO with the high surface area of the open-porous framework, making them valuable photonic and catalysis support materials. One route to produce inverse opals is to mineralize the voids of close-packed polymer nanoparticle templates by chemical bath deposition (CBD) using a ZnO precursor solution, followed by template removal. To ensure synthesis control, the formation and growth of ZnO nanoparticles in a precursor solution containing the organic additive polyvinylpyrrolidone (PVP) was investigated by in situ ultra-small- and small-angle X-ray scattering (USAXS/SAXS). Before that, we studied the precursor solution by in-house SAXS at T = 25 °C, revealing the presence of a PVP network with semiflexible chain behavior. Heating the precursor solution to 58 °C or 63 °C initiates the formation of small ZnO nanoparticles that cluster together, as shown by complementary transmission electron microscopy images (TEM) taken after synthesis. The underlying kinetics of this process could be deciphered by quantitatively analyzing the USAXS/SAXS data considering the scattering contributions of particles, clusters, and the PVP network. A nearly quantitative description of both the nucleation and growth period could be achieved using the two-step Finke-Watzky model with slow, continuous nucleation followed by autocatalytic growth.

Harmonic Mode‐Locked Er‐Doped Fiber Laser Based on a Microfiber‐Based PbS Nanoparticle Saturable Absorber

AbstractLead sulfide (PbS) is a nanomaterial with excellent optical and chemical properties, such as a narrow bandgap (0.37 eV), high thermal damage threshold, and high stability. Obviously, it is appropriate as a saturable absorber (SA) device for ultrafast photonics. However, PbS nanoparticles (NPs) as the SA of ultrashort harmonic mode‐locked pulse still haven't been demonstrated at present. In this paper, the PbS NPs are made into an SA‐device‐based microfiber by optical deposition method and connected in an integrated Erbium‐doped fiber laser. And both characteristics and nonlinear optical properties of PbS NPs have been systemically investigated. A fundamental frequency mode‐locked pulsed laser is proposed, whose central wavelength is 1560 nm, and the pulse width is 1 ps. In addition, high repetition rate operations are achieved, with a maximum repetition rate of 833 MHz. This is the first time that PbS NPs are used to generate 96th‐order harmonic mode‐locking, and the corresponding pulse duration is 987 fs. It is demonstrated that PbS NPs are a kind of SA photonic material with excellent performance. It can improve the communication capacity by applying fiber communication, and it has potential application value even in material processing and optical comb.

Design of Photonic Crystal Biosensors for Cancer Cell Detection.

A photonic crystal biosensor is a compact device fabricated from photonic crystal materials, which enables the detection and monitoring of the presence and concentration changes of biological molecules or chemical substances. In this paper, we propose a biosensor for cancer cell detection based on a silicon photonic crystal with a hexagonal resonant cavity introduced in a triangular lattice array. One of the bandgap ranges of this structure is 1188 nm≤λ≤1968 nm. When the incident light wavelength is within the range of 1188 nm≤λ≤1968 nm, the transmission coefficient of this structure at the resonant wavelength of 1469.58 nm is found to reach 99.62% through the finite difference time domain method, with a quality factor of 980. Subsequently, a biosensor is designed from this structure, with its sensing mechanism relying on the change in refractive index leading to a shift in the resonant wavelength. The target sample can be identified by observing the shift in the resonant wavelength. As cancer cells and normal cells possess different refractive indices, this biosensor can be used for their detection. The maximum sensitivity of the sensor is 915.75 nm/RIU and the minimum detection limit is 0.000236 RIU.

Vibrational Exciton and Polaron Nano-imaging: New Functional Nano-Imaging for Molecular Electronic, Photonic, and Photovoltaic Materials.

Vibrational Exciton and Polaron Nano-imaging: New Functional Nano-Imaging for Molecular Electronic, Photonic, and Photovoltaic Materials.

Nonlinear optical effects in natural topaz

We investigate the nonlinear optical properties of natural topaz. For the first time, the observation of nonlinear phenomena related to multiphoton absorption effects, such as the up-conversion luminescence of the material defects, is reported in natural gems. In particular, we were able to detect the presence of the AlO4-related defects which are responsible for the change of the color of topaz as a consequence of irradiation with γ-rays as well as electrons and neutrons beams. Besides, the nonlinear spectral broadening of intense laser beams permits to spot of the presence of rare earth elements, such as Ytterbium and Neodymium, which are not found by means of standard characterization techniques of natural gems, e.g., those based on X-ray fluorescence, electron paramagnetic resonance, and linear optical fluorescence and absorbance measurements. In this sense, our results demonstrate that nonlinear optical effects induced luminescence measurements are a complementary, and previously unforeseen, technique for the characterization of the optical and physicochemical properties of natural gems. Finally, using intense infrared laser pulses allowed us to trigger extreme nonlinear effects, such as multiphoton ionization and conical emission. Our results will be of interest for the investigation of novel nonlinear optical effects in materials that are transparent in the whole visible spectral range and may give insights into the development of materials for nonlinear photonics.

Experimental probe of twist angle-dependent band structure of on-chip optical bilayer photonic crystal.

Recently, twisted bilayer photonic materials have been extensively used for creating and studying photonic tunability through interlayer couplings. While twisted bilayer photonic materials have been experimentally demonstrated in microwave regimes, a robust platform for experimentally measuring optical frequencies has been elusive. Here, we demonstrate the first on-chip optical twisted bilayer photonic crystal with twist angle-tunable dispersion and great simulation-experiment agreement. Our results reveal a highly tunable band structure of twisted bilayer photonic crystals due to moiré scattering. This work opens the door to realizing unconventional twisted bilayer properties and novel applications in optical frequency regimes.

An Angle-Independent Multi-Color Display Electro-Responsive Hydrogel Film.

In nature, some organisms have the ability to camouflage to adapt to environmental changes; they blend with the environment by changing their skin colors. Such a phenomenon is of great significance for the research of adaptive camouflage materials. In this study, we propose a novel design scheme for the study of angle-independent photonic materials and successfully prepare an electrically tunable multi-color display angle-independent inverse opal photonic gel (IOPG). After photopolymerization of hydroxyethyl methacrylate with ionizable monomer acrylic acid (AA) in a long-range disordered opal template and etching, the angle-independent inverse opal photonic gel is obtained, presenting a single structural color. The electrically responsive color changes can be achieved at different angles. The color of the disordered AA-IOPG changes from green to blue-green when applying +4 V bias voltage and from green to orange when applying -4 V bias voltage. The electrochromism of the disordered AA-IOPG is mainly due to the local pH change caused by water electrolysis under bias voltage, which leads to a change of the swelling ratio. The disordered AA-IOPG shows high color tunability and durability through repeated opposite bias voltage tests, indicating that it is a promising conductive photonic material.

Investigation of europium oxide (Eu2O3) doped in cobalt boro-silicate glasses from waste glass for photonics material application

The boro-silicate glasses have been doped with different concentration of Eu2O3 keeping constant CoO concentration (0.02 mol%) and synthesized in melt quench technique, these glasses are characterized through physical parameters, optical absorption, photo, and X-ray luminescence spectroscopy. The results showed that the optical characteristics of the samples are dependent on the Eu2O3 content rather than CoO content inside the glass. We observe tetrahedral dominance of Co2+ in the present glass system. The absorption spectra showed the three broad band of Co2+ ion at 4T1 g(F) → 2T1 g, 4A2 (4F) → 1T1 (4P), and 5T2 g → 5Eg respectively. Using optical absorption spectra, the crystal field parameter (10Dq), Racah parameter (B) were evaluated for all the concentration of Eu3+ doped glass. The phonon side band spectrum shows 1067.98 cm−1 for the present glass system. The integral scintillating efficiency have been studied and exhibited that the value show 8.78 % compared with commercial BGO scintillating crystal. Judd-Ofelt intensity parameters were investigated and used to compute the radiative properties of present glasses. These studies are useful for optimizing glass composition and could be useful for the optical display devices.

Optical Characteristics of Stretchable Chiral Liquid Crystal Elastomer under Multiaxial Stretching

AbstractChiral liquid crystal elastomers (CLCEs) are soft photonic materials that exhibit both the photonic characteristics of nanoscale periodic helical structures and mechanical properties of rubber. Owing to its elasticity, the structural color of CLCEs can be tuned through mechanical deformations known as mechanochromism. Thus far, there is significant research attention to exploring the mechanochromism of CLCEs. However, most studies have only discussed the color shifting of CLCEs under uniaxial deformation. Therefore, the optical and chiral structural deformation behaviors of CLCEs under multiaxial stress are not well understood. This study investigates multiaxial (uniaxial, biaxial, and out‐of‐plane) stretching‐induced helical structure change and the resulting optical properties of CLCEs. The results confirm that uniaxial stretching leads to a loss of intrinsic circular polarization selectivity in CLCEs due to helix unwinding deformations, while biaxial and out‐of‐plane stretching maintain circular polarization.

Chalcogenide Chip-Based Frequency Combs for Advanced Laser Spectroscopy

Optical frequency combs have revolutionized spectral measurement technologies, such as dual-comb spectrometers, for fast and accurate spectroscopic measurements over broad spectral ranges. Moreover, chip-scale frequency combs based on microresonators are revolutionizing laser spectroscopy due to their compact size, low cost, and low power consumption, which offer a promising solution for integrated optical sensing applications by replacing costly bulk optical sensing components. Developing new attractive photonic materials for integrated microcomb is critical to realizing chip-based microcombs with high efficiency, broad bandwidth, and low pumping power. In this tutorial, we present novel chalcogenide chip-based microcombs for broadband laser spectroscopy. The integrated chalcogenide microresonators on silicon wafers are achieved using a home-developed chalcogenide glass (Ge <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">25</sub> Sb <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">10</sub> S <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">65</sub> ) with ultra-wide transmittance window, high Kerr nonlinearity, and low thermo-optic coefficient. Two fabrication processes of high quality-factor integrated chalcogenide microresonators with different core-cladding structures operating in the telecom and mid-infrared (MIR) regions, respectively, are introduced. Combined high nonlinearity with lithographically controlled flexible dispersion engineering of the chalcogenide microresonators, we have realized the versatile Kerr microcombs generation and physical mechanism, including bright soliton microcomb, dark-pulse microcomb, Raman-Kerr microcomb, broadband Kerr microcomb and the future opportunity of the MIR Kerr comb. In addition, we review the most potent examples of dual-comb spectroscopy applications for molecular characterization and laser ranging with ultra-high sensitivity and high accuracy and discuss the challenges of realizing MIR microcombs with high performance and ultracompact footprint for laser spectroscopy.

Cross-Sectional Investigations of Spherical Colloidal Clusters from Submicrometer-Sized Silica Particles toward Designing Novel Photonic Materials

Cross-Sectional Investigations of Spherical Colloidal Clusters from Submicrometer-Sized Silica Particles toward Designing Novel Photonic Materials

Optical mid-infrared modulator based on D-shaped photonic crystal fiber and GST phase changing material

Photonic crystal fibers (PCFs) have recently attracted compelling attention because of their numerous applications, particularly in the mid-infrared (mid-IR) wavelength region. In this paper, we have presented and analyzed mid-IR optical modulator based on phase-changing material (PCM) known as germanium-antimony-tellurium (GST) and D-shaped PCF. The modulation process can be performed as the GST material’s phase undergoes a transition between amorphous (on) and crystalline (off) states. To analyze the proposed design numerically, full vectorial finite element method (FVFEM) is employed. Further, we studied the light propagation through the suggested structure using 3D finite difference time domain (FDTD) method. The optical losses of the fundamental transverse electric (TE) mode supported by the reported structure in the two GST states are studied. The obtained extinction ratio (ER) of the proposed modulator approaches 302.61 dB, whereas the insertion loss (IL) is less than 0.00014 dB throughout the wavelength range from 3 to 5.8 μm at a device length (LD) of 0.2 mm. Therefore, the suggested modulator can be utilized in photonic integrated circuits that require high ER, very low IL, and large optical bandwidth.

New Glasses in the PbCl2–PbO–B2O3 System: Structure and Optical Properties

New oxychloride lead borate glasses in the xPbCl2–(50-0.5x)PbO–(50-0.5x)B2O3 system were synthesized with a maximum lead chloride content of 40 mol%. The characteristic temperatures and mechanical and optical properties were studied. The incorporation of lead chloride led to a significant expansion of the transparency range in the UV (up to 355 nm) and IR regions (up to 4710 nm). Decreases in the Vickers hardness, density, and glass transition temperature were the consequences of a change in the structure. The studied glasses are promising materials for photonics and IR optics. The structure of the PbCl2–PbO–B2O3 system was analyzed in detail using vibrational spectroscopy and X-ray diffraction.

Refractive Properties of Conjugated Organic Materials Doped with Fullerenes and Other Carbon-Based Nano-Objects.

Due to the high demand for optoelectronics for use in new materials and processes, as well as the search for their modeling properties, the expansion of the functionality of modified materials using nanotechnology methods is relevant and timely. In the current paper, a specific nanotechnology approach is shown to increase the refractive and photoconductive parameters of the organic conjugated materials. The sensitization process, along with laser treatment, are presented in order to improve the basic physical-chemical properties of laser, solar energy, and general photonics materials. Effective nanoparticles, such as fullerenes, shungites, reduced graphene oxides, carbon nanotubes, etc., are used in order to obtain the bathochromic shift, increase the laser-induced change in the refractive index, and amplify the charge carrier mobility of the model matrix organics sensitized with these nanoparticles. The four-wave mixing technique is applied to test the main refractive characteristics of the studied materials. Volt-current measurements are used to estimate the increased charge carrier mobility. The areas of application for the modified nanostructured plastic matrixes are discussed and extended, while also taking into account the surface relief.

Mimicking Natural-Colored Photonic Structures with Cellulose-Based Materials

Structural coloration has become a fascinating field of research, inspiring scientists and engineers to explore the vibrant colors observed in nature and develop bio-inspired photonic structures for various applications. Cellulose-based materials derived from plant fibers offer a promising platform for mimicking natural photonic structures. Their abundance, renewability, and versatility in form and structure make them ideal for engineering specific optical properties. Self-assembly techniques enable the creation of ordered, periodic structures at the nanoscale by manipulating the interactions between cellulose fibers through chemical modification or physical manipulation. Alternatively, additive manufacturing techniques like 3D printing and nanoimprint lithography can directly fabricate desired structures. By em-ulating natural photonic structures, cellulose-based materials hold immense potential for applications such as colorimetric sensors, optoelectronic devices, camouflage, and decorative materials. However, further research is needed to fully com-prehend and control their optical properties, as well as develop cost-effective and scalable manufacturing processes. This article presents a comprehensive review of the fundaments behind natural structural colors exhibited by living organisms and their bio-inspired artificial counterparts. Emphasis is placed on understanding the underlying mechanisms, strategies for tunability, and potential applications of these photonic nanostructures, with special focus on the utilization of cellulose nanocrystals (CNCs) for fabricating photonic materials with visible structural color. The challenges and future prospects of these materials are also discussed, highlighting the potential for advancements to unlock the full potential of cellulose-based materials with structural color.

Annealing effect on the morphology, linear and non-linear optical properties of squaraine derivative thin films for optoelectronics applications

Squaraine is a class of organic compounds that possess unique optical properties, including strong absorption of light, high fluorescence quantum yields, etc. Here, we explore the structural and spectroscopic investigations of 2,4-Bis[4-(N,N-dibenzylamino)-2,6 dihydroxyphenyl] squaraine dye (SQ) under different conditions of thermal effects. The molar absorptivity (εmolar) spectra were used to describe the electric dipole strength (q2) and the oscillator strengths (f) of SQ dye. The Surface morphology of SQ dye was investigated by AFM and the average roughness shows dependence on the annealing effect. A slight change in the optical energy gap (⁓ 0.3 eV) after annealing up to 473 K reflects the optical stability of our investigated thin films. The optical band transitions and photoluminescence (PL) emission spectra were described before and after annealing at 423 & 473 K. As the temperature annealing film increased to 473 K, the nonlinear parameters such as χ(3) and n2 decreased by about 44% and 36%, respectively. The good thermal stability, suitable optical band gap, and refractive index offer potential applications as active photonic materials in photonic/optoelectronic applications.

Semiconductor-on-diamond cavities for spin optomechanics.

Optomechanical cavities are powerful tools for classical and quantum information processing that can be realized using nanophotonic structures that co-localize optical and mechanical resonances. Typically, phononic localization requires suspended devices that forbid vertical leakage of mechanical energy. Achieving this in some promising quantum photonic materials such as diamond requires non-standard nanofabrication techniques, while hindering integration with other components and exacerbating heating related challenges. As an alternative, we have developed a semiconductor-on-diamond platform that co-localizes phononic and photonic modes without requiring undercutting. We have designed an optomechanical crystal cavity that combines high optomechanical coupling with low dissipation, and we show that this platform will enable optomechanical coupling to spin qubits in the diamond substrate. These properties demonstrate the promise of this platform for realizing quantum information processing devices based on spin, phonon, and photon interactions.

Inorganic Chemistry in Dalian University of Technology: Fundamental Science and Solution for Renewable Energy, Environment, Health, and Materials

This Institute Feature “Dalian University of Technology” is a special collection of research articles and reviews on the inorganic chemistry in Dalian University of Technology. The Dean of the School of Chemical Engineering Xinwen Guo and the Guest Editor Jianzhang Zhao briefly introduce Dalian University of Technology and showcase the excellent research in this collection. Dalian University of Technology (DUT) was founded in 1949. It is a national key university directly administrated by the Ministry of Education of China and sponsored by Project 211 and Project 985. It has formed a multi-disciplinary system that focuses on science and engineering, as well as economics, management, humanities, law, philosophy, and arts. The university has 27 schools and more than 2992 faculty members, including 15 Chinese academicians. The university is actively involved in promoting the “One Belt, One Road” education initiative and building a community of shared future for human beings’ development. At present, the university has established three Sino-foreign cooperative institutions with Ritsumeikan University, Leicester University, and Belarusian State University, and one Sino-foreign cooperative program with University of California, Irvine. The university actively fosters over 150 overseas exchange programs. In recent years, nearly 3,000 students studied overseas each year; more than 700 overseas experts and scholars have been invited to DUT for long/short-term visits each year. Up to 2021, the university has enrolled 1,077 international students. DUT has joined 21 international organizations and alliances in higher education, including the Sino-EU Engineering Education Platform, Association of Sino-Russian Technical Universities, University Alliance of Belt & Road, Shanghai Cooperation Organization University, China-Central Eastern European Countries Higher Education Institutions Consortium, and ASEAN-China Network for Cooperation and Exchange among Engineering and Technology Universities. The School of Chemical Engineering of DUT was found in 1949. Nowadays there are nine departments in the school, including chemical engineering, material engineering, applied catalysis, chemical engineering processing, pharmaceutical engineering, and fine chemicals, etc. with 256 faculties in total. The school has strong collaborations with several world-renowned universities and institutes. In this Institute Feature, the review article by Li et al. focuses on the stereoselective polymerization catalysts for aromatic polar vinyl monomers, which gives a detailed analysis of the effect of the molecular structure of the catalysts and solvents on the activity and stereoselectivity of the polymerization reaction. In another review article, Wu et al. summarized the recent development in preparing nanospheres for the application of photonic materials in areas of coloring, sensors, luminescence, and surface-enhanced Raman scattering. Zhao et al. reported the preparation of efficient catalysts for the hydrodeoxygenation of methyl palmitate to produce biodiesel. Guo et al. reported new CuBTC materials with hierarchical pore structures for efficient separation of CO2/CH4, which has potential applications in industry. Zhu et al. reported the synthesis of sheet-like ZSN-5 zeolites with an ethanol modulator. The obtained sheet-like ZSM-5 showed better catalytic performance than its conventional counterpart in the alkylation of benzene with ethanol. Yu et al. reported the preparation of a series of supported metal sulfate catalysts FexZny/SiO2, which was efficient for isobutene dimerization but inert for other olefins in the C4 mixture (a valuable petroleum processing by-product). The catalysts were useful for the rational utilization of mixed C4 and further production of isooctane with a high-octane number to replace methyltert-butylether (MTBE) in gasoline. Gao et al. prepared an amorphous Ti/SiO2 catalyst by grafting amorphous SiO2 with TiCl4 in ethanol solvent in a chemical liquid-phase deposition process, which showed high catalytic activity for gas-phase epoxidation of propylene. Xiong et al. reported the preparation of Y/ZSM-5 composite zeolites by an aerosol-assisted hydrothermal method involving two-step crystallization. The application of catalytic 1,3,5-triisopropylbenzene cracking for the selective production of benzene was studied. Ge et al. reported a facile assembly-within-foam strategy to prepare a nanodiamond/carbon nanotube hybrid monolithic carbocatalyst for direct dehydrogenation of ethylbenzene to styrene. Suo et al. reported a method for preparing well-confined Ni nanoparticles (NPs) by precisely adjusting the reduction temperature of nickel-containing phyllosilicates (PSi) materials to obtain [email protected] catalysts. The materials were used as catalysts for the steam reforming of methane. It was found the material was not only endowed with the highest reaction rate for steam reforming of methane (SRM) but also kept high stability under harsh reaction conditions. Feng et al. reported calcium coordination polymers showing multi-stimuli-responsive properties, such as mechanochromic luminescence and selective detection of halogenated hydrocarbons or trace water in DMF. Meng et al. prepared an organic dye-conjugated Eu(III) complex as a luminescent probe for the discrimination and detection of biothiols (GSH and Cys/Hcy.), which allowed time-gated and steady-state luminescence modes to be combined for detecting total biothiols and discriminating GSH and Cys/Hcy. In another VIP paper, Kong et al. reported a unique Eu3+−Tb3+-complex-mixed probe for ratiometric time-gated luminescence detection of H2S. The probe showed prominent Golgi apparatus-targeting ability, selective detection of H2S in aqueous media and Golgi apparatus of living cells was successfully achieved. Ye et al. prepared a N^N Pt(II) bisacetylide complex using perylenemonoimide acetylide ligand. The complex was used as a triplet photosensitizer to generate delayed fluorescence with perylenebisimide (PBI) as the triplet state energy acceptor and emitter, via the intermolecular triplet-triplet energy transfer (TTET) and triplet-triplet annihilation (TTA), the delayed fluorescence lifetime is up to 52.5 μs under the experimental conditions. Zhao et al. reported the pyrolysis of NiFe-containing nanocrystals, which lead to the formation of NiFe alloy particles embedded in carbon with an exceptionally high area specific exchange current density toward the alkaline hydrogen oxidation reaction (HOR). Yan et al. reported that the addition of formic acid as a modulator led to the formation of MOF-801 membrane with a higher missing-linker number, which was beneficial for increasing water flux with little compromise in dye rejection rate, thus holding great promise for application in wastewater treatment. Wang et al. prepared porous α-Al2O3-supported short-chain bis(triethoxysilyl)methane (BTESM)-based hybrid-silica membranes as potential candidates for application in desalination. Wu et al. used first-principle-based thermodynamic calculation to study CO adsorption in atomic catalysts. Wang et al. prepared a non-enzymatic glucose biosensor based on nanostructured CuxO/Cu electrodes. He et al. employed the strategy of generating catalytic species from in situ reduction of divalent cobalt(II) salt for selective carbonylative ring expansion of epoxides under extremely mild conditions. β-Lactones with excellent functionality were moderately isolated to achieve excellent yields and selectivity. Wu et al. prepared homochiral Ir(III)-metallohelix-based porous molecular crystal, and the polymorph by single-crystal-to-single-crystal (SCSC) transformations was studied. The authors found that the β-polymorph could be effectively obtained through SCSC transformation from α-polymorph in solid state using isopropanol as a trigger. Compared with the α-polymorph, the obtained β-polymorph porous molecular crystal displayed higher CO2 uptake and better selectivity for CO2 over N2 at 298 K. Both β-polymorph and α-polymorph exhibited similar enantioselective separation capacity towards alcohols but different adsorption kinetics. Feng et al. reported the gram-scale synthesis of a novel unsymmetric β-diketiminate ligand containing a thioether tether, which served as not only a bio-mimicking functional platform but also excellent cooperative catalysts. We are grateful to the editorial office of Eur. J. Inorg. Chem for offering this showcase. We are grateful to all the authors for their great enthusiasm for the support of this Institute Feature, especially Prof. Yi Liu for their great effort. We would like to thank all the reviewers for their critical comments. We believe that inorganic chemistry research at Dalian University of Technology will continue flourishing. Moreover, through collaboration with chemists all over the world, we can find better solutions for addressing global concerns. The opinions expressed in this publication are the view of the author and do not necessarily reflect the opinions or views of the European Journal of Inorganic Chemistry, the Publisher, Chemistry Europe, or the affiliated editors. Xinwen Guo is a Professor at Dalian University of Technology. He received Ph.D. degree from Dalian University of Technology (DUT) in 1994. Then, he joined DUT as a lecturer. He was promoted to full professor in 2001. From 2001 to 2002, he was a visiting scholar at Penn State University. His research focuses on zeolite synthesis, MOF synthesis, shape-selective catalysis, selective oxidation, and the catalytic conversion of CO2. He has published more than 500 papers on peer-reviewed journals, with 13,000 citations and H-index of 62. He is the member of the International Advisory Board of the journal Chin J of Catal. and the Specialty Chief Editor of Frontiers in Chemical Engineering (Catalytic Engineering). Jianzhang Zhao is a Professor at Dalian University of Technology. He received a Ph.D. degree at Jilin University in 2000. After postdoctoral research at Pohang University of Science and Technology (South Korea), Max Planck Research Unit of Enzymology of Protein Folding (Germany), and University of Bath (U.K.), he took up the current position at Dalian University of Technology in 2005. His research interests are synthesis of functional organic and inorganic compounds, and study of the charge, energy, spin transport by transient optical spectroscopic methods and pulsed laser excited time-resolved electron paramagnetic resonance spectroscopy. He is also interested in the application of photochemistry in industry. He has published more than 300 papers in peer-reviewed journals, with 17,000 citations and an H-index of 78. He is a member of the International Advisory Board of Eur. J. Inorg. Chem.

Mechanochromic and Conductive Chiral Nematic Nanostructured Film for Bioinspired Ionic Skins.

Chameleon skin is naturally adaptive and can sense environmental changes and transform sensing into bioelectrical and optical signals by manipulating ion transduction and photonic nanostructures. The increasing interest in mimicking biological skins has considerably promoted the development of advanced photonic materials with an increasing ionic conductivity. Herein, we report the judicious design and fabrication of a bioinspired mechanochromic chiral nematic nanostructured film with good ionic conductivity by infiltrating fluorine-rich ionic liquids (FILs) into a swollen self-assembled cellulose nanocrystal (CNC) film with helical nanoarchitectures. Notably, the introduction of 2-hydroxyethyl acrylate considerably enhances the compatibility of hydrophobic FILs and hydrophilic CNCs. The resulting FIL-CNC nanostructured films exhibited excellent mechanochromism, good ionic conductivity, and outstanding optical/electrical dual-signal sensing performance when used as a bioinspired ionic skin for real-time monitoring of human motions. Owing to the integration of FILs, the underwater stability of the chiral liquid crystal nanostructures of CNCs was significantly enhanced. Notably, underwater contact/contactless sensing modes and encrypted information transmission have been achieved with the FIL-CNC nanostructured film. This study can offer great insights for the advancement of biomimetic multifunctional artificial skins and emerging interactive devices, which can find important applications in wearable iontronics, human-machine interactions, and intelligent robots.