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Electrospun Polymer Nanofibers for Food and Health Applications

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ISBN: 9783039281923 9783039281930 Year: Pages: 74 DOI: 10.3390/books978-3-03928-193-0 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Technology (General)
Added to DOAB on : 2020-04-07 23:07:08
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The electrospinning method has the unique ability to produce structured polymeric fibers on the micro or nano scale and to generate novel materials for food and healthcare purposes. The potential of electrospun nanofibers for human healthcare applications is promising, for example, in tissue/organ repair and regeneration, in medical diagnostics and instrumentation, and as vectors to deliver drugs and therapeutics, as biocompatible and biodegradable medical implant devices, as protective fabrics against environmental and infectious agents in hospitals and general surroundings. Furthermore, considerable effort has been directed toward developing scaffolds using biodegradable and biocompatible synthetic, natural polymers or renewable materials that enhance in vitro cell growth, while killing pathogenic bacteria cells. This Special Issue ""Electrospun Polymer Nanofibers for Food and Health Applications” will cover the latest research of electrospun nanofibres in this field including shape-memory electrospun fibre meshes with programmable cell orientation, water-absorbing nano?ber meshes for e?cient removal of excess water from kidney failure patients, and hydrogel nano?bers which can be used as a drug carrier for methylene blue.

Electrospun Nanofibers for Biomedical Applications

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ISBN: 9783039287741 / 9783039287758 Year: Pages: 308 DOI: 10.3390/books978-3-03928-775-8 Language: eng
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Technology (General)
Added to DOAB on : 2020-06-09 16:38:57
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Electrospinning is a versatile and effective technique widely used to manufacture nanofibrous structures from a diversity of materials (synthetic, natural or inorganic). The electrospun nanofibrous meshes’ composition, morphology, porosity, and surface functionality support the development of advanced solutions for many biomedical applications. The Special Issue on “Electrospun Nanofibers for Biomedical Applications” assembles a set of original and highly-innovative contributions showcasing advanced devices and therapies based on or involving electrospun meshes. It comprises 13 original research papers covering topics that span from biomaterial scaffolds’ structure and functionalization, nanocomposites, antibacterial nanofibrous systems, wound dressings, monitoring devices, electrical stimulation, bone tissue engineering to first-in-human clinical trials. This publication also includes four review papers focused on drug delivery and tissue engineering applications.

Keywords

sol-gel --- electrospinning --- hydroxyapatite --- nanofiber --- antibacterial --- titanium --- antibacterial coatings --- electrospinning --- nanocomposite coatings --- TiO2 photocatalytic --- orthopedic infections --- electrospinning --- 3D printing --- nanofibers --- encapsulation --- protein diffusion --- in vivo tissue engineering --- immuno-isolation --- transplantation --- electrospinning --- sputtering --- drug delivery --- wound dressing --- biocompatibility --- tissue engineering --- biomimetic scaffolds --- gelatin --- electrospinning --- micromolding --- biomaterials --- poly(lactic acid) (PLLA) --- bioactive glass --- scaffolds --- electrospinning --- composite fibres --- bone regeneration --- poly(vinylidene fluoride) --- composite nanofiber --- piezoelectricity --- antioxidant activity --- well-aligned nanofibers --- P(VDF-TrFE) --- piezoelectric nanogenerator --- preosteoblasts electrospinning --- silicone modified polyurethane nanofibers --- physical properties --- cell attachment --- cell proliferation --- cytotoxicity --- biopolymers --- packaging --- pharmaceutical --- biomedical --- electrospinning --- alginate --- gelatin fibers --- ZnO particles --- antibacterial activity --- electrospinning --- nanofibers --- fabrication --- therapeutics --- biomedical applications --- antibody immobilization --- electrospun nanofibers --- TNF-? capture --- human articular chondrocytes --- rheumatoid arthritis --- nanofibers --- microfluidic chip --- electrospinning --- live assay --- hepatocellular carcinoma cells --- PLA95 --- biocompatibility --- guided tissue regeneration (GTR) --- electrospinning --- electrospun fiber mats --- mechanobiology --- glioblastoma --- biomaterials --- finite element modeling --- electrospun nanofibers --- cancer treatment --- drug release --- nanomedicine --- biocompatible polymers --- hyperthermia

Micro/Nano Materials for Clean Energy and Environment

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ISBN: 9783039211289 9783039211296 Year: Pages: 123 DOI: 10.3390/books978-3-03921-129-6 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Technology (General) --- General and Civil Engineering
Added to DOAB on : 2019-08-28 11:41:30
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The Tsinghua University–University of Waterloo Joint Research Center for Micro/Nano Energy & Environment Technology (JCMEET) is a platform. It was established on Nov.11, 2017. The Chairperson of University Council of Tsinghua University, Dr. Xu Chen, and the President of the University of Waterloo, Dr. Feridun Hamdullahpur, attended the opening ceremony and unveiled the nameplate for the joint research center on 29th of March, 2018. The research center serves as a platform for researchers at both universities to conduct joint research in the targeted areas, and to meet regularly for information exchange, talent exchange, and knowledge mobilization, especially in the fields of micro/nano, energy, and environmental technologies. The center focuses on three main interests: micro/nano energy technology, micro/nano pollution control technology, and relevant fundamental research. In order to celebrate the first anniversary of the Joint Research Center, we were invited to serve as the Guest Editors of this Special Issue of Materials focusing on the topic of micro/nano-materials for clean energy and environment. It collects research papers from a broad range of topics related to micro/nanostructured materials aimed at future energy resources, low emission energy conversion, energy storage, energy efficiency improvement, air emission control, air monitoring, air cleaning, and many other related applications. This Special Issue provides an opportunity and example for the international community to discuss how to actively address the energy and environment issues that we are facing.

Recent Development of Electrospinning for Drug Delivery

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ISBN: 9783039281404 9783039281411 Year: Pages: 206 DOI: 10.3390/books978-3-03928-141-1 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Medicine (General) --- Therapeutics
Added to DOAB on : 2020-04-07 23:07:09
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Several promising techniques have been developed to overcome the poor solubility and/or membrane permeability properties of new drug candidates, including different fiber formation methods. Electrospinning is one of the most commonly used spinning techniques for fiber formation, induced by the high voltage applied to the drug-loaded solution. With modifying the characteristics of the solution and the spinning parameters, the functionality-related properties of the formulated fibers can be finely tuned. The fiber properties (i.e., high specific surface area, porosity, and the possibility of controlling the crystalline–amorphous phase transitions of the loaded drugs) enable the improved rate and extent of solubility, causing a rapid onset of absorption. However, the enhanced molecular mobility of the amorphous drugs embedded into the fibers is also responsible for their physical–chemical instability. This Special Issue will address new developments in the area of electrospun nanofibers for drug delivery and wound healing applications, covering recent advantages and future directions in electrospun fiber formulations and scalability. Moreover, it serves to highlight and capture the contemporary progress in electrospinning techniques, with particular attention to the industrial feasibility of developing pharmaceutical dosage forms. All aspects of small molecule or biologics-loaded fibrous dosage forms, focusing on the processability, structures and functions, and stability issues, are included.

Keywords

electrospinning --- gentamicin sulfate --- polylactide-co-polycaprolactone --- drug release kinetics --- tissue engineering --- growth factor --- diabetic --- wound healing --- nanocomposite --- electrospinning --- coaxial spinning --- core-sheath nanofibers --- biomedical --- drug delivery --- electrospinning --- scale-up --- processability --- biopharmaceuticals --- oral dosage form --- grinding --- aceclofenac --- nanofiber --- electrospinning --- scanning electron microscopy --- fourier transform infrared spectroscopy --- differential scanning calorimetry --- nanotechnology --- biotechnology --- probiotics --- Lactobacillus --- Lactococcus --- electrospinning --- nanofibers --- drying --- local delivery --- viability --- antibacterial activity --- bacterial bioreporters --- drug release --- electrospinning --- microfibers --- nanofibers --- UV imaging --- wetting --- in situ drug release --- nanofibers --- electrospinning --- poorly water-soluble drug --- piroxicam --- hydroxypropyl methyl cellulose --- polydextrose --- scanning white light interferometry --- nanotechnology --- nanofibers --- traditional electrospinning --- ultrasound-enhanced electrospinning --- drug delivery system --- haemanthamine --- plant-origin alkaloid --- electrospinning --- amphiphilic nanofibers --- self-assembled liposomes --- physical solid-state properties --- drug release --- electrospinning --- PCL --- gelatin --- clove essential oil --- antibacterial --- biocompatibility --- artificial red blood cells --- electrospinning and electrospray --- pectin --- oligochitosan --- hydrogel --- microcapsules --- electrospinning --- wound dressings --- solvent casting --- 3D printing --- polymeric carrier --- n/a

Advances in Electrochemical Energy Materials

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ISBN: 9783039286423 / 9783039286430 Year: Pages: 156 DOI: 10.3390/books978-3-03928-643-0 Language: eng
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Physics (General)
Added to DOAB on : 2020-06-09 16:38:57
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Electrochemical energy storage is becoming essential for portable electronics, electrified transportation, integration of intermittent renewable energy into grids, and many other energy and power applications. The electrode materials and their structures, in addition to the electrolytes, play key roles in supporting a multitude of coupled physicochemical processes that include electronic, ionic, and diffusive transport in electrode and electrolyte phases, electrochemical reactions and material phase changes, as well as mechanical and thermal stresses, thus determining the storage energy density and power density, conversion efficiency, performance lifetime, and system cost and safety. Different material chemistries and multiscale porous structures are being investigated for high performance and low cost. The aim of this Special Issue is to report the recent advances in materials used in electrochemical energy storage that encompass supercapacitors and rechargeable batteries.

Polymeric Foams

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ISBN: 9783039216321 9783039216338 Year: Pages: 322 DOI: 10.3390/books978-3-03921-633-8 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Technology (General) --- Chemical Engineering
Added to DOAB on : 2019-12-09 11:49:16
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Advances in nanotechnology have boosted the development of more efficient materials, with emerging sectors (electronics, energy, aerospace, etc.) demanding novel materials to fulfill the complex technical requirements of their products. This is the case of polymeric foams, which may display good structural properties alongside functional characteristics through a complex composition and (micro)structure in which a gas phase is combined with rigid ones, mainly based on nanoparticles, dispersed throughout the polymer matrix. In recent years, there has been an important impulse in the development of nanocomposite foams, extending the concept of nanocomposites to the field of cellular materials. This, alongside developments in new advanced foaming technologies which have allowed the generation of foams with micro, sub-micro, and even nanocellular structures, has extended the applications of more traditional foams in terms of weight reduction, damping, and thermal and/or acoustic insulation to novel possibilities, such as electromagnetic interference (EMI) shielding. This Special Issue, which consists of a total of 22 articles, including one review article written by research groups of experts in the field, considers recent research on novel polymer-based foams in all their aspects: design, composition, processing and fabrication, microstructure, characterization and analysis, applications and service behavior, recycling and reuse, etc.

Keywords

grey relational analysis --- multi-objective particle swarm optimization --- acoustic performances --- Ethylene Propylene Diene Monomer --- polyurethane foam composites --- DOPO --- itaconic acid --- ethyl cellulose --- phenolic foams --- composites --- adjacent façade --- PUR --- energy conservation --- heat transfer --- burning characteristic --- semi-rigid polyurethane foams --- aluminum microfibers --- quasi-static compression tests --- mechanical properties --- energy absorption capability --- foams --- polyamide --- crystalline --- thermal conductivity --- mechanical property --- functional --- biomaterials --- composites --- EMI --- cellulose foam --- polypropylene --- foaming quality --- impact property --- intrinsic toughness --- flame-retardant ABS microcellular foams --- phosphorus flame retardants --- MuCell® injection-molding foaming --- graphene oxide --- rigid polyurethane foam --- thermogravimetric analysis --- activation energies --- extrusion foaming --- super critical CO2 --- lignin --- sound absorption coefficient --- mechanical property --- Pluronic --- surfactants --- foams --- SANS --- multilayers --- epoxy composite foam adhesive --- core–shell rubber --- impact wedge–peel test --- automobile structural adhesives --- flame retardancy --- foams --- phosphorus --- ternary synergistic effect --- polypropylene --- fluoelastomer --- scCO2 foaming --- heterogeneous nucleation --- polypropylene --- cellulose nanofiber --- foam injection molding --- mechanical properties --- polystyrene foams --- 1,3,5-benzene-trisamides --- cell nucleation --- foam extrusion --- foam morphology --- supramolecular additives --- thermal insulation --- compression properties --- piezoelectric --- functional foam --- piezocomposite --- PZT --- expandable microspheres --- permittivity --- polyetherimide foams --- graphene --- multifunctional foams --- ultrasonication --- scCO2 --- electrical conductivity --- polymer waste --- polyurethane foam --- leaching test --- microstructure --- absorbent PMI foam --- metallic tube --- electromagnetic wave absorption --- mechanical properties --- failure mechanism --- polymers --- foams --- shock compression --- equation of state --- epoxy --- foams --- expandable microspheres --- graphene --- nanotubes --- conductivity --- syntactic foams --- n/a

Novel Smart Textiles

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ISBN: 9783039285709 / 9783039285716 Year: Pages: 230 DOI: 10.3390/books978-3-03928-571-6 Language: eng
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Arts in general
Added to DOAB on : 2020-06-09 16:38:57
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The sensing, adapting, responding, multifunctionality, low energy, small size and weight, ease of forming, and low-cost attributes of smart textiles and their multidisciplinary scope offer numerous end uses in medical, sports and fitness, military, fashion, automotive, aerospace, the built environment, and energy industries. The research and development on these new and high-value materials cross scientific boundaries, redefine material science design and engineering, and enhance quality of life and our environment. “Novel Smart Textiles” is a focused Special Issue that reports the latest research of this field and facilitates dissemination, networking, discussion, and debate.

Keywords

e-textile --- metamaterials --- transmission line --- wearable --- split ring resonator --- dye-sensitized solar cell (DSSC) --- polyacrylonitrile (PAN) --- nanofiber mat --- electrospinning --- PEDOT:PSS --- dye-sensitized solar cell --- half-textile --- spectral analysis --- parameter identification --- equivalent circuit --- black-box --- grey-box --- power spectral density --- optimization --- analytical model --- electromagnetic shielding effectiveness --- electric properties --- fabric --- woven textiles --- carbon nanomaterials --- smart fabrics --- in-line monitoring --- polymeric composites --- carbon nanotubes --- reduced graphene oxide --- textile electrode --- ECG --- motion sensor --- skin-electrode impedance --- electrically conductive textiles --- polymers --- smart textiles --- surface area evaluation --- microencapsulation --- biofunctional --- drug-delivery --- textile-based stretch sensors --- stitch structure --- wearable stretch sensor --- conductive thread --- conductivity --- metal flake --- coating --- e-textile --- encapsulation --- durability --- stiffness --- textile/polymer composite --- stretchable electronics --- smart textiles --- mechanical and electrical properties --- quasi-static and cyclic mechanical loading --- life-time expectancy --- smart textile --- thermal textile pixel --- thermal communication --- non-auditory and nonvisual communication --- thermal conductivity --- Peltier element --- SMART pattern-changing fabric --- pattern effect --- visual response --- visual brain --- event-related potential (ERP) --- psychotextiles --- art and design --- smart textiles --- textile sensors --- e-textiles --- visual brain --- thermal textile pixels --- stretchable electronics --- conductive textiles --- wearables --- stitch-based sensors --- biofunctional textiles --- ECG --- hybrid electrodes --- motion tracking --- carbon nanotextiles --- composites --- EMS textiles --- electrospun solar cells --- embroidered e-textiles --- targeted delivery --- psychotextiles --- energy harvesting --- multifunctional

Electrochemical Surface Science: Basics and Applications

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ISBN: 9783039216420 9783039216437 Year: Pages: 398 DOI: 10.3390/books978-3-03921-643-7 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Chemistry (General) --- Inorganic Chemistry
Added to DOAB on : 2019-12-09 11:49:15
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Electrochemical surface science (EC-SS) is the natural advancement of traditional surface science (where gas–vacuum/solid interfaces are studied) to liquid (solution)/electrified solid interfaces. Such a merging between two different disciplines—i.e., surface science (SS) and electrochemistry—officially advanced ca. three decades ago. The main characteristic of EC-SS versus electrochemistry is the reductionist approach undertaken, inherited from SS and aiming to understand the microscopic processes occurring at electrodes on the atomic level. A few of the exemplary keystone tools of EC-SS include EC-scanning probe microscopies, operando and in situ spectroscopies and electron microscopies, and differential EC mass spectrometry (DEMS). EC-SS indirectly (and often unconsciously) receives a great boost from the requirement for rational design of energy conversion and storage devices for the next generation of energetic landscapes. As a matter of fact, the number of material science groups deeply involved in such a challenging field has tremendously expanded and, within such a panorama, EC and SS investigations are intimately combined in a huge number of papers. The aim of this Special Issue is to offer an open access forum where researchers in the field of electrochemistry, surface science, and materials science could outline the great advances that can be reached by exploiting EC-SS approaches. Papers addressing both the basic science and more applied issues in the field of EC-SS and energy conversion and storage materials have been published in this Special Issue.

Keywords

electrosynthesis --- switchable surfaces --- alkoxyamine surfaces --- redox monolayers --- porphyrins --- self-assembly --- surface nanostructures --- in situ EC-STM --- metal-electrolyte interface --- potential-dependent structures --- combined non-covalent control --- ECALE --- CdS --- silver single crystals --- alkanthiols --- SAMs --- EQCM --- AES --- polypyrrole --- diazonium salts --- flexible ITO --- adhesion --- redox properties --- X-ray absorption spectroscopy --- energy dispersive --- quick-XAS --- FEXRAV --- free electron laser --- electrochemistry --- photoelectrochemistry --- photochemistry --- pump &amp --- probe --- oxygen evolution reaction --- water splitting --- iridium --- thin-films --- spin-coating --- model systems --- electrocatalysts --- oxygen evolution reaction --- iridium --- nickel --- electrodeposition --- model catalyst --- water oxidation --- CO oxidation --- DFT --- hydrogen adsorption --- Pt–Ru catalysts --- ordered mesoporous carbons --- graphitization --- CO oxidation --- methanol oxidation --- direct methanol fuel cells --- electrocatalysis --- catalysts --- methanol oxidation reaction --- graphene --- DMFC --- Pt --- SOFC --- cathode --- XAFS --- in situ --- cobalt oxide --- water oxidation --- photo-electrochemistry --- hydroxyl radical --- electro-oxidation --- Lead OPD --- surface alloy --- XPS --- UPS --- EF-PEEM --- ORR --- Platinum --- PVDF --- PEMFC --- in situ ambient pressure XPS --- hard X rays --- photoelectron simulations --- solid/liquid interface --- TiO2 --- APTES --- Cu(111) --- electrochemical interface --- in-situ X-ray diffraction --- carbon nanofiber --- porous fiber --- electrospinning --- mesopore --- micropore --- porogen --- ammonia activation --- surface area --- methanol oxidation --- platinum single crystals --- pH and concentration effects --- adsorbed OH --- reduced graphene oxide --- electrophoretic deposition --- surface chemistry --- click chemistry --- gold --- palladium --- bimetallic alloy --- carbon nanofibers (CNFs) --- cyclic voltammetry (CV) --- Surface Modification --- Blackening of Steel --- Magnetite --- Corrosion Protection --- Auger-Electron Spectroscopy --- Ordered mesoporous carbon --- nitrogen doping --- cobalt-based electrocatalyst --- bifunctional oxygen electrode --- solvothermal method --- underpotential deposition (upd) --- Au --- Pt --- Pd --- nanoparticles --- cyclic voltammetry --- electrocatalysis --- operando --- near ambient pressure XPS --- scanning photoelectron microscopy --- solid oxide fuel cells --- surface science --- electrodeposited alloys --- CO electro-oxidation --- Pt single-crystal electrodes --- potential cycling --- potential stepping --- surface reconstruction --- electrocatalysis --- oxygen reduction --- ORR --- gas diffusion electrode --- platinum --- fuel cells --- thin-films --- benchmarking --- mass transport --- formic acid oxidation --- Au nanocrystals --- Pd thin films --- electrocatalysis --- d-band theory --- polymer --- silicon nanoparticles --- EPR spectroscopy --- photoconversion --- n/a

Design and Development of Nanostructured Thin Films

Authors: --- ---
ISBN: 9783039287383 / 9783039287390 Year: Pages: 386 DOI: 10.3390/books978-3-03928-739-0 Language: eng
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Technology (General)
Added to DOAB on : 2020-06-09 16:38:57
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Due to their unique size-dependent physicochemical properties, nanostructured thin films are used in a wide range of applications from smart coating and drug delivery to electrocatalysis and highly-sensitive sensors. Depending on the targeted application and the deposition technique, these materials have been designed and developed by tuning their atomic-molecular 2D- and/or 3D-aggregation, thickness, crystallinity, and porosity, having effects on their optical, mechanical, catalytic, and conductive properties. Several open questions remain about the impact of nanomaterial production and use on environment and health. Many efforts are currently being made not only to prevent nanotechnologies and nanomaterials from contributing to environmental pollution but also to design nanomaterials to support, control, and protect the environment. This Special Issue aims to cover the recent advances in designing nanostructured films focusing on environmental issues related to their fabrication processes (e.g., low power and low cost technologies, the use of environmentally friendly solvents), their precursors (e.g., waste-recycled, bio-based, biodegradable, and natural materials), their applications (e.g., controlled release of chemicals, mimicking of natural processes, and clean energy conversion and storage), and their use in monitoring environment pollution (e.g., sensors optically- or electrically-sensitive to pollutants)

Keywords

InAlN --- nanospiral --- metamaterial --- sputtering --- chirality --- microparticle deposition --- self-assembly --- homogeneity --- monomer synthesis --- mask --- hazardous organic solvents --- photonic nanostructures --- self-assembly --- polymer nanoparticles --- biomimetic solvent sensors --- iridescence --- mesoporous --- Al2O3 --- MgO --- poly(dimethylacrylamide) --- hydrogel --- thin film --- spin coating --- SEM --- FIB --- Kr physisorption --- hydrogenated amorphous carbon films --- metallic nanoparticles --- hybrid deposition system --- nanoscratch --- nanocomposites --- aqueous dispersion --- carbon nanotube --- graphene oxide --- ink --- rod coating --- electrical conductivity --- optical transmittance --- mechanical flexibility --- silk sericin --- agarose --- lysozyme --- composite gel --- wound dressing --- nanofiber --- lamination --- water filtration --- CdTe --- self-catalysed --- wires --- Mg alloy --- LDH --- corrosion --- deposition --- coating --- ReB2/TaN multilayers --- modulation structure --- first-principles calculation --- interfacial model --- adsorption energy --- interfacial energy --- biomaterial --- biomedical --- nanofibers --- scaffolds --- reinforced --- hybrid material --- thermal analysis --- nanofibrous membranes --- light trapping --- silicon thin film --- photovoltaics --- polystyrene sphere assisted lithography --- nanostructured back reflectors --- Raman scattering --- quantum confinement --- electron–phonon coupling --- polar semiconductors --- zinc oxide --- metal-organic framework --- microscopy --- thin films --- powders --- electrodeposition --- platinum --- highly oriented pyrolytic graphite --- 2D growth --- barrier material --- nanocoating of SiOx --- polymeric matrix --- plasma deposition --- PVD --- PA-PVD --- PECVD --- permeation --- CERAMIS® --- SorpTest --- iron oxides --- FeO --- Fe3O4 --- ultrathin films --- epitaxial growth --- platinum --- ruthenium --- symmetry --- LEEM --- LEED --- XPEEM --- electrodeposition --- platinum --- highly oriented pyrolytic graphite --- 2D growth --- thin films --- TiO2NPs --- AuNPs --- photocatalysis --- mercury vapors adsorbing layer --- PAS device --- iron oxides --- ultrathin films --- silver --- epitaxial growth --- structural characterization --- STM --- LEED --- XPS --- DFT --- model system --- Pt thin deposits --- galvanic displacement --- UPD --- SLRR --- electrocatalysis --- nanostructured films --- birefringence --- nanocrystalline cellulose --- Mueller matrix --- vanadium dioxide --- post-treatment --- plasma irradiation --- luminous transmittance --- phase transition performance --- electrospinning deposition --- chemosensor --- nanocomposite conductive polymers --- polyhydroxibutyrate --- polystyrene --- H2TPP --- VOCs selectivity --- mesoporous graphene --- thin film --- nanostructure --- CaxCoO2 --- sputtering --- phase transformation --- Ge surface engineering --- La2O3 passivation layer --- atomic layer deposition --- electrical properties

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