Phase Deposition
상 증착

Phase Deposition(상 증착)란 무엇입니까?

Phase Deposition 상 증착 - Herein, a hygro-responsive superoleophobic/superhydrophilic coating was fabricated by liquid-phase deposition of TiO2 with perfluorooctanoic acid. ^[1] The purpose of this research is to investigate a low-cost liquid-phase deposition (LPD) method for preparing gallium oxide ([Formula: see text]-Ga2O[Formula: see text] films. ^[2] To combat this problem, this study used liquid-phase deposition (LPD) to fabricate a TiO2 film on anodizing TNT. ^[3] This Letter describes a method termed solid-phase deposition (SPD). ^[4] Liquid-phase deposition of exfoliated 2D nanosheets is the basis for emerging technologies that include writable electronic inks, molecular barriers, selective membranes, and protective coatings against fouling or corrosion. ^[5] In particular, we focus on providing theoretical interpretations on how open nanoporous MIEC interlayers manipulate β-phase deposition and stripping behavior and thereby suppress such instabilities, referring to the fundamental thermodynamics and kinetics governing the nucleation and growth of the β-phase. ^[6] The preparation strategies to construct 2D homojunctions including vapor-phase deposition, lithium intercalation, laser irradiation, chemical doping, electrostatic doping, and photodoping are summarized in detail. ^[7] A technology for applying an anti-emission pyrocarbon coating by plasma-chemical gas-phase deposition to the grid electrodes of high-power electrovacuum devices has been developed. ^[8] The supporting information of the article entitled "Corrosion Inhibition for Steel Surface Using a Polyacrylic Gel Sheet Containing Ni–Al Layered Double Hydroxide Prepared by Liquid-Phase Deposition". ^[9] Solvent-based deposition in a fluorinated oil (FC-40) generated significantly higher contact angles than deposition in ethanol or gas-phase deposition, yielding hydrophobic surfaces with contact angle > 110˚ under optimized conditions. ^[10] Diamond coatings on a molybdenum substrate were obtained by gas-phase deposition from a high-speed jet of activated gases. ^[11] In this paper, we report on a new drying method: sublimation drying by LPD (Liquid-phase deposition). ^[12] The objective of our study was to prepare Y-, USY- and ZSM-5-based catalysts by hydrothermal synthesis, followed by copper active-phase deposition by either conventional ion-exchange or ultrasonic irradiation. ^[13] The zoned distribution of moganite and variations in the microtexture and porosity of the agates indicate a multi-phase deposition of SiO2 under varying physico-chemical conditions and a discontinuous silica supply. ^[14] 68%) were prepared from anisotropic natural balsa wood via a scalable and sustainable silanization reaction using liquid-phase deposition (LPD). ^[15] In-situ and ex-situ X-ray 3D-tomography is used to characterize the microstructure of Ni microwires, with wire diameters spanning 25–100 μm, (i) after vapor-phase deposition of Ti onto their surface and (ii) after subsequent homogenization to achieve the near-equiatomic NiTi composition desired for shape-memory or superelastic behavior. ^[16] Solvent-based deposition in a fluorinated oil (FC-40) generated significantly higher contact angles than deposition in ethanol or gas-phase deposition, yielding hydrophobic surfaces with contact angle >110° under optimized conditions. ^[17] Here the authors implement vapor-phase deposition to fabricate 3D polymeric materials that permit biomolecule functionalization, tunable mass transport and mechanical properties, as well as control over boundaries between compartments, and analyze the behavior of 3D encapsulated cells. ^[18] The surface preparation is a prerequisite for ensuring the required properties of a diamond film formed by gas-phase deposition. ^[19] In this article, we review five approaches for fabricating UiO-66 polycrystalline membranes including in situ synthesis, secondary synthesis, biphase synthesis, gas-phase deposition and electrochemical deposition, as well as their applications in gas separation, pervaporation, nanofiltration and ion separation. ^[20] It has been established that the addition of ammonia significantly changes the mechanism of the gas-phase deposition of films. ^[21] The electrodes were prepared using gas-phase deposition of mixed Ni0. ^[22] The process described herein details a solution-phase deposition of a catalytically-active noble metal (Pd) from a transition metal halide salt (H2PdCl4) onto aqueously-suspended, anisotropic plasmonic structures (AuNR). ^[23] We report here systematic measurements of longitudinal electrical transport, Shubnikov-de-Haas (SdH) quantum oscillations, Hall coefficient (R_H^2D), and Seebeck coefficient as a function of film thickness (d) and temperature using high quality Bi2-xSbxTe3-ySey (BSTS) single crystal thin films grown by physical vapor-phase deposition. ^[24] A kind of water-soluble organic dye CuPc-SO3H was immobilized onto the surface of Al@SiO2 by liquid-phase deposition. ^[25] Strengthening layers were formed by external and internal vapor-phase deposition of titaniumsilicate glass. ^[26] Thin-film analogs of these two systems are fabricated by the sequential, alternating, solution-phase deposition of the inorganic and organic ligand precursors that result in conformal films via van der Merwe-like growth. ^[27] Aligned Co/F codoped tin oxide (SnO2) nanotubes/nanowires with high photocatalytic activity were successfully prepared via the liquid-phase deposition (LPD) process by immersing the anodic aluminum oxide template in a (NH4)2SnF6 aqueous solution. ^[28] We report a metal-insulator-semiconductor (MIS) diode with an α-Ga 2 O 3 thin-film insulator layer grown by liquid-phase deposition (LPD). ^[29] In the present chapter, ZnO nanowire structures via a low-pressure vapor-phase deposition and a simple solvothermal method will be presented. ^[30] The results of experimental studies of chip formation peculiarities and wear resistance of carbide inserts with a multi-layer wear-resistant coating obtained by chemical vapor-phase deposition when turning 08X18H10T corrosion-resistant heat-resistant steel are presented. ^[31]
여기서, 흡습성 초소유성/초친수성 코팅은 퍼플루오로옥탄산으로 TiO2의 액상 증착에 의해 제조되었다. ^[1] 이 연구의 목적은 산화갈륨([화학식: 본문 참조]-Ga2O[화학식: 본문 참조] 필름을 제조하기 위한 저가의 액상 증착(LPD) 방법을 조사하는 것입니다. ^[2] 이 문제를 해결하기 위해 이 연구에서는 LPD(액상 증착)를 사용하여 아노다이징 TNT 위에 TiO2 막을 제작했습니다. ^[3] 이 편지는 고체상 증착(SPD)이라는 방법을 설명합니다. ^[4] 박리된 2D 나노시트의 액상 증착은 쓰기 가능한 전자 잉크, 분자 장벽, 선택적 멤브레인 및 오염 또는 부식에 대한 보호 코팅을 포함하는 새로운 기술의 기초입니다. ^[5] 특히, 우리는 개방형 나노다공성 MIEC 중간층이 β-상 증착 및 스트리핑 거동을 조작하여 이러한 불안정성을 억제하는 방법에 대한 이론적 해석을 제공하는 데 초점을 맞추고 β-상의 핵 생성 및 성장을 지배하는 기본 열역학 및 동역학을 참조합니다. ^[6] 기상 증착, 리튬 인터칼레이션, 레이저 조사, 화학적 도핑, 정전 도핑 및 포토 도핑을 포함한 2D 호모 접합을 구성하기 위한 준비 전략이 자세히 요약되어 있습니다. ^[7] 고출력 전자진공 소자의 그리드 전극에 플라즈마-화학적 기상 증착법에 의한 방출 방지 파이로카본 코팅을 적용하는 기술이 개발되었다. ^[8] "액상 증착에 의해 제조된 Ni-Al 층상 이중 수산화물을 포함하는 폴리아크릴 겔 시트를 사용한 강철 표면의 부식 억제"라는 제목의 기사의 지원 정보. ^[9] 용제 기반 증착 플루오르화 오일(FC-40)은 에탄올에서의 증착 또는 기상 증착으로 소수성 표면 생성 최적화된 조건에서 접촉각 > 110˚. ^[10] 몰리브덴 기판의 다이아몬드 코팅은 활성화된 가스의 고속 제트로부터 기상 증착에 의해 얻어졌습니다. ^[11] 이 논문에서 우리는 새로운 건조 방법인 LPD(액상 증착)에 의한 승화 건조에 대해 보고합니다. ^[12] 우리 연구의 목적은 열수 합성에 의해 Y-, USY- 및 ZSM-5 기반 촉매를 준비한 다음 기존의 이온 교환 또는 초음파 조사에 의한 구리 활성상 증착을 준비하는 것입니다. ^[13] 모가나이트의 구역 분포와 마노의 미세 조직 및 다공성의 변화는 다양한 물리 화학적 조건과 불연속 실리카 공급에서 SiO2의 다상 증착을 나타냅니다. ^[14] 68%)는 LPD(액상 증착)를 사용하여 확장 가능하고 지속 가능한 실란화 반응을 통해 이방성 천연 발사목으로 준비했습니다. ^[15] In-situ 및 ex-situ X-ray 3D 단층 촬영은 와이어 직경이 25–100μm인 Ni 마이크로 와이어의 미세 구조를 특성화하는 데 사용됩니다. 형상 기억 또는 초탄성 거동에 필요한 거의 등원자 NiTi 조성을 달성하기 위한 후속 균질화. ^[16] 플루오르화 오일(FC-40)의 용매 기반 증착은 에탄올 또는 기상 증착보다 훨씬 더 높은 접촉각을 생성하여 최적화된 조건에서 접촉각이 >110°인 소수성 표면을 생성했습니다. ^[17] 여기에서 저자는 생체 분자 기능화, 조정 가능한 질량 수송 및 기계적 특성뿐만 아니라 구획 간의 경계 제어를 허용하고 3D 캡슐화된 세포의 동작을 분석하는 3D 고분자 재료를 제조하기 위해 기상 증착을 구현합니다. ^[18] 표면 처리는 기상 증착에 의해 형성된 다이아몬드 필름의 요구되는 특성을 보장하기 위한 전제 조건입니다. ^[19] 이 기사에서는 현장 합성, 2차 합성, 2상 합성, 기체상 증착 및 전기화학 증착을 포함한 UiO-66 다결정질 막을 제조하기 위한 5가지 접근법과 기체 분리, 투과증발, 나노여과 및 이온 분리에서의 응용을 검토합니다. ^[20] 암모니아를 첨가하면 필름의 기상 증착 메커니즘이 크게 변경된다는 것이 확인되었습니다. ^[21] 전극은 혼합 NiO의 기상 증착을 사용하여 준비되었습니다. ^[22] 여기에 설명된 공정은 전이 금속 할로겐화물 염(H2PdCl4)으로부터 수성 현탁된 이방성 플라즈몬 구조(AuNR) 상으로의 촉매 활성 귀금속(Pd)의 용액상 증착을 자세히 설명합니다. ^[23] 우리는 고품질 Bi2-xSbxTe3-를 사용하여 필름 두께(d) 및 온도의 함수로서 세로 전기 전송, Shubnikov-de-Haas(SdH) 양자 진동, 홀 계수(R_H^2D) 및 Seebeck 계수의 체계적인 측정을 보고합니다. 물리적 기상 증착에 의해 성장된 ySey(BSTS) 단결정 박막. ^[24] 수용성 유기염료인 CuPc-SO3H의 일종을 Al@SiO2의 표면에 액상증착에 의해 고정화하였다. ^[25] 강화층은 티타늄실리케이트 유리의 외부 및 내부 기상 증착에 의해 형성되었습니다. ^[26] 이 두 시스템의 박막 유사체는 반 데르 메르베(van der Merwe)와 같은 성장을 통해 등각 필름을 생성하는 무기 및 유기 리간드 전구체의 순차적 교대 용액상 증착에 의해 제조됩니다. ^[27] 높은 광촉매 활성을 갖는 정렬된 Co/F codoped tin oxide(SnO2) 나노튜브/나노와이어는 양극 산화알루미늄 템플릿을 (NH4)2SnF6 수용액에 침지함으로써 액상 증착(LPD) 공정을 통해 성공적으로 준비되었습니다. ^[28] 우리는 액상 증착(LPD)에 의해 성장된 α-Ga 2 O 3 박막 절연체 층이 있는 금속 절연체 반도체(MIS) 다이오드를 보고합니다. ^[29] 이 장에서는 저압 기상 증착을 통한 ZnO 나노와이어 구조와 간단한 solvothermal 방법을 제시할 것이다. ^[30] 08X18H10T 내부식성 내열강을 선삭할 때 화학 기상 증착에 의해 얻은 다층 내마모성 코팅이 적용된 카바이드 인서트의 칩 형성 특성 및 내마모성에 대한 실험적 연구 결과가 제시됩니다. ^[31]

ng m2 day m2일의

Almost all OPEs underwent net gas-phase deposition to the lakes, dominated by TCEP and TCPPs with median fluxes of -3980 ng/m2/day and -1320 ng/m2/day; the exception was TnBP, which underwent volatilization with the median fluxes of 1980 ng/m2/day. ^[1]
거의 모든 OPE는 -3980ng/m2/day 및 -1320ng/m2/day의 중앙 플럭스를 갖는 TCEP 및 TCPP가 지배하는 호수에 순 기상 증착을 거쳤습니다. 예외는 TnBP로, 플럭스 중앙값이 1980ng/m2/day로 휘발되었습니다. ^[1]

reduced graphene oxide 환원그래핀옥사이드

In this work, nickel-palladium (NiPd) alloy-reduced graphene oxide (rGO) has been prepared via liquid-phase deposition (LPD) technique and applied as counter electrode (CE) of dye-sensitized solar cell (DSSC). ^[1]
이 연구에서 니켈-팔라듐(NiPd) 합금 ​​환원 그래핀 산화물(rGO)은 액상 증착(LPD) 기술을 통해 준비되었으며 염료 감응 태양 전지(DSSC)의 상대 전극(CE)으로 적용되었습니다. ^[1]

Liquid Phase Deposition 액상 증착

In this study, an indium tin oxide (ITO) glass surface was roughened, and liquid phase deposition (LPD) was used to create TiO 2 compact layers to improve the efficiency of dye-sensitized solar cells (DSSCs). ^[1] A superhydrophobic CuFeCo powder alloy, obtained by combining high-energy ball milling (HEBM) and liquid phase deposition (LPD), was used to remove high-density polyethylene fibres from water. ^[2] The one-dimensional MoO3 nanobelts were prepared by a simple hydrothermal method, and then it was modified by AgI nanoparticles in a handy liquid phase deposition approach. ^[3] In this study, poly(acrylic acid) (PAA)-assisted molecularly imprinted (MI) TiO2 nanothin films fabricated via liquid phase deposition (LPD) were employed for CR detection. ^[4] Herein, we prepared WO3/HY zeolite catalysts by liquid phase deposition method with phosphotungstic acid as the precursor, and their catalytic activities were evaluated by alkylation of naphthalene and n-tetradecene (C14H28). ^[5] Specifically, 3D NiO NFs/CFM was fabricated by a sequential liquid phase deposition and annealing process, which was then characterized by scanning electron microscopy, X-ray photoelectron spectrum, UV-vis absorption spectra and N2 adsorption-desorption measurement. ^[6] The cathode has been prepared via liquid phase deposition technique assisted with modified Hummer’s method and spin-coating technique. ^[7] In this work, the spherical TiO2 inverse opal photonic crystals (IOPCs) have been successfully prepared through the combination of sol–gel and liquid phase deposition (LPD) method using SiO2 spheres as the templates. ^[8] The aim of this study was to improve the performance of a TiO2-nanorod solid–liquid heterojunction (SLHJ) ultraviolet photodetector covered with Al2O3-thin-film passivation layer through liquid phase deposition. ^[9] Sol–gel (SG) and liquid phase deposition (LPD) methods have been used to coat spherical glass beads with the photocatalyst (TiO2). ^[10] The catalyst used was the titanium dioxide nanoparticles/graphene oxide (TiO2/GO) nanocomposite, which was synthesized using the Hummers and Hoffman's method and the liquid phase deposition method. ^[11] In this work, zinc aminocaproate complex was extracted from expired aminocaproic acid injection via one-step facile chemical liquid phase deposition for the first time, and the morphology, microstr. ^[12] Liquid phase deposition (LPD) is one of the simplest methods among the chemical methods. ^[13] Insulating TiO2 coatings further improve the performance, and this work presents a facile liquid phase deposition strategy under ambient conditions using an aqueous TiF62- solution that proves more effective than the widely used method with TiCl4 for fabricating high-performing SnO2@TiO2 photoanode surfaces. ^[14] In this paper, the hollow-box-structured mesoscopic TiO2/g-C3N4 (M-T-CN) composites with visible-light response were prepared by liquid phase deposition (LPD) and topological transformation. ^[15] In this work, the needle-like γ-FeOOH nanoparticles were prepared by liquid phase deposition-air oxidation method, and then were calcined under different conditions to obtain γ-FeOOH and γ-Fe2O3 hybrid nanoparticles (γ-FeOOH@Fe2O3). ^[16] Lithium ions-doped NaV6O15 thin films have been prepared using a simple low temperature liquid phase deposition method and subsequent annealing process. ^[17] This paper reports ZnPt bimetallic nanoparticles (ZnPtBNs) synthesis through the liquid phase deposition (LPD) of of Zn(NO3)2. ^[18] WO3 · 2H2O with the layered crystal structure was grown into films consisting of plate-like particles on indium doped tin oxide substrates by the liquid phase deposition at room temperature. ^[19] To solve this problem, the bulk WC and the high dispersion supported WC were modified by hydrophobic organosilicones through simple liquid phase deposition. ^[20] Vapor deposition, liquid phase deposition, nanocasting, solid state approach, and energy beam techniques will be described. ^[21] TiO2 film was deposited on the PS microsphere template via liquid phase deposition (LPD) using a solution of ammonium hexafluoro-titanate [(NH4)2TiF6] and boric acid (H3BO3). ^[22] A modified liquid phase deposition process named “gas-assisted liquid phase deposition (G-LPD)” was developed to fabricate oxide films at a synthesis temperature below 100 °C and atmospheric pressure using readily available metal salts such as nitrates and chlorides. ^[23] Liquid phase deposition (LPD) which is simple, inexpensive and additive/binder free method is used for deposition. ^[24] The presence of perfluoro and alkylphosphonic self-assembled monolayers prepared by the liquid phase deposition (LPD) technique was confirmed by Fourier transform infrared spectroscopy (FTIR). ^[25] ZnO films were fabricated on polyether sulfone substrates using gas-assisted liquid phase deposition with ethylene glycol (EG) at 60 °C. ^[26] A dynamic chemical liquid phase deposition method was adopted to fabricate a set of proposed sensors with different silver layer thicknesses. ^[27] The extraction substrate was synthesized by depositing urchin-like ZnO micron particles on glass sheets using chemical liquid phase deposition. ^[28] This paper reports the preparation of silver-platinum (AgPt) nanofernson ITO surface using liquid phase deposition technique with various concentrations of silver nitrate in synthesis solution. ^[29] With the TiO2/chitosan liquid phase deposition columns with the concentration ratio of 3:7 [(NH4)2TiF6:chitosan], alkaloids were baseline separated within 11 min. ^[30] In this study, we report the synthesis of indium tin oxide (ITO) decorated Pt–Pd nanoparticle by a simple and facile liquid phase deposition protocol and their application as a heterogeneous catalyst for the reduction of toxic hexavalent chromium. ^[31] TiO2 HSs with external diameters around 450 nm were synthesized using hydrothermally grown carbon spheres as the template and through a liquid phase deposition (LPD) technique. ^[32] Branched higher silicon hydrides Si nH2 n+2 with n > 6 were recently found to be excellent precursors for the liquid phase deposition of silicon films. ^[33] TiO2 HSs were also prepared through the liquid phase deposition (LPD) of TiO2 on carbon spheres followed by a calcination process. ^[34] Graphene-coated TiO2 films have been prepared via liquid phase deposition assisted with spin coating technique and employed as photoanode of dye-sensitized solar cell (DSSC). ^[35] Liquid phase deposition (LPD) method was used to prepare the fluorine-containing titania transition layer as step 1, not only improving the binding force with the substrate, but also contributing to the deposition of the second bioactive layer obtained by hydrothermal method in step 2. ^[36] Preparation of well-ordered TiO2 films from alkaline solution by liquid phase deposition (LPD) method is still challenging owing to the fact that, in traditional mixing process, several disadvantages exist in controllable homogenous chemical reactions. ^[37] In our work, the Liquid Phase Deposition (LPD) method, as a new, non-vacuum method for aluminum coating on spherical spheres, is investigated as an alternative, scalable, and simple coating process. ^[38] We report the synthesis of TiO2/Graphene oxide nanocomposites (2%, 4%, 6% and 8%) by liquid phase deposition of titania on graphene oxide (GO) nanosheets. ^[39] In specific, zinc oxide (ZnO) nanowires were locally synthesized and directly integrated on a flexible polymer substrate using localized hydrothermal synthesis methods and their surfaces were selectively functionalized with palladium (Pd) nanoparticles using a liquid phase deposition process. ^[40]
이 연구에서는 인듐 주석 산화물(ITO) 유리 표면을 거칠게 하고 액상 증착(LPD)을 사용하여 TiO 2 콤팩트 층을 생성하여 염료 감응 태양 전지(DSSC)의 효율을 개선했습니다. ^[1] 고에너지 볼 밀링(HEBM)과 액상 증착(LPD)을 결합하여 얻은 초소수성 CuFeCo 분말 합금을 사용하여 물에서 고밀도 폴리에틸렌 섬유를 제거했습니다. ^[2] nan ^[3] nan ^[4] 여기에서는 인텅스텐산을 전구체로 하여 액상증착법으로 WO3/HY 제올라이트 촉매를 제조하고 나프탈렌과 n-테트라데센(C14H28)의 알킬화 반응을 통해 촉매 활성을 평가하였다. ^[5] nan ^[6] 음극은 수정된 Hummer의 방법과 스핀 코팅 기술을 지원하는 액상 증착 기술을 통해 준비되었습니다. ^[7] nan ^[8] nan ^[9] nan ^[10] nan ^[11]