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Monolayer assembly

Sohoeler U, Tews K FI and Kuhn FI 1974 Potential model of dye moleoule from measurements of the photoourrent in monolayer assemblies J. Chem. Phys. 61 5009-16... [Pg.2630]

Liu Z, Loo B FI, Baba R and Fu]ishima A 1990 Exoellent reversible photoohromio behaviour of 4-ootyl-4 -(5-oarboxyl-pentamethyleneoxy)-azobenzene in organized monolayer assemblies Chem. Lett. 1023-6... [Pg.2632]

Netzer L and Sagiv J 1983 A new approach to construction of artificial monolayer assemblies J. Am. Chem. Soc. 105 674-6... [Pg.2635]

Bertilsson L and Liedberg B 1993 Infrared study of thiol monolayers assemblies on gold—preparation, oharaoterization, and funotionalization of mixed monolayers Langmuir 3 141-9... [Pg.2640]

SFA has been traditionally used to measure the forces between modified mica surfaces. Before the JKR theory was developed, Israelachvili and Tabor [57] measured the force versus distance (F vs. d) profile and pull-off force (Pf) between steric acid monolayers assembled on mica surfaces. The authors calculated the surface energy of these monolayers from the Hamaker constant determined from the F versus d data. In a later paper on the measurement of forces between surfaces immersed in a variety of electrolytic solutions, Israelachvili [93] reported that the interfacial energies in aqueous electrolytes varies over a wide range (0.01-10 mJ/m-). In this work Israelachvili found that the adhesion energies depended on pH, type of cation, and the crystallographic orientation of mica. [Pg.107]

Inacker, O., Kuhn, H., Bucher, H., Meyer, H. and Tews, K. H. (1970). Monolayer assembling technique used to determine the multipole nature of the phosphorescence of a dye molecule. Chem. Phys. Lett. 7, 213-8. [Pg.69]

Tarabara V.V., Nabiev I.R., Feofanov A.V., Surface-enhanced Raman scattering (SERS) study of mercaptoethanol monolayer assemblies on silver citrate hydrosol. Preparation and characterization of modified hydrosol as a SERS-active substrate, Langmuir 1998 14 1092-1098. [Pg.255]

I. Willner, V. Heleg-Shabtai, R. Blonder, E. Katz, and G. Tao, Electrical wiring of glucose oxidase by reconstitution of FAD-modified monolayers assembled onto Au-electrodes. J. Am. Chem. Soc. 118, 10321-10322 (1996). [Pg.91]

Fig. 12 In situ optical switching of the current flowing through a DAE monolayer assembled in a PEDOT PSS interlayer-based LAJ. (a) Comparison of the current densities flowing through as assembled open and closed isomer and upon in-situ photoisomerization. Fig. 12 In situ optical switching of the current flowing through a DAE monolayer assembled in a PEDOT PSS interlayer-based LAJ. (a) Comparison of the current densities flowing through as assembled open and closed isomer and upon in-situ photoisomerization.
After the cleaning process, other techniques are used to prepare the surface of the substrate for coating. Some techniques include drying, surface etching, and chemical surface preparation. Examples of chemical surface preparation include the formation of an oxide layer or the monolayer assembly of an adhesion promoter on the surface. These processes modify the surface of the substrates so as to facilitate the subsequent deposition process. In surface preparation, frequently, the hydrophilic/hydrophobic character of the surface is controlled to match the coating solution properties. For example, Van Driessche et al.19 reported on improving the wettability of Ni-4at%W tapes... [Pg.35]

Control of molecular orientation and packing in monolayer assemblies... [Pg.82]

Control of oriented antibody layer by monolayer assemblying technique. [Pg.88]

Various Orientation of functional groups in monolayer assemblies and its effect upon some functions. [Pg.99]

Figure 29. For the latter case, it is considered that the semiconducting re-electron systems are separated by insulating hydrocarbon spacers, resulting in alternate thin layers of organic semiconductor and insulator in these monolayer assemblies. The direct current - voltage (I - V) characteristics were mea- sured for the multilayers H2Pc(R)8 and Cu-Pc(R)8 in directions perpendicular and parallel to the film plane. In both cases, the linear I - V relationships of Ohm s law were observed at low electric field and obtained DC conductivities are summarized in Table 3. The normal conductivity (ajJ were ca. 10 13 S cm-1, while the lateral ones p//) were 3.4 x 10-7 and 9.9 x 10 7 S cm 1 for films of the metal-free and copper Pc derivatives, respectively. The former (ojJ tended to decrease slightly with increase of Figure 29. Schematical illustration of the substituent alkyl chain length,... Figure 29. For the latter case, it is considered that the semiconducting re-electron systems are separated by insulating hydrocarbon spacers, resulting in alternate thin layers of organic semiconductor and insulator in these monolayer assemblies. The direct current - voltage (I - V) characteristics were mea- sured for the multilayers H2Pc(R)8 and Cu-Pc(R)8 in directions perpendicular and parallel to the film plane. In both cases, the linear I - V relationships of Ohm s law were observed at low electric field and obtained DC conductivities are summarized in Table 3. The normal conductivity (ajJ were ca. 10 13 S cm-1, while the lateral ones p//) were 3.4 x 10-7 and 9.9 x 10 7 S cm 1 for films of the metal-free and copper Pc derivatives, respectively. The former (ojJ tended to decrease slightly with increase of Figure 29. Schematical illustration of the substituent alkyl chain length,...
Polycondensation of long-chain esters of amino acids containing aromatic rings in the monolayer assemblies. [Pg.111]

Figure 1. Schematic representation of the artificial photosynthetic reaction center by a monolayer assembly by A-S-D triad and antenna molecules for light harvesting (H), lateral energy migration and energy transfer, and charge separation across the membrane via multistep electron transfer (a) Side view of mono-layer assembly, (b) top view of a triad surrounded by H molecules, and (c) energy diagram for photo-electric conversion in a monolayer assembly. Figure 1. Schematic representation of the artificial photosynthetic reaction center by a monolayer assembly by A-S-D triad and antenna molecules for light harvesting (H), lateral energy migration and energy transfer, and charge separation across the membrane via multistep electron transfer (a) Side view of mono-layer assembly, (b) top view of a triad surrounded by H molecules, and (c) energy diagram for photo-electric conversion in a monolayer assembly.
Fig. 5 /d-Tds characteristics for polydiacetylene monolayers, assembled and polymerized on the air-water interface (inset) and transferred to form bottom-contact, bottom-gate p-type FETs... [Pg.223]

Fig. 10 (a) Transfer characteristics in the linear and saturation regimes for a-substituted quinquethiophene liquid crystalline monolayers assembled on the Si02 gate dielectric surface of a 40 pm channel length FET. Inset) Field-effect mobility as a function of FET channel length, (b) Output characteristics of the FET. The transfer and output characteristics were scanned in both positive and negative directions in applied voltage... [Pg.229]

Electrical Wiring of Redox Enzymes by Relay-Functionalized Monolayer Assemblies... [Pg.335]

Amplified electrochemical detection of DNA in monolayer assemblies was accomplished by the conjugation of bioelectrocatalytic transformations to the DNA recognition events. This was exemplified with the amplified electrochemical analysis of M13 phage DNA (Fig. 12.20a).75 A capturing nucleic acid, (20), complementary to... [Pg.361]

H. Kuhn, Interaction of chromophores in monolayer assemblies , Pure Appl. Chem., 27, 1971. 421. [Pg.359]


See other pages where Monolayer assembly is mentioned: [Pg.162]    [Pg.2574]    [Pg.70]    [Pg.126]    [Pg.45]    [Pg.68]    [Pg.82]    [Pg.82]    [Pg.83]    [Pg.99]    [Pg.101]    [Pg.111]    [Pg.117]    [Pg.435]    [Pg.139]    [Pg.92]    [Pg.95]    [Pg.16]    [Pg.215]    [Pg.222]    [Pg.227]    [Pg.341]    [Pg.765]    [Pg.205]    [Pg.1018]    [Pg.1019]   
See also in sourсe #XX -- [ Pg.543 , Pg.572 ]




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Adhesion Self-assembled monolayers

Alkanethiol self-assembled monolayers

Alkanethiols, self-assembled monolayers

Assembled Monolayers of Metal Complexes on Single-Crystal Surfaces

Assembled monolayers

Assembled monolayers

Assembly of monolayers

Biomaterial self-assembled monolayers

Chlorophylls) monolayer assemblies

Collapse States of Monolayer Assemblies

Contact angle self-assembled monolayers

Design using self-assembled monolayers

Disulfides, self-assembled monolayers

Electroactive monolayers/multilayers self-assembly

Electroactive self-assembled monolayers, with

Electrochemical sensors self-assembled monolayers

Electrochemistry and Self-Assembled Monolayers

Electrochemistry on Self-assembled Monolayers

Electron monolayer assembly

Fluorinated self-assembled monolayer

Fluorinated self-assembled monolayer SAM) film

Formation of Self-Assembled Monolayers

Gate self-assembled monolayer

General Factors Affecting the Behavior of Metals Deposited onto Self-Assembled Monolayers

Gold nanoparticles self-assembled monolayers

Gold surfaces, chromophores self-assembled monolayers

Grafting-from methods self-assembled monolayer

High-density self-assembled monolayers

Hydroxy-terminated self-assembled monolayers

Immunoassays and immunosensors, recent self-assembled monolayers

Interfacial reactions self-assembled monolayers

Langmuir—Blodgett deposition self-assembled monolayers

Low-density self-assembled monolayers

Macroscopic self-assembled monolayers

Mechanically assembled monolayers

Mercaptoundecanoic acid, self-assembled monolayer

Microcontact Printing of Self-Assembled Monolayers

Molecular Recognition at LB Films and Self-Assembled Monolayers

Molecular self-assembled monolayer

Monolayer assemblies, reproducibility

Monolayer randomly assembled

Monolayer self-assembled

Monolayer, self-assembling

Monolayer- and Multilayer-enzyme Assemblies Functionalized with Electron-transfer Mediators

Monolayers and LB Films - Controllable Layered Assembly

Monolayers organized assemblies

Monolayers, self-assembled, nucleation

N-Alkanoic acid self-assembled monolayers

Nanoparticle-based corrosion inhibitors and self-assembled monolayers

Nanoparticles and self-assembled monolayers

Nanopores in Self-Assembled Monolayers

Organic reactions, self-assembled monolayers

Oriented Monolayer Assemblies

Patterned Self-assembled Monolayers

Patterned self-assembling monolayers

Polymer brushes self-assembled monolayers

Polymers patterned self-assembling monolayers

Preparation of Self-Assembled Monolayers

SAM = self-assembled monolayer

Selectivity self-assembled” monolayers

Self assembled monolayers chemical transformations

Self assembled monolayers computational studies

Self assembled monolayers definition

Self assembled monolayers formation, mechanism

Self assembled monolayers synthesis

Self assembled monolayers systems

Self assembly of monolayers

Self-Assembled Monolayer Gate Dielectrics

Self-Assembled Monolayers and Multilayers

Self-Assembled Monolayers and Multilayers Derived from Organosilicon Derivatives

Self-Assembled Monolayers characterisation

Self-Assembled Monolayers with Hydroquinone Incorporation

Self-Assembled Monolayers, Biological Membranes, and Biosensors

Self-Assembled Monolayers—Lipids in Materials Science and Bioengineering

Self-Assembly Monolayer Formation

Self-Assembly Monolayers (SAMs)

Self-assembled Alkanethiol Monolayer on Mercury

Self-assembled DNA monolayers

Self-assembled Monolayers as Tailored Functional Surfaces in Two and Three Dimensions

Self-assembled Monolayers for Surface Engineering

Self-assembled Monolayers of Rigid Mercaptobiphenyls

Self-assembled monolayer alkylthiol

Self-assembled monolayer antibody immobilization

Self-assembled monolayer chemistry

Self-assembled monolayer derivatization

Self-assembled monolayer desorption

Self-assembled monolayer electron-transfer kinetics

Self-assembled monolayer hydrophobic

Self-assembled monolayer monolayers)

Self-assembled monolayer noble metals

Self-assembled monolayer on gold

Self-assembled monolayer preparation

Self-assembled monolayer response times

Self-assembled monolayer semiconductors

Self-assembled monolayer technique

Self-assembled monolayers

Self-assembled monolayers , label-free

Self-assembled monolayers , scanning

Self-assembled monolayers , scanning electrochemical microscopy

Self-assembled monolayers , scanning electron transfer

Self-assembled monolayers SAMs)

Self-assembled monolayers and

Self-assembled monolayers applications

Self-assembled monolayers characterization

Self-assembled monolayers chemical reactions

Self-assembled monolayers chemistry

Self-assembled monolayers copper surfaces

Self-assembled monolayers corrosion inhibitors

Self-assembled monolayers cyclodextrins

Self-assembled monolayers development

Self-assembled monolayers electrochemical behavior

Self-assembled monolayers electrochemical studies

Self-assembled monolayers electrochemistry

Self-assembled monolayers electron transfer

Self-assembled monolayers electrostatic binding

Self-assembled monolayers energy transfer

Self-assembled monolayers enhancing stability

Self-assembled monolayers enzymatic surface-initiated

Self-assembled monolayers fluorescent

Self-assembled monolayers formation

Self-assembled monolayers future applications

Self-assembled monolayers hydroxyl terminated

Self-assembled monolayers hyperbranched

Self-assembled monolayers laboratory experiments

Self-assembled monolayers mechanism

Self-assembled monolayers micro-contact printing

Self-assembled monolayers modified electrodes

Self-assembled monolayers molecular conductance

Self-assembled monolayers molecular recognition

Self-assembled monolayers multilayering

Self-assembled monolayers nanotechnology

Self-assembled monolayers new approaches

Self-assembled monolayers of alkanethiols

Self-assembled monolayers of n-alkanoic

Self-assembled monolayers of n-alkanoic acids

Self-assembled monolayers of silanes

Self-assembled monolayers overview

Self-assembled monolayers oxidation

Self-assembled monolayers patterning

Self-assembled monolayers photoactive

Self-assembled monolayers photochemistry

Self-assembled monolayers pinholes

Self-assembled monolayers polymeric

Self-assembled monolayers polymerization

Self-assembled monolayers preparation

Self-assembled monolayers reactions

Self-assembled monolayers reduction

Self-assembled monolayers solution-phase deposition

Self-assembled monolayers solutions

Self-assembled monolayers stability

Self-assembled monolayers structure

Self-assembled monolayers surface characterization

Self-assembled monolayers surface modification

Self-assembled monolayers terminal groups

Self-assembled monolayers test solution

Self-assembled monolayers thiol

Self-assembled monolayers thiol-based

Self-assembled monolayers through, chains

Self-assembled monolayers transformations

Self-assembled monolayers tunneling microscopy

Self-assembled monolayers, of DNA

Self-assembled monolayers, reactive

Self-assembled monolayers, reactive surfaces

Self-assembled thiourea monolayer

Self-assembled, generally monolayers

Self-assembling monolayers

Self-assembling monolayers, SAMs

Self-assembly monolayer

Self-assembly monolayer imprinted

Self-assembly monolayers

Self-assembly process, polymer monolayer

Self-assembly, organized assemblies monolayers

Silanes, self-assembled monolayers

Silicon surfaces, self-assembled monolayers

Stability self-assembled monolayer

Surface Self-Assembled Monolayers

The Self-assembled Monolayer Approach

Thiols, self-assembled monolayers

Use of self-assembly monolayers

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