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Stern

Rudnick J and Stern E A 1971 Second-harmonic radiation from metal surfaces Rhys. Rev. B 4 4274-90... [Pg.1301]

Hoch J 0 and Stern A S 1996 NMR Data Processing (New York Wiley-Liss)... [Pg.1465]

Rugar D, Mamin FI J, Guenther P, Lambert S E, Stern J E, McFadyen I and Yogi T 1990 Magnetic force microscopy general principles and application to longitudinal recording media J. Appl. Phys. 68 1169... [Pg.1725]

Frisch FI L and Stern S A 1983 Diffusion of small molecules in polymers Crit. Rev. Solid State Mater. Sc/. 11 123... [Pg.2540]

Stern D A, Wellner E, Salaita G N, Laguren-Davidson L, Lu F, Batina N, Frank D G, Zapien D C, Walton N and Flubbard A T 1988 Adsorbed thiophenol and related oompounds studied at Pt(111) eleotrode by EELS, Auger-speotrosoopy, and oyolie voltammetry J. Am. Chem. Soc. 110 4885-93... [Pg.2639]

Proger, Stern and Ilberg, System der organischen Verbindungen, 246 pp. (1926). This volume lists the 4877 system numbers and includes the common names with appropriate references to " system numbers (Julius Springer Edwards Brothers). [Pg.1117]

Stern plane Sternutators Steroid Steroid acids Steroidal antiestrogens Steroidal estrogens... [Pg.931]

Fig. 8. Electrical double layer of a sohd particle and placement of the plane of shear and 2eta potential. = Wall potential, = Stern potential (potential at the plane formed by joining the centers of ions of closest approach to the sohd wall), ] = zeta potential (potential at the shearing surface or plane when the particle and surrounding Hquid move against one another). The particle and surrounding ionic medium satisfy the principle of electroneutrafity. Fig. 8. Electrical double layer of a sohd particle and placement of the plane of shear and 2eta potential. = Wall potential, = Stern potential (potential at the plane formed by joining the centers of ions of closest approach to the sohd wall), ] = zeta potential (potential at the shearing surface or plane when the particle and surrounding Hquid move against one another). The particle and surrounding ionic medium satisfy the principle of electroneutrafity.
G-7. Stern, Air Follution, 3d ed., vols. 3-5, Academic, Orlando, FL, 1976-77. G-8. Strauss, Industtial Gas Cleaning, 2d ed., Pergamon, New York, 1975. G-9. Theodore and Biionicore, Air Follution Control Equipment Selection, Design, Operation and Maintenance, Prentice Hall, Englewood Cliffs, NJ, 1982. [Pg.1427]

FIG. 14-108 ( 7)Liqi lid entrainment from the bottom of a vessel by centrifugal flow. (Rietema and Veroer, Cyclones in Industry, Elsevier, Amsterdam, 1961. ) (h) Gas-oiitlet sldrt for liquid cyclones. (Stern et al. Cyclone Dust Collectors, Ametican Petroleum Institute, New York, 1955. )... [Pg.1429]

General Reeerences Nolilc and Stern ( edsj. Membrane Sejiaralions... [Pg.2023]

Catalytic A catalytic-membrane reactor is a combination heterogeneous catalyst and permselective membrane that promotes a reaction, allowing one component to permeate. Many of the reactions studied involve H9. Membranes are metal (Pd, Ag), nonporous metal oxides, and porous structures of ceran iic and glass. Falconer, Noble, and Speriy [in Noble and Stern (eds.), op. cit., pp. 669-709] review status and potential developments. [Pg.2050]

Economics It is ironic that a great virtue of membranes, their versatility, makes economic optimization of a membrane process veiy difficult. Designs can be tailored to veiy specific applications, but each design requires a sophisticated computer program to optimize its costs. Spillman [in Noble and Stern (eds)., op. cit., pp. 589-667] provides an overall review and numerous specific examples including circa 1989 economics. [Pg.2052]

This equation is not particularly useful in practice, since it is difficult to quantify the relationship between concentration and ac tivity. The Floiy-Huggins theory does not work well with the cross-linked semi-ciystaUine polymers that comprise an important class of pervaporation membranes. Neel (in Noble and Stern, op. cit., pp. 169-176) reviews modifications of the Stefan-Maxwell approach and other equations of state appropriate for the process. [Pg.2054]

Figure 5.1 Effect of oxygen concentration on corrosion of mild steel in slowly moving water containing 165 ppm CaCl2 48-hour test, 25°C. [Courtesy of H. H. Uhlig, D. N. Triadis, and M. Stern, Effect of Oxygen, Chlorides, and Calcium Ion on Corrosion Inhibition of Iron by Polyphosphates, J. Electrochem. Soc. 102, p. 60 (1955). Reprinted with permission by The Electrochemical Society, Inc. ]... Figure 5.1 Effect of oxygen concentration on corrosion of mild steel in slowly moving water containing 165 ppm CaCl2 48-hour test, 25°C. [Courtesy of H. H. Uhlig, D. N. Triadis, and M. Stern, Effect of Oxygen, Chlorides, and Calcium Ion on Corrosion Inhibition of Iron by Polyphosphates, J. Electrochem. Soc. 102, p. 60 (1955). Reprinted with permission by The Electrochemical Society, Inc. ]...
Fig. 17-4 Distribution of galvanic anodes for different shapes of stem, (a) Steamer stern one propeller, one balance rudder, (b) Steamer stern one propeller, a suspension rudder, (c) Tugboat stem two propellers, a Kort nozzle mdder. (d) Transom stem two propellers, a suspension mdder. (e) Transom stem two propellers, two suspension mdders. Fig. 17-4 Distribution of galvanic anodes for different shapes of stem, (a) Steamer stern one propeller, one balance rudder, (b) Steamer stern one propeller, a suspension rudder, (c) Tugboat stem two propellers, a Kort nozzle mdder. (d) Transom stem two propellers, a suspension mdder. (e) Transom stem two propellers, two suspension mdders.
M Levitt, C Sander, PS Stern. Int I Quant Chem Quant Biol Symp 10 181-199, 1983. [Pg.166]

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Alan Stern

Collisional Quenching the Stern-Volmer Relation

Double electrical layer Stern-Gouy Chapman model

Double layer model, Stern-Gouy-Chapman

Double layer theories Stern

Electric Stern model

Electrical Gouy-Chapman-Stern model

Electrical double layer Stern model

Fluorescence quenching Stern-Volmer plots

Gouy-Chapman-Stern double layer

Gouy-Chapman-Stern model

Gouy—Chapman—Stern—Grahame model

Helmholtz, Gouy-Chapman, Stern, and Grahame

Isotherms Stern-Langmuir

K. Stern

Metal Stern model

Oxide stern capacitance

Photochemical reactions Stern-Volmer plot

Quenching Stern-Volmer plot

Stern Extended or Quad Layer Model

Stern Modification

Stern Report

Stern adsorption

Stern adsorption isotherm

Stern cells

Stern double layer

Stern inner region

Stern layer

Stern layer binding

Stern layer ionic mobilities

Stern layer thickness

Stern model

Stern model of the double layer

Stern model, electric double

Stern model, electric double layer

Stern plane

Stern potential

Stern region

Stern review

Stern studies

Stern surface

Stern theory

Stern, David

Stern, Fritz

Stern, Georg

Stern, Katherine

Stern, Nicholas

Stern, Otto

Stern, Rose

Stern, Rudolf

Stern, Scott

Stern-Geary approximation

Stern-Geary equation

Stern-Geary equation derivation

Stern-Geary linear polarization method

Stern-Geary method

Stern-Geary relation

Stern-Gerlach

Stern-Gerlach apparatus

Stern-Gerlach deflection experiment

Stern-Gerlach experiment

Stern-Gerlach machine

Stern-Gerlach magnet

Stern-Gerlach method

Stern-Gerlach technique

Stern-Gouy-Chapman theory

Stern-Graham equation

Stern-Graham model

Stern-Grahame double layer model

Stern-Grahame model

Stern-Helmholtz layer

Stern-Helmholtz model

Stern-Langmuir equation

Stern-Lindemann formulation

Stern-Makrides washer

Stern-Vollmer

Stern-Vollmer plot

Stern-Volmer

Stern-Volmer analyses

Stern-Volmer behavior

Stern-Volmer constant

Stern-Volmer constants, quenching fluorescence

Stern-Volmer equation

Stern-Volmer expression

Stern-Volmer expression plotting

Stern-Volmer graphs

Stern-Volmer kinetics

Stern-Volmer law

Stern-Volmer mechanism

Stern-Volmer plot

Stern-Volmer plot emission

Stern-Volmer product quenching

Stern-Volmer product quenching studies

Stern-Volmer quenching

Stern-Volmer quenching constant

Stern-Volmer quenching curves

Stern-Volmer quenching rates

Stern-Volmer relation

Stern-Volmer relationship

Stern-Volmer, oxygen

Stern-Volraer

Sterne

Sterne

Sterne, Laurence

Sterne, Laurence Tristram Shandy

Stern’s layer

Stewart, Stern

The Aconitum and Delphinium, Alkaloids by E. S. Stern

The Diterpenoid Alkaloids from Aconitum, Delphinium, and Garrya Species by E. S. Stern

The Gouy-Chapman-Stern model

The Stern layer

The Stern-Gerlach Experiment

The Stern-Volmer Equation for Determination of Quenching Rate

Wilkinson, Ronald Sterne

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