An introduction to interfaces & colloids: the bridge to nanoscience
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| Sprache: | English |
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World Scientific
2010
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| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | Hier auch später erschienene, unveränderte Nachdrucke. |
| Beschreibung: | XVIII, 785 S. Ill., graph. Darst. |
| ISBN: | 9814299820 9789814299824 9789814293075 9814293075 |
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MARC
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| 020 | |a 9789814299824 |c pbk |9 978-981-4299-82-4 | ||
| 020 | |a 9789814293075 |c hbk |9 978-981-4293-07-5 | ||
| 020 | |a 9814293075 |9 981-4293-07-5 | ||
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| 084 | |a CHE 180f |2 stub | ||
| 100 | 1 | |a Berg, John C. |d ca. 20./21. Jhr. |e Verfasser |0 (DE-588)1280171286 |4 aut | |
| 245 | 1 | 0 | |a An introduction to interfaces & colloids |b the bridge to nanoscience |c John C. Berg |
| 264 | 1 | |a Singapore |b World Scientific |c 2010 | |
| 300 | |a XVIII, 785 S. |b Ill., graph. Darst. | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 500 | |a Hier auch später erschienene, unveränderte Nachdrucke. | ||
| 650 | 4 | |a Interfaces (Physical sciences) | |
| 650 | 4 | |a Colloids | |
| 650 | 4 | |a Nanoscience | |
| 650 | 4 | |a Colloids | |
| 650 | 4 | |a Interfaces (Physical sciences) | |
| 650 | 4 | |a Nanoscience | |
| 650 | 0 | 7 | |a Oberflächenphysik |0 (DE-588)4134881-3 |2 gnd |9 rswk-swf |
| 650 | 0 | 7 | |a Oberflächenchemie |0 (DE-588)4126166-5 |2 gnd |9 rswk-swf |
| 650 | 0 | 7 | |a Physikalisch-chemische Eigenschaft |0 (DE-588)4369521-8 |2 gnd |9 rswk-swf |
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| 856 | 4 | 2 | |m Digitalisierung UB Bayreuth |q application/pdf |u http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=020209796&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |3 Inhaltsverzeichnis |
| 999 | |a oai:aleph.bib-bvb.de:BVB01-020209796 | ||
Datensatz im Suchindex
| _version_ | 1804142798524383232 |
|---|---|
| adam_text | CONTENTS
Preface vii
I. INTRODUCTION
1
A. Interfaces
1
B.
Colloids
4
C.
The bridge to nanoscience
10
1. What is nanoscience?
10
2.
Nanostructures and assemblies
12
3.
Generic nanoscience
17
4.
New tools of generic nanoscience
18
5.
The plan
22
II. FLUID INTERFACES AND CAPILLARITY
23
A. Fluid interfaces: Young s membrane model
23
1.
The thinness of interfaces
23
2.
Definition of surface tension
25
B. The surface tension of liquids
26
1.
Pure liquids
26
2.
Temperature dependence of surface tension
27
3.
Surface tension of solutions
29
C. Intermolecular forces and the origin of surface tension
31
1.
Van
der Waals
forces
31
2.
Surface tension as unbalanced intermolecular forces
;
the
Hamaker
constant
35
3.
Pressure deficit in the
interfacial
layer;
Bakker
s
equation
37
4.
Components of the surface tension
41
D. Interfacial
tension
43
1.
Experimental
interfacial
tension
43
2.
Combining rules for
interfacial
tension
43
E. Dynamic surface tension
46
F. Capillary hydrostatics: the Young-Laplace Equation
46
1.
Capillary pressure: pressure jump across a curved fluid
interface
46
2.
The curvature of a surface
48
3.
Derivation of the Young-Laplace equation
53
4.
Boundary conditions for the Young-Laplace equation
55
G. Some solutions to the Young-Laplace equation
57
1.
Cylindrical surfaces; meniscus against a flat plate
57
2.
Axisymmetric and other surfaces
59
x
CONTENTS
3. Nondimensionalization
of the Young-Laplace equation;
the Bond number
59
4.
Saddle-shaped surfaces
62
H. The measurement of surface and
interfacial
tension
64
1.
Geometric vs. force methods
64
2.
Capillary rise
65
3.
Sessile drop and pendant drop
68
4. Du Noüy
ring detachment
68
5.
Wilhelmy slide
69
6.
Langmuir film balance
70
7.
Drop weight (or volume)
71
8.
Maximum bubble pressure and dynamic surface tension
72
9.
The pulsating bubble
surfactometer
74
10.
Elliptical (vibrating) jet
74
11.
Contracting circular jet
75
12.
Problems with
interfacial
tension measurement
75
13.
Spinning drop method
76
I. Forces on solids in contact with liquids: capillary interactions
76
1.
Liquid bridges
76
2.
Shared menisci
80
J. Effect of curvature on the equilibrium properties of bulk
liquids: the Kelvin Effect
84
1.
The vapor pressure of small droplets and liquids in pores
84
2.
The effect of curvature on boiling point
86
3.
Capillary condensation
86
4.
Nucleation
88
K. Thin liquid films
91
1.
Disjoining pressure and its measurement
91
2.
The molecular origin of disjoining pressure
94
3.
The disjoining pressure isotherm
98
4.
The augmented Young-Laplace equation
101
SOME FUN THINGS TO DO: CHAPTER
2 103
III. THERMODYNAMICS OF
INTERFACIAL
SYSTEMS
107
A. The thermodynamics of simple bulk systems
107
l.Thermodynamic concepts
107
2.
The simple compressible system
108
B. The simple capillary system
110
1.
The work of extension
110
2.
Heat effects; abstract properties
;
definition of
boundary tension 111
C. Extension to fluid-solid
interfacial
systems
114
1.
The work of area extension in fluid-solid systems
114
2.
Compound
interfacial
systems; Young s equation
116
D. Multicomponent interfacial
systems
119
1.
The Gibbs dividing surface and adsorption
119
CONTENTS xi
2.
Immiscible
interfacial
systems
123
3.
The measurement of adsorption
124
4.
The phase rule; descriptive equations for binary
interfacial
systems
127
E. The Gibbs adsorption equation
128
F. Surface tension of solutions
134
1.
Ideal-dilute capillary systems
134
2.
Moderately dilute capillary systems
135
G. Surface active agents (surfactants) and their solutions
137
1.
The structure of different types of surface active agents
137
2.
Solutions of non-electrolyte surfactants
144
3.
Solutions of electrolyte surfactants
147
H. Self-assembly of surfactant monomers in solution
148
1.
Formation of micelles: critical micelle concentration (CMC)
148
2.
Solubilization
160
I. Micelle morphology, other self-assembled structures, and
concentrated surfactant solutions
164
1.
Micellar shape and the Critical Packing Parameter (CPP)
164
2.
Beyond micelles: other self-assembled structures
166
3.
Concentrated surfactant solutions; liquid crystalline
mesophases
170
4.
Kinetics of micellization and other self-assembly processes
171
J. Dynamic surface tension of surfactant solutions
171
1.
Diffusion-controlled adsorption
171
2.
Finite adsorption-desorption kinetics
175
K. Insoluble (Langmuir) monolayers
176
1.
Formation of monolayers by spontaneous spreading
176
2.
Hydrodynamic consequences of monolayers:
Gibbs elasticity
177
3.
π-Α
isotherms of insoluble monolayers
178
4.
Langmuir-Blodgett films
182
5.
Transport properties of monolayers
184
L. The thermodynamics of fluid-solid
interfacial
systems revisited
186
1.
The concept of
interfacial
energy and its measurement in
fluid-solid systems
186
2.
Adsorption of non-polymeric molecules at the solid-liquid
interface
191
3.
Experimental measurement of small molecule solid-liquid
adsorption
201
4.
Adsorption of polymers at the solid-liquid interface
202
SOME FUN THINGS TO DO: CHAPTER
3 207
IV. SOLID-LIQUID INTERACTIONS
214
A. Wettability and the contact angle: Young s Equation
214
1.
Importance of wetting; definition of contact angle
214
xii CONTENTS
2.
Young s equation revisited; classification of wetting and
contact angle values
216
B. Contact angle hysteresis
218
1.
Origins of hysteresis: roughness and heterogeneity
218
2.
Complexity of real surfaces: texture and scale
221
3. Wenzel
equation for rough surfaces
223
4.
Cassie-Baxter analysis of heterogeneous surfaces;
composite surfaces and ultra-hydrophobicity
224
5.
The dynamic contact angle; Tanner s law
227
C. Methods for measuring the contact angle
229
1.
Optical or profile methods: contact angle goniometry
229
2.
Force methods: contact angle tensiometry
231
3.
Dynamic contact angle measurement
235
D. Relation of wetting behavior to surface chemical constitution
236
1.
Zisman plots; the critical surface tension
236
2.
The wettability series
238
3.
Estimates of surface energies from contact angle data
or vice versa
239
4.
Thermodynamics of solid-liquid contact: work of adhesion,
work of wetting and work of spreading; the
Young-Dupré
equation
243
5.
The promotion or retardation of wetting: practical
strategies
245
E. Spreading of liquids on solid surfaces
250
1. Criteria for spontaneous spreading; spreading morphology
250
2.
Temperature effects of wetting; heats of immersion and
wetting transitions
254
3.
The kinetics of spreading on smooth surfaces
255
4.
Spreading agents; superspreaders
257
F. The relationship of wetting and spreading behavior to adhesion
258
1.
Definition of adhesion; adhesion mechanisms
258
2.
The Laws of Molecular Adhesion
259
3.
Practicaladhesion vs. thermodynamic adhesion
261
4.
The importance of wetting (contact angle) to practical
adhesion
263
5.
The optimization of thermodynamic contact adhesion
264
6.
Acid-base effects in adhesion
267
7.
Contact mechanics; the JKR method
272
G. Heterogeneous nucleation
277
H. Processes based on wettability changes or differences
279
1.
Detergency
279
2.
Flotation
280
3.
Selective or spherical agglomeration
281
4.
Offset lithographic printing
282
I. Wicking flows (capillary action) and absorbency
284
1.
Wicking into a single capillary tube
284
CONTENTS xiii
2. Wicking in
porous media
286
3.
Practical strategies for promoting absorbency
290
4.
Immiscible displacement
292
5.
Mercury
porosimitry
292
6.
Motion of liquid threads
293
7.
Surface wicking; spreading over rough or porous surfaces
295
J. Particles at interfaces
297
1.
Particles at solid-fluid interfaces: effects on wetting and
spreading
297
2.
The disposition of particles at fluid interfaces
297
3.
Particle-assisted wetting
299
4.
Pickering emulsions
303
5.
Armored bubbles and liquid marbles
305
6.
Janus particles and nanoparticles at fluid interfaces
306
K. The description of solid surfaces
309
1.
Solid surface roughness
309
2.
Fractal surfaces
310
3.
Surface texture
ЗІЗ
4.
Measurement of surface roughness and texture by stylus
profilometry
314
L. Optical techniques for surface characterization
315
1.
Optical microscopy
315
2.
Optical profilometry
318
3.
Confocal microscopy
318
4.
Electron microscopy
319
5.
Near-field scanning optical microscopy (NSOM)
320
M. Scanning probe microscopy (SPM)
321
1.
Scanning Tunneling Microscopy (STM)
322
2.
Atomic Force Microscopy (AFM)
324
N.
Surface area of powders, pore size distribution
331
O. Energetic characterization of solid surfaces: Inverse Gas
Chromatography (IGC)
333
SOME FUN THINGS TO DO: CHAPTER
4 338
V. COLLOIDAL SYSTEMS: PHENOMENOLOGY AND
CHARACTERIZATION
345
A. Preliminaries
345
1.
Definition and classification of colloids
345
2.
General properties of colloidal dispersions
346
3.
Dense vs. dilute dispersions
349
B. Mechanisms of lyophobic colloid instability
351
1.
Phase segregation: the phoretic processes
351
2.
Thermodynamic criteria for stability
353
3.
Aggregation
353
4.
Coalescence
355
5.
Particle size disproportionation
356
xiv CONTENTS
C.
Preparation of colloid particles and colloidal dispersions
358
{.Classification of preparation strategies for lyophobic
colloids
358
2.
Top-down strategies
360
3.
Bottom-up strategies
365
D. Morphology of colloids: particle size, size distribution, and
particle shape
371
1.
Description of particle size distributions
371
2.
Distributions based on different size variables and
weighting factors
375
3.
Normal (Gaussian) and log-normal distributions
379
4.
Particle shape
382
E. Sedimentation and centrifugation
387
1.
Individual particle settling: Stokes
law
387
2.
Multi-particle, wall and charge effects on sedimentation
389
3.
Differential sedimentation; particle size analysis
391
4.
Centrifugation
395
F. Brownian motion; sedimentation-diffusion equilibrium
397
1.
Kinetic theory and diffusion
397
2.
Brownian motion
399
3.
Sedimentation (centrifugation)
-
diffusion equilibrium
403
4.
Practical retrospective regarding sedimentation and
other phoretic processes
407
G. Measurement of particle size and size distribution: overview
409
1.
Classification of methods
409
2.
Microscopy
410
H. Light scattering
413
1.
Classical (static) light scattering
413
2.
Rayleigh scattering
414
3.
Turbidity
418
4. Rayleigh-Gans-Debye (RGD)
scattering
421
5.
Mie
scattering
427
6. Fraunhofer
diffraction; laser diffraction
429
7.
Inelastic scattering: absorbance; the Raman effect
431
8.
Scattering from denser dispersions
436
9.
Dynamic Light Scattering (Photon Correlation
Spectroscopy)
437
10.
Dynamic light scattering from denser dispersions
442
I. Aperture,
Chromatographie
and acoustic methods for
particle sizing
444
1.
Aperture (one-at-a-time) methods
444
2. Chromatographie
methods
446
3.
Acoustic methods
448
SOME FUN THINGS TO DO: CHAPTER
5 450
CONTENTS xv
VI. ELECTRICAL PROPERTIES OF INTERFACES
455
A. Origin of charge separation at interfaces
455
1.
Overview
455
2.
Preferential adsorptionldesorption of lattice ions
456
3.
Specific adsorption of charged species
459
4.
Ionization of surface functional groups
460
5.
Isomorphic substitution
461
6.
Accumulation/depletion of electrons
462
7.
Interface charging in non-aqueous systems
463
B. Electric double layer formation and structure
466
1.
The Helmholtz model; electrostatic units
466
2.
The Gouy-Chapman model; Poisson-Boltzmann equation
467
3.
Boundary conditions to the Poisson-Boltzmann equation
475
4.
Double layers at spherical and cylindrical surfaces All
5.
The free energy of double layer formation
478
6.
The Stern model; structure of the inner part of the
double layer
480
7.
The mercury solution interface; electrocapillarity and
refinements to the double layer model
483
8.
Oriented dipoles at the interface: the
χ
-potential
485
С
Electrostatic characterization of colloids by titration methods
487
1.
Colloid titrations
487
2.
Potentiometric titrations
488
3.
Conductometric titrations
492
4.
Donnan
equilibrium and the suspension effect
493
D. Electrokinetics
496
1.
The electrokinetic phenomena
496
2.
The
zeta
potential and its interpretation
500
3.
Electrokinetic measurements; micro-electrophoresis
503
4.
Relationship of
zeta
potential to electrophoretic mobility
508
5.
Electrokinetic titrations
512
6.
Electro-acoustic measurements
514
E. Dielectrophoresis and optical trapping
516
. Dielectrophoresis
516
2.
Electrorotation and traveling wave dielectrophoresis
519
3.
Optical trapping; laser tweezers
520
SOME FUN THINGS TO DO: CHAPTER
6 523
VII.
INTERACTION BETWEEN COLLOID PARTICLES
525
A. Overview and rationale
525
B. Long-range van
der Waals
interactions
526
1.
The
Hamaker
(microscopic) approach
526
2.
Retardation
530
3.
The Lifshitz (macroscopic) approach
532
4.
Measurement of
Hamaker
constants
535
C. Electrostatic interactions; DLVO theory
540
xvi CONTENTS
1.
Electrostatic
repulsion between charged flat plates
540
2.
Electrostatic interactions between curved surfaces;
the Derjaguin approximation
544
3.
DLVO theory: electrocratic dispersions
547
4.
Jar testing, the Schulze-Hardy rule and agreement
with theory
552
5.
The
Hofmeister
series; ion speciation and ionic
specific adsorption
554
6.
Repeptization
556
7.
Interaction between dissimilar surfaces:
hetero-aggre gation
558
D.
Kinetics of aggregation
560
1.
Classification of aggregation rate processes and
nomenclature
560
2.
Smoluchowski theory of diffusion-limited aggregation
561
3.
The hydrodynamic drainage effect
566
4.
Orthokinetic (shear flow induced) aggregation
568
5.
Reaction-limited (slow) aggregation; the stability ratio
W
569
6.
Secondary minimum effects
571
7.
Kinetics of hetero-aggregation
573
8.
Measurement of early-stage aggregation kinetics (W)
574
9.
Surface aggregation
577
10.
Electrostatic stabilization and aggregation rates in
apoiar
media
579
E. Steric stabilization and other colloid-polymer interactions
582
1.
Polymer adsorption and steric stabilization
582
2.
Thermodynamic considerations: enthalpic vs.
entropie
effects
585
3.
Fischer theory
587
4.
Steric repulsion plotted on DLVO coordinates
591
5.
Electro-steric stabilization
595
6.
Bridging flocculation
596
7.
Depletion flocculation
597
8.
Electrophoretic displays; electronic paper
599
F. The kinetics (and thermodynamics) of flocculation
601
G. Other non-DLVO interaction forces
603
H. Aggregate structure evolution; fractal aggregates
607
1.
Stages of the aggregation process
607
2.
Fractal aggregates
608
3.
The effect of particle size on aggregation phenomena;
coating by nanoparticles
612
SOME FUN THINGS TO DO: CHAPTER
7 613
CONTENTS xvii
VIII.
RHEOLOGY OF
DISPERSIONS
616
A.
Rheology: scope and definitions
616
B.
Viscometry
617
1.
Newton s law of viscosity
617
2.
Measurement of viscosity
618
C. The viscosity of colloidal dispersions
622
1.
Dilute dispersions; Einstein theory
622
2.
Denser dispersions of non-interacting particles
623
3.
Dilute dispersions of non-spherical particles
625
D. Non-Newtonian rheology
626
1.
General viscous behavior of dispersions of non-interacting
particulates
626
2.
Fluids with a yield stress
630
3.
Time-dependent rheology
632
4.
Viscoelasticity
633
E. Electroviscous effects
637
SOME FUN THINGS TO DO: CHAPTER
8 640
IX. EMULSIONS AND FOAMS
643
A. General consideration of emulsions
643
1.
Classification of emulsions
643
2.
Emulsifiers and emulsion stability
644
3.
Thermodynamics of emulsification/breakdown
649
A. Preparation of emulsions
651
B. O/W or W/O emulsions?
652
1.
Rules of thumb
652
2.
The hydrophile-lipophile balance (HLB) and related scales
654
3.
Double (or multiple) emulsions
659
C. Application of emulsions
661
1.
Formation/breaking in situ
661
2.
Demulsification
663
D. Microemulsions
664
1.
Distinction between microemulsions and macro emulsions
664
2.
Phase behavior of microemulsion systems
666
3.
Ultra-low
interfacial
tension
671
4.
Interfacial
film properties in microemulsion systems
672
.
E. General consideration of foams
673
1.
Nature and preparation of foams
673
2.
Stages in foam lifetime
675
3.
Stability mechanisms
676
4.
Foam behavior and foaming agents
681
5.
Antifoam action
684
6.
Froth flotation
686
xviii CONTENTS
7.
Foaming in non-aqueous media; general surface activity
near a phase split
687
SOME FUN THINGS TO DO: CHAPTER
9 691
X.
INTERFACIAL
HYDRODYNAMICS
695
A. Unbalanced forces at fluid interfaces
695
1.
Unbalanced normal forces
695
2.
Tangential force imbalances: the
Marangoni
effect
696
3.
Boundary conditions at
afluid
interface
702
B. Examples of
Interfacial
Hydrodynamic Flows
705
1.
The breakup of capillary jets
705
2.
Steady thermocapillary flow
712
3.
The motion of bubbles or drops in a temperature gradient
714
4.
Marangoni
instability in a shallow liquid
pool-Bénard
cells
718
C. Some Practical Implications of the
Marangoni
Effect
728
1.
Marangoni
effects on mass transfer
728
2.
Marangoni
drying
732
3.
Marangoni
patterning
733
D. The Effect of Surface Active Agents
735
1.
Gibbs elasticity
735
2.
The boundary conditions describing the effects
of surfactants
1Ъ1
3.
The effect of surfactants on bubble or droplet circulation
740
4.
The effect of surfactants on the stability of a pool heated
from below
745
SOME FUN THINGS TO DO: CHAPTER
10 748
Appendix
1:
EXERCISES
753
Appendix
2:
THE TOP TEN
767
Appendix
3:
OTHER SOURCES
771
Index
773
|
| any_adam_object | 1 |
| author | Berg, John C. ca. 20./21. Jhr |
| author_GND | (DE-588)1280171286 |
| author_facet | Berg, John C. ca. 20./21. Jhr |
| author_role | aut |
| author_sort | Berg, John C. ca. 20./21. Jhr |
| author_variant | j c b jc jcb |
| building | Verbundindex |
| bvnumber | BV036127422 |
| callnumber-first | Q - Science |
| callnumber-label | QD506 |
| callnumber-raw | QD506 |
| callnumber-search | QD506 |
| callnumber-sort | QD 3506 |
| callnumber-subject | QD - Chemistry |
| classification_rvk | UP 7500 VE 7000 |
| classification_tum | CHE 180f |
| ctrlnum | (OCoLC)498932462 (DE-599)BVBBV036127422 |
| dewey-full | 541/.345 |
| dewey-hundreds | 500 - Natural sciences and mathematics |
| dewey-ones | 541 - Physical chemistry |
| dewey-raw | 541/.345 |
| dewey-search | 541/.345 |
| dewey-sort | 3541 3345 |
| dewey-tens | 540 - Chemistry and allied sciences |
| discipline | Chemie / Pharmazie Physik Chemie |
| format | Book |
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| id | DE-604.BV036127422 |
| illustrated | Illustrated |
| indexdate | 2024-07-09T22:37:30Z |
| institution | BVB |
| isbn | 9814299820 9789814299824 9789814293075 9814293075 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-020209796 |
| oclc_num | 498932462 |
| open_access_boolean | |
| owner | DE-29T DE-355 DE-BY-UBR DE-91G DE-BY-TUM DE-19 DE-BY-UBM DE-92 DE-20 |
| owner_facet | DE-29T DE-355 DE-BY-UBR DE-91G DE-BY-TUM DE-19 DE-BY-UBM DE-92 DE-20 |
| physical | XVIII, 785 S. Ill., graph. Darst. |
| publishDate | 2010 |
| publishDateSearch | 2010 |
| publishDateSort | 2010 |
| publisher | World Scientific |
| record_format | marc |
| spelling | Berg, John C. ca. 20./21. Jhr. Verfasser (DE-588)1280171286 aut An introduction to interfaces & colloids the bridge to nanoscience John C. Berg Singapore World Scientific 2010 XVIII, 785 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Hier auch später erschienene, unveränderte Nachdrucke. Interfaces (Physical sciences) Colloids Nanoscience Oberflächenphysik (DE-588)4134881-3 gnd rswk-swf Oberflächenchemie (DE-588)4126166-5 gnd rswk-swf Physikalisch-chemische Eigenschaft (DE-588)4369521-8 gnd rswk-swf Oberflächenchemie (DE-588)4126166-5 s Physikalisch-chemische Eigenschaft (DE-588)4369521-8 s DE-604 Oberflächenphysik (DE-588)4134881-3 s Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=020209796&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Berg, John C. ca. 20./21. Jhr An introduction to interfaces & colloids the bridge to nanoscience Interfaces (Physical sciences) Colloids Nanoscience Oberflächenphysik (DE-588)4134881-3 gnd Oberflächenchemie (DE-588)4126166-5 gnd Physikalisch-chemische Eigenschaft (DE-588)4369521-8 gnd |
| subject_GND | (DE-588)4134881-3 (DE-588)4126166-5 (DE-588)4369521-8 |
| title | An introduction to interfaces & colloids the bridge to nanoscience |
| title_auth | An introduction to interfaces & colloids the bridge to nanoscience |
| title_exact_search | An introduction to interfaces & colloids the bridge to nanoscience |
| title_full | An introduction to interfaces & colloids the bridge to nanoscience John C. Berg |
| title_fullStr | An introduction to interfaces & colloids the bridge to nanoscience John C. Berg |
| title_full_unstemmed | An introduction to interfaces & colloids the bridge to nanoscience John C. Berg |
| title_short | An introduction to interfaces & colloids |
| title_sort | an introduction to interfaces colloids the bridge to nanoscience |
| title_sub | the bridge to nanoscience |
| topic | Interfaces (Physical sciences) Colloids Nanoscience Oberflächenphysik (DE-588)4134881-3 gnd Oberflächenchemie (DE-588)4126166-5 gnd Physikalisch-chemische Eigenschaft (DE-588)4369521-8 gnd |
| topic_facet | Interfaces (Physical sciences) Colloids Nanoscience Oberflächenphysik Oberflächenchemie Physikalisch-chemische Eigenschaft |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=020209796&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
| work_keys_str_mv | AT bergjohnc anintroductiontointerfacescolloidsthebridgetonanoscience |