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Surface science

January 01, 1970

For the journal, see Surface Science (journal).

Surface science is the study of physical and chemical phenomena that occur at the interface of two phases, including solidliquid interfaces, solid–gas interfaces, solid–vacuum interfaces, and liquidgas interfaces. It includes the fields of surface chemistry and surface physics.[1] Some related practical applications are classed as surface engineering. The science encompasses concepts such as heterogeneous catalysis, semiconductor device fabrication, fuel cells, self-assembled monolayers, and adhesives. Surface science is closely related to interface and colloid science.[2] Interfacial chemistry and physics are common subjects for both. The methods are different. In addition, interface and colloid science studies macroscopic phenomena that occur in heterogeneous systems due to peculiarities of interfaces.

STM image of a quinacridone adsorbate. The self-assembled supramolecular chains of the organic semiconductor are adsorbed on a graphite surface.

History edit

The field of surface chemistry started with heterogeneous catalysis pioneered by Paul Sabatier on hydrogenation and Fritz Haber on the Haber process.[3] Irving Langmuir was also one of the founders of this field, and the scientific journal on surface science, Langmuir, bears his name. The Langmuir adsorption equation is used to model monolayer adsorption where all surface adsorption sites have the same affinity for the adsorbing species and do not interact with each other. Gerhard Ertl in 1974 described for the first time the adsorption of hydrogen on a palladium surface using a novel technique called LEED.[4] Similar studies with platinum,[5] nickel,[6][7] and iron[8] followed. Most recent developments in surface sciences include the 2007 Nobel prize of Chemistry winner Gerhard Ertl's advancements in surface chemistry, specifically his investigation of the interaction between carbon monoxide molecules and platinum surfaces.

Chemistry edit

Surface chemistry can be roughly defined as the study of chemical reactions at interfaces. It is closely related to surface engineering, which aims at modifying the chemical composition of a surface by incorporation of selected elements or functional groups that produce various desired effects or improvements in the properties of the surface or interface. Surface science is of particular importance to the fields of heterogeneous catalysis, electrochemistry, and geochemistry.

Catalysis edit

The adhesion of gas or liquid molecules to the surface is known as adsorption. This can be due to either chemisorption or physisorption, and the strength of molecular adsorption to a catalyst surface is critically important to the catalyst's performance (see Sabatier principle). However, it is difficult to study these phenomena in real catalyst particles, which have complex structures. Instead, well-defined single crystal surfaces of catalytically active materials such as platinum are often used as model catalysts. Multi-component materials systems are used to study interactions between catalytically active metal particles and supporting oxides; these are produced by growing ultra-thin films or particles on a single crystal surface.[9]

Relationships between the composition, structure, and chemical behavior of these surfaces are studied using ultra-high vacuum techniques, including adsorption and temperature-programmed desorption of molecules, scanning tunneling microscopy, low energy electron diffraction, and Auger electron spectroscopy. Results can be fed into chemical models or used toward the rational design of new catalysts. Reaction mechanisms can also be clarified due to the atomic-scale precision of surface science measurements.[10]

Electrochemistry edit

Electrochemistry is the study of processes driven through an applied potential at a solid-liquid or liquid-liquid interface. The behavior of an electrode-electrolyte interface is affected by the distribution of ions in the liquid phase next to the interface forming the electrical double layer. Adsorption and desorption events can be studied at atomically flat single crystal surfaces as a function of applied potential, time, and solution conditions using spectroscopy, scanning probe microscopy[11] and surface X-ray scattering.[12][13] These studies link traditional electrochemical techniques such as cyclic voltammetry to direct observations of interfacial processes.

Geochemistry edit

Geologic phenomena such as iron cycling and soil contamination are controlled by the interfaces between minerals and their environment. The atomic-scale structure and chemical properties of mineral-solution interfaces are studied using in situ synchrotron X-ray techniques such as X-ray reflectivity, X-ray standing waves, and X-ray absorption spectroscopy as well as scanning probe microscopy. For example, studies of heavy metal or actinide adsorption onto mineral surfaces reveal molecular-scale details of adsorption, enabling more accurate predictions of how these contaminants travel through soils[14] or disrupt natural dissolution-precipitation cycles.[15]

Physics edit

Surface physics can be roughly defined as the study of physical interactions that occur at interfaces. It overlaps with surface chemistry. Some of the topics investigated in surface physics include friction, surface states, surface diffusion, surface reconstruction, surface phonons and plasmons, epitaxy, the emission and tunneling of electrons, spintronics, and the self-assembly of nanostructures on surfaces. Techniques to investigate processes at surfaces include surface X-ray scattering, scanning probe microscopy, surface-enhanced Raman spectroscopy and X-ray photoelectron spectroscopy.

Analysis techniques edit

The study and analysis of surfaces involves both physical and chemical analysis techniques.

Several modern methods probe the topmost 1–10 nm of surfaces exposed to vacuum. These include angle-resolved photoemission spectroscopy (ARPES), X-ray photoelectron spectroscopy (XPS), Auger electron spectroscopy (AES), low-energy electron diffraction (LEED), electron energy loss spectroscopy (EELS), thermal desorption spectroscopy (TPD), ion scattering spectroscopy (ISS), secondary ion mass spectrometry, dual-polarization interferometry, and other surface analysis methods included in the list of materials analysis methods. Many of these techniques require vacuum as they rely on the detection of electrons or ions emitted from the surface under study. Moreover, in general ultra-high vacuum, in the range of 10−7 pascal pressure or better, it is necessary to reduce surface contamination by residual gas, by reducing the number of molecules reaching the sample over a given time period. At 0.1 mPa (10−6 torr) partial pressure of a contaminant and standard temperature, it only takes on the order of 1 second to cover a surface with a one-to-one monolayer of contaminant to surface atoms, so much lower pressures are needed for measurements. This is found by an order of magnitude estimate for the (number) specific surface area of materials and the impingement rate formula from the kinetic theory of gases.

Purely optical techniques can be used to study interfaces under a wide variety of conditions. Reflection-absorption infrared, dual polarisation interferometry, surface-enhanced Raman spectroscopy and sum frequency generation spectroscopy can be used to probe solid–vacuum as well as solid–gas, solid–liquid, and liquid–gas surfaces. Multi-parametric surface plasmon resonance works in solid–gas, solid–liquid, liquid–gas surfaces and can detect even sub-nanometer layers.[16] It probes the interaction kinetics as well as dynamic structural changes such as liposome collapse[17] or swelling of layers in different pH. Dual-polarization interferometry is used to quantify the order and disruption in birefringent thin films.[18] This has been used, for example, to study the formation of lipid bilayers and their interaction with membrane proteins.

Acoustic techniques, such as Quartz Crystal Microbalance with dissipation monitoring, is used for time-resolved measurements of solid-vacuum, solid-gas and solid-liquid interfaces. The method allows for analysis of molecule-surface interactions as well as structural changes and viscoelastic properties of the adlayer.  

X-ray scattering and spectroscopy techniques are also used to characterize surfaces and interfaces. While some of these measurements can be performed using laboratory X-ray sources, many require the high intensity and energy tunability of synchrotron radiation. X-ray crystal truncation rods (CTR) and X-ray standing wave (XSW) measurements probe changes in surface and adsorbate structures with sub-Ångström resolution. Surface-extended X-ray absorption fine structure (SEXAFS) measurements reveal the coordination structure and chemical state of adsorbates. Grazing-incidence small angle X-ray scattering (GISAXS) yields the size, shape, and orientation of nanoparticles on surfaces.[19] The crystal structure and texture of thin films can be investigated using grazing-incidence X-ray diffraction (GIXD, GIXRD).

X-ray photoelectron spectroscopy (XPS) is a standard tool for measuring the chemical states of surface species and for detecting the presence of surface contamination. Surface sensitivity is achieved by detecting photoelectrons with kinetic energies of about 10-1000 eV, which have corresponding inelastic mean free paths of only a few nanometers. This technique has been extended to operate at near-ambient pressures (ambient pressure XPS, AP-XPS) to probe more realistic gas-solid and liquid-solid interfaces.[20] Performing XPS with hard X-rays at synchrotron light sources yields photoelectrons with kinetic energies of several keV (hard X-ray photoelectron spectroscopy, HAXPES), enabling access to chemical information from buried interfaces.[21]

Modern physical analysis methods include scanning-tunneling microscopy (STM) and a family of methods descended from it, including atomic force microscopy (AFM). These microscopies have considerably increased the ability and desire of surface scientists to measure the physical structure of many surfaces. For example, they make it possible to follow reactions at the solid–gas interface in real space, if those proceed on a time scale accessible by the instrument.[22][23]

See also edit

References edit

  1. ^ Prutton, Martin (1994). Introduction to Surface Physics. Oxford University Press. ISBN 978-0-19-853476-1.
  2. ^ Luklema, J. (1995–2005). Fundamentals of Interface and Colloid Science. Vol. 1–5. Academic Press.
  3. ^ Wennerström, Håkan; Lidin, Sven. "Scientific Background on the Nobel Prize in Chemistry 2007 Chemical Processes on Solid Surfaces" (PDF).
  4. ^ Conrad, H.; Ertl, G.; Latta, E.E. (February 1974). "Adsorption of hydrogen on palladium single crystal surfaces". Surface Science. 41 (2): 435–446. Bibcode:1974SurSc..41..435C. doi:10.1016/0039-6028(74)90060-0.
  5. ^ Christmann, K.; Ertl, G.; Pignet, T. (February 1976). "Adsorption of hydrogen on a Pt(111) surface". Surface Science. 54 (2): 365–392. Bibcode:1976SurSc..54..365C. doi:10.1016/0039-6028(76)90232-6.
  6. ^ Christmann, K.; Schober, O.; Ertl, G.; Neumann, M. (June 1, 1974). "Adsorption of hydrogen on nickel single crystal surfaces". The Journal of Chemical Physics. 60 (11): 4528–4540. Bibcode:1974JChPh..60.4528C. doi:10.1063/1.1680935.
  7. ^ Christmann, K.; Behm, R. J.; Ertl, G.; Van Hove, M. A.; Weinberg, W. H. (May 1, 1979). "Chemisorption geometry of hydrogen on Ni(111): Order and disorder". The Journal of Chemical Physics. 70 (9): 4168–4184. Bibcode:1979JChPh..70.4168C. doi:10.1063/1.438041.
  8. ^ Imbihl, R.; Behm, R. J.; Christmann, K.; Ertl, G.; Matsushima, T. (May 2, 1982). "Phase transitions of a two-dimensional chemisorbed system: H on Fe(110)". Surface Science. 117 (1): 257–266. Bibcode:1982SurSc.117..257I. doi:10.1016/0039-6028(82)90506-4.
  9. ^ Fischer-Wolfarth, Jan-Henrik; Farmer, Jason A.; Flores-Camacho, J. Manuel; Genest, Alexander; Yudanov, Ilya V.; Rösch, Notker; Campbell, Charles T.; Schauermann, Swetlana; Freund, Hans-Joachim (2010). "Particle-size dependent heats of adsorption of CO on supported Pd nanoparticles as measured with a single-crystal microcalorimeter". Physical Review B. 81 (24): 241416. Bibcode:2010PhRvB..81x1416F. doi:10.1103/PhysRevB.81.241416. hdl:11858/00-001M-0000-0011-29F8-F.
  10. ^ Lewandowski, M.; Groot, I.M.N.; Shaikhutdinov, S.; Freund, H.-J. (2012). "Scanning tunneling microscopy evidence for the Mars-van Krevelen type mechanism of low temperature CO oxidation on an FeO(111) film on Pt(111)". Catalysis Today. 181: 52–55. doi:10.1016/j.cattod.2011.08.033. hdl:11858/00-001M-0000-0010-50F9-9.
  11. ^ Gewirth, Andrew A.; Niece, Brian K. (1997). "Electrochemical Applications ofin Situ Scanning Probe Microscopy". Chemical Reviews. 97 (4): 1129–1162. doi:10.1021/cr960067y. PMID 11851445.
  12. ^ Nagy, Zoltán; You, Hoydoo (2002). "Applications of surface X-ray scattering to electrochemistry problems". Electrochimica Acta. 47 (19): 3037–3055. doi:10.1016/S0013-4686(02)00223-2.
  13. ^ Gründer, Yvonne; Lucas, Christopher A. (2016-11-01). "Surface X-ray diffraction studies of single crystal electrocatalysts". Nano Energy. 29: 378–393. doi:10.1016/j.nanoen.2016.05.043. ISSN 2211-2855.
  14. ^ Catalano, Jeffrey G.; Park, Changyong; Fenter, Paul; Zhang, Zhan (2008). "Simultaneous inner- and outer-sphere arsenate adsorption on corundum and hematite". Geochimica et Cosmochimica Acta. 72 (8): 1986–2004. Bibcode:2008GeCoA..72.1986C. doi:10.1016/j.gca.2008.02.013.
  15. ^ Xu, Man; Kovarik, Libor; Arey, Bruce W.; Felmy, Andrew R.; Rosso, Kevin M.; Kerisit, Sebastien (2014). "Kinetics and mechanisms of cadmium carbonate heteroepitaxial growth at the calcite surface". Geochimica et Cosmochimica Acta. 134: 221–233. doi:10.1016/j.gca.2013.11.036.
  16. ^ Jussila, Henri; Yang, He; Granqvist, Niko; Sun, Zhipei (5 February 2016). "Surface plasmon resonance for characterization of large-area atomic-layer graphene film". Optica. 3 (2): 151. Bibcode:2016Optic...3..151J. doi:10.1364/OPTICA.3.000151.
  17. ^ Granqvist, Niko; Yliperttula, Marjo; Välimäki, Salla; Pulkkinen, Petri; Tenhu, Heikki; Viitala, Tapani (18 March 2014). "Control of the Morphology of Lipid Layers by Substrate Surface Chemistry". Langmuir. 30 (10): 2799–2809. doi:10.1021/la4046622. PMID 24564782.
  18. ^ Mashaghi, A; Swann, M; Popplewell, J; Textor, M; Reimhult, E (2008). "Optical Anisotropy of Supported Lipid Structures Probed by Waveguide Spectroscopy and Its Application to Study of Supported Lipid Bilayer Formation Kinetics". Analytical Chemistry. 80 (10): 3666–76. doi:10.1021/ac800027s. PMID 18422336.
  19. ^ Renaud, Gilles; Lazzari, Rémi; Leroy, Frédéric (2009). "Probing surface and interface morphology with Grazing Incidence Small Angle X-Ray Scattering". Surface Science Reports. 64 (8): 255–380. Bibcode:2009SurSR..64..255R. doi:10.1016/j.surfrep.2009.07.002.
  20. ^ Bluhm, Hendrik; Hävecker, Michael; Knop-Gericke, Axel; Kiskinova, Maya; Schlögl, Robert; Salmeron, Miquel (2007). "In Situ X-Ray Photoelectron Spectroscopy Studies of Gas-Solid Interfaces at Near-Ambient Conditions". MRS Bulletin. 32 (12): 1022–1030. doi:10.1557/mrs2007.211. S2CID 55577979.
  21. ^ Sing, M.; Berner, G.; Goß, K.; Müller, A.; Ruff, A.; Wetscherek, A.; Thiel, S.; Mannhart, J.; Pauli, S. A.; Schneider, C. W.; Willmott, P. R.; Gorgoi, M.; Schäfers, F.; Claessen, R. (2009). "Profiling the Interface Electron Gas ofLaAlO3/SrTiO3Heterostructures with Hard X-Ray Photoelectron Spectroscopy". Physical Review Letters. 102 (17): 176805. arXiv:0809.1917. Bibcode:2009PhRvL.102q6805S. doi:10.1103/PhysRevLett.102.176805. PMID 19518810. S2CID 43739895.
  22. ^ Wintterlin, J.; Völkening, S.; Janssens, T. V. W.; Zambelli, T.; Ertl, G. (1997). "Atomic and Macroscopic Reaction Rates of a Surface-Catalyzed Reaction". Science. 278 (5345): 1931–4. Bibcode:1997Sci...278.1931W. doi:10.1126/science.278.5345.1931. PMID 9395392.
  23. ^ Waldmann, T.; et al. (2012). "Oxidation of an Organic Adlayer: A Bird's Eye View". Journal of the American Chemical Society. 134 (21): 8817–8822. doi:10.1021/ja302593v. PMID 22571820.

Further reading edit

  • Kolasinski, Kurt W. (2012-04-30). Surface Science: Foundations of Catalysis and Nanoscience (3 ed.). Wiley. ISBN 978-1119990352.
  • Attard, Gary; Barnes, Colin (January 1998). Surfaces. Oxford Chemistry Primers. ISBN 978-0198556862.

External links edit

 
Wikimedia Commons has media related to Surface science.
  • "Ram Rao Materials and Surface Science", a video from the Vega Science Trust
  • Surface Chemistry Discoveries
  • Surface Metrology Guide

January 01, 1970
surface, science, journal, surface, science, journal, study, physical, chemical, phenomena, that, occur, interface, phases, including, solid, liquid, interfaces, solid, interfaces, solid, vacuum, interfaces, liquid, interfaces, includes, fields, surface, chemi. For the journal see Surface Science journal Surface science is the study of physical and chemical phenomena that occur at the interface of two phases including solid liquid interfaces solid gas interfaces solid vacuum interfaces and liquid gas interfaces It includes the fields of surface chemistry and surface physics 1 Some related practical applications are classed as surface engineering The science encompasses concepts such as heterogeneous catalysis semiconductor device fabrication fuel cells self assembled monolayers and adhesives Surface science is closely related to interface and colloid science 2 Interfacial chemistry and physics are common subjects for both The methods are different In addition interface and colloid science studies macroscopic phenomena that occur in heterogeneous systems due to peculiarities of interfaces STM image of a quinacridone adsorbate The self assembled supramolecular chains of the organic semiconductor are adsorbed on a graphite surface Contents 1 History 2 Chemistry 2 1 Catalysis 2 2 Electrochemistry 2 3 Geochemistry 3 Physics 4 Analysis techniques 5 See also 6 References 7 Further reading 8 External linksHistory editThe field of surface chemistry started with heterogeneous catalysis pioneered by Paul Sabatier on hydrogenation and Fritz Haber on the Haber process 3 Irving Langmuir was also one of the founders of this field and the scientific journal on surface science Langmuir bears his name The Langmuir adsorption equation is used to model monolayer adsorption where all surface adsorption sites have the same affinity for the adsorbing species and do not interact with each other Gerhard Ertl in 1974 described for the first time the adsorption of hydrogen on a palladium surface using a novel technique called LEED 4 Similar studies with platinum 5 nickel 6 7 and iron 8 followed Most recent developments in surface sciences include the 2007 Nobel prize of Chemistry winner Gerhard Ertl s advancements in surface chemistry specifically his investigation of the interaction between carbon monoxide molecules and platinum surfaces Chemistry editSurface chemistry can be roughly defined as the study of chemical reactions at interfaces It is closely related to surface engineering which aims at modifying the chemical composition of a surface by incorporation of selected elements or functional groups that produce various desired effects or improvements in the properties of the surface or interface Surface science is of particular importance to the fields of heterogeneous catalysis electrochemistry and geochemistry Catalysis edit The adhesion of gas or liquid molecules to the surface is known as adsorption This can be due to either chemisorption or physisorption and the strength of molecular adsorption to a catalyst surface is critically important to the catalyst s performance see Sabatier principle However it is difficult to study these phenomena in real catalyst particles which have complex structures Instead well defined single crystal surfaces of catalytically active materials such as platinum are often used as model catalysts Multi component materials systems are used to study interactions between catalytically active metal particles and supporting oxides these are produced by growing ultra thin films or particles on a single crystal surface 9 Relationships between the composition structure and chemical behavior of these surfaces are studied using ultra high vacuum techniques including adsorption and temperature programmed desorption of molecules scanning tunneling microscopy low energy electron diffraction and Auger electron spectroscopy Results can be fed into chemical models or used toward the rational design of new catalysts Reaction mechanisms can also be clarified due to the atomic scale precision of surface science measurements 10 Electrochemistry edit Electrochemistry is the study of processes driven through an applied potential at a solid liquid or liquid liquid interface The behavior of an electrode electrolyte interface is affected by the distribution of ions in the liquid phase next to the interface forming the electrical double layer Adsorption and desorption events can be studied at atomically flat single crystal surfaces as a function of applied potential time and solution conditions using spectroscopy scanning probe microscopy 11 and surface X ray scattering 12 13 These studies link traditional electrochemical techniques such as cyclic voltammetry to direct observations of interfacial processes Geochemistry edit Geologic phenomena such as iron cycling and soil contamination are controlled by the interfaces between minerals and their environment The atomic scale structure and chemical properties of mineral solution interfaces are studied using in situ synchrotron X ray techniques such as X ray reflectivity X ray standing waves and X ray absorption spectroscopy as well as scanning probe microscopy For example studies of heavy metal or actinide adsorption onto mineral surfaces reveal molecular scale details of adsorption enabling more accurate predictions of how these contaminants travel through soils 14 or disrupt natural dissolution precipitation cycles 15 Physics editSurface physics can be roughly defined as the study of physical interactions that occur at interfaces It overlaps with surface chemistry Some of the topics investigated in surface physics include friction surface states surface diffusion surface reconstruction surface phonons and plasmons epitaxy the emission and tunneling of electrons spintronics and the self assembly of nanostructures on surfaces Techniques to investigate processes at surfaces include surface X ray scattering scanning probe microscopy surface enhanced Raman spectroscopy and X ray photoelectron spectroscopy Analysis techniques editThe study and analysis of surfaces involves both physical and chemical analysis techniques Several modern methods probe the topmost 1 10 nm of surfaces exposed to vacuum These include angle resolved photoemission spectroscopy ARPES X ray photoelectron spectroscopy XPS Auger electron spectroscopy AES low energy electron diffraction LEED electron energy loss spectroscopy EELS thermal desorption spectroscopy TPD ion scattering spectroscopy ISS secondary ion mass spectrometry dual polarization interferometry and other surface analysis methods included in the list of materials analysis methods Many of these techniques require vacuum as they rely on the detection of electrons or ions emitted from the surface under study Moreover in general ultra high vacuum in the range of 10 7 pascal pressure or better it is necessary to reduce surface contamination by residual gas by reducing the number of molecules reaching the sample over a given time period At 0 1 mPa 10 6 torr partial pressure of a contaminant and standard temperature it only takes on the order of 1 second to cover a surface with a one to one monolayer of contaminant to surface atoms so much lower pressures are needed for measurements This is found by an order of magnitude estimate for the number specific surface area of materials and the impingement rate formula from the kinetic theory of gases Purely optical techniques can be used to study interfaces under a wide variety of conditions Reflection absorption infrared dual polarisation interferometry surface enhanced Raman spectroscopy and sum frequency generation spectroscopy can be used to probe solid vacuum as well as solid gas solid liquid and liquid gas surfaces Multi parametric surface plasmon resonance works in solid gas solid liquid liquid gas surfaces and can detect even sub nanometer layers 16 It probes the interaction kinetics as well as dynamic structural changes such as liposome collapse 17 or swelling of layers in different pH Dual polarization interferometry is used to quantify the order and disruption in birefringent thin films 18 This has been used for example to study the formation of lipid bilayers and their interaction with membrane proteins Acoustic techniques such as Quartz Crystal Microbalance with dissipation monitoring is used for time resolved measurements of solid vacuum solid gas and solid liquid interfaces The method allows for analysis of molecule surface interactions as well as structural changes and viscoelastic properties of the adlayer X ray scattering and spectroscopy techniques are also used to characterize surfaces and interfaces While some of these measurements can be performed using laboratory X ray sources many require the high intensity and energy tunability of synchrotron radiation X ray crystal truncation rods CTR and X ray standing wave XSW measurements probe changes in surface and adsorbate structures with sub Angstrom resolution Surface extended X ray absorption fine structure SEXAFS measurements reveal the coordination structure and chemical state of adsorbates Grazing incidence small angle X ray scattering GISAXS yields the size shape and orientation of nanoparticles on surfaces 19 The crystal structure and texture of thin films can be investigated using grazing incidence X ray diffraction GIXD GIXRD X ray photoelectron spectroscopy XPS is a standard tool for measuring the chemical states of surface species and for detecting the presence of surface contamination Surface sensitivity is achieved by detecting photoelectrons with kinetic energies of about 10 1000 eV which have corresponding inelastic mean free paths of only a few nanometers This technique has been extended to operate at near ambient pressures ambient pressure XPS AP XPS to probe more realistic gas solid and liquid solid interfaces 20 Performing XPS with hard X rays at synchrotron light sources yields photoelectrons with kinetic energies of several keV hard X ray photoelectron spectroscopy HAXPES enabling access to chemical information from buried interfaces 21 Modern physical analysis methods include scanning tunneling microscopy STM and a family of methods descended from it including atomic force microscopy AFM These microscopies have considerably increased the ability and desire of surface scientists to measure the physical structure of many surfaces For example they make it possible to follow reactions at the solid gas interface in real space if those proceed on a time scale accessible by the instrument 22 23 See also editInterface matter Boundary between volumes of matter of different types or states Kelvin probe force microscope Noncontact variant of atomic force microscopy Micromeritics Science and technology of small particles Surface modification of biomaterials with proteins Surface finishing Range of processes that alter the surface of an item to achieve a certain property Surface modification Act of modifying the surface of a material Surface phenomenon Study of physical and chemical phenomena that occur at the interface of two phasesPages displaying short descriptions of redirect targets Tribology Science and engineering of interacting surfaces in relative motionReferences edit Prutton Martin 1994 Introduction to Surface Physics Oxford University Press ISBN 978 0 19 853476 1 Luklema J 1995 2005 Fundamentals of Interface and Colloid Science Vol 1 5 Academic Press Wennerstrom Hakan Lidin Sven Scientific Background on the Nobel Prize in Chemistry 2007 Chemical Processes on Solid Surfaces PDF Conrad H Ertl G Latta E E February 1974 Adsorption of hydrogen on palladium single crystal surfaces Surface Science 41 2 435 446 Bibcode 1974SurSc 41 435C doi 10 1016 0039 6028 74 90060 0 Christmann K Ertl G Pignet T February 1976 Adsorption of hydrogen on a Pt 111 surface Surface Science 54 2 365 392 Bibcode 1976SurSc 54 365C doi 10 1016 0039 6028 76 90232 6 Christmann K Schober O Ertl G Neumann M June 1 1974 Adsorption of hydrogen on nickel single crystal surfaces The Journal of Chemical Physics 60 11 4528 4540 Bibcode 1974JChPh 60 4528C doi 10 1063 1 1680935 Christmann K Behm R J Ertl G Van Hove M A Weinberg W H May 1 1979 Chemisorption geometry of hydrogen on Ni 111 Order and disorder The Journal of Chemical Physics 70 9 4168 4184 Bibcode 1979JChPh 70 4168C doi 10 1063 1 438041 Imbihl R Behm R J Christmann K Ertl G Matsushima T May 2 1982 Phase transitions of a two dimensional chemisorbed system H on Fe 110 Surface Science 117 1 257 266 Bibcode 1982SurSc 117 257I doi 10 1016 0039 6028 82 90506 4 Fischer Wolfarth Jan Henrik Farmer Jason A Flores Camacho J Manuel Genest Alexander Yudanov Ilya V Rosch Notker Campbell Charles T Schauermann Swetlana Freund Hans Joachim 2010 Particle size dependent heats of adsorption of CO on supported Pd nanoparticles as measured with a single crystal microcalorimeter Physical Review B 81 24 241416 Bibcode 2010PhRvB 81x1416F doi 10 1103 PhysRevB 81 241416 hdl 11858 00 001M 0000 0011 29F8 F Lewandowski M Groot I M N Shaikhutdinov S Freund H J 2012 Scanning tunneling microscopy evidence for the Mars van Krevelen type mechanism of low temperature CO oxidation on an FeO 111 film on Pt 111 Catalysis Today 181 52 55 doi 10 1016 j cattod 2011 08 033 hdl 11858 00 001M 0000 0010 50F9 9 Gewirth Andrew A Niece Brian K 1997 Electrochemical Applications ofin Situ Scanning Probe Microscopy Chemical Reviews 97 4 1129 1162 doi 10 1021 cr960067y PMID 11851445 Nagy Zoltan You Hoydoo 2002 Applications of surface X ray scattering to electrochemistry problems Electrochimica Acta 47 19 3037 3055 doi 10 1016 S0013 4686 02 00223 2 Grunder Yvonne Lucas Christopher A 2016 11 01 Surface X ray diffraction studies of single crystal electrocatalysts Nano Energy 29 378 393 doi 10 1016 j nanoen 2016 05 043 ISSN 2211 2855 Catalano Jeffrey G Park Changyong Fenter Paul Zhang Zhan 2008 Simultaneous inner and outer sphere arsenate adsorption on corundum and hematite Geochimica et Cosmochimica Acta 72 8 1986 2004 Bibcode 2008GeCoA 72 1986C doi 10 1016 j gca 2008 02 013 Xu Man Kovarik Libor Arey Bruce W Felmy Andrew R Rosso Kevin M Kerisit Sebastien 2014 Kinetics and mechanisms of cadmium carbonate heteroepitaxial growth at the calcite surface Geochimica et Cosmochimica Acta 134 221 233 doi 10 1016 j gca 2013 11 036 Jussila Henri Yang He Granqvist Niko Sun Zhipei 5 February 2016 Surface plasmon resonance for characterization of large area atomic layer graphene film Optica 3 2 151 Bibcode 2016Optic 3 151J doi 10 1364 OPTICA 3 000151 Granqvist Niko Yliperttula Marjo Valimaki Salla Pulkkinen Petri Tenhu Heikki Viitala Tapani 18 March 2014 Control of the Morphology of Lipid Layers by Substrate Surface Chemistry Langmuir 30 10 2799 2809 doi 10 1021 la4046622 PMID 24564782 Mashaghi A Swann M Popplewell J Textor M Reimhult E 2008 Optical Anisotropy of Supported Lipid Structures Probed by Waveguide Spectroscopy and Its Application to Study of Supported Lipid Bilayer Formation Kinetics Analytical Chemistry 80 10 3666 76 doi 10 1021 ac800027s PMID 18422336 Renaud Gilles Lazzari Remi Leroy Frederic 2009 Probing surface and interface morphology with Grazing Incidence Small Angle X Ray Scattering Surface Science Reports 64 8 255 380 Bibcode 2009SurSR 64 255R doi 10 1016 j surfrep 2009 07 002 Bluhm Hendrik Havecker Michael Knop Gericke Axel Kiskinova Maya Schlogl Robert Salmeron Miquel 2007 In Situ X Ray Photoelectron Spectroscopy Studies of Gas Solid Interfaces at Near Ambient Conditions MRS Bulletin 32 12 1022 1030 doi 10 1557 mrs2007 211 S2CID 55577979 Sing M Berner G Goss K Muller A Ruff A Wetscherek A Thiel S Mannhart J Pauli S A Schneider C W Willmott P R Gorgoi M Schafers F Claessen R 2009 Profiling the Interface Electron Gas ofLaAlO3 SrTiO3Heterostructures with Hard X Ray Photoelectron Spectroscopy Physical Review Letters 102 17 176805 arXiv 0809 1917 Bibcode 2009PhRvL 102q6805S doi 10 1103 PhysRevLett 102 176805 PMID 19518810 S2CID 43739895 Wintterlin J Volkening S Janssens T V W Zambelli T Ertl G 1997 Atomic and Macroscopic Reaction Rates of a Surface Catalyzed Reaction Science 278 5345 1931 4 Bibcode 1997Sci 278 1931W doi 10 1126 science 278 5345 1931 PMID 9395392 Waldmann T et al 2012 Oxidation of an Organic Adlayer A Bird s Eye View Journal of the American Chemical Society 134 21 8817 8822 doi 10 1021 ja302593v PMID 22571820 Further reading editKolasinski Kurt W 2012 04 30 Surface Science Foundations of Catalysis and Nanoscience 3 ed Wiley ISBN 978 1119990352 Attard Gary Barnes Colin January 1998 Surfaces Oxford Chemistry Primers ISBN 978 0198556862 External links edit nbsp Wikimedia Commons has media related to Surface science Ram Rao Materials and Surface Science a video from the Vega Science Trust Surface Chemistry Discoveries Surface Metrology Guide Retrieved from https en wikipedia org w index php title Surface science amp oldid 1217094085 Analysis techniques, wikipedia, wiki, book, books, library,

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