04987nam 2200769 a 450 991082657080332120240516150718.01-283-85790-13-11-027400-010.1515/9783110273991(CKB)2670000000211131(EBL)893990(OCoLC)796384298(SSID)ssj0000678462(PQKBManifestationID)11469954(PQKBTitleCode)TC0000678462(PQKBWorkID)10728872(PQKB)11464649(MiAaPQ)EBC893990(DE-B1597)174412(OCoLC)797050554(DE-B1597)9783110273991(Au-PeEL)EBL893990(CaPaEBR)ebr10582311(CaONFJC)MIL417040(EXLCZ)99267000000021113120111108d2012 uy 0engurnn#---|u||utxtccrNanoclusters and microparticles in gases and vapors /Boris M. Smirnov1st ed.Berlin ;Boston De Gruyterc20121 online resource (264 p.)De Gruyter studies in mathematical physics ;6Description based upon print version of record.3-11-027399-3 3-11-027390-X Includes bibliographical references and index.Front matter --Preface --Contents --List of figures --Chapter 1. Introduction --Part I. Properties of small particles and their behavior in gases --Chapter 2. Nanoclusters and microparticles in gases --Chapter 3. Cluster properties and their modeling --Chapter 4. Dynamics of collisions in buffer gas involving clusters --Part II. Processes involving small particles in gases --Chapter 5. Transport phenomena in gases involving small particles --Chapter 6. Particle motion in gas flows --Chapter 7. Processes in buffer gas on surface of small particles --Chapter 8. Charging of small particles in ionized gases --Chapter 9. Growth of clusters and small particles in buffer gas --Chapter 10. Structures formed in aggregation of solid particles --Chapter 11. Conclusion --Appendix A. Physical parameters --Appendix B. Conversional factors --Appendix C. Transport coefficients of atomic particles in gases --Bibliography --IndexVarious nanoclusters and microparticles are considered in excited and ionized gases, as well as various processes with their participation. The concepts of these processes were developed 50 - 100 years ago mostly for dense media, and basing on these concepts, we analyze these processes in gases in two opposite regimes, so that in the kinetic regime surrounding atoms of a buffer gas do not partake in processes involving small particles, and the diffusion regime corresponds to a dense gas where interaction of small particles with a buffer gas subjects to laws of hydrodynamics. For calculation or estimation of the rates of these processes, we are based on the liquid drop model for small particles which was introduced in physics by N. Bohr about 80 years ago for the analysis of properties of atomic nuclei including the nuclear fusion and the hard sphere model (or the model of billiard balls) which was used by J. C. Maxwell 150 years ago and helped to create the kinetic theory of gases. These models along with the analysis of their accuracy allow one to study various processes, such as transport processes in gases involving small particles, charging of small particles in gases, chemical processes, atom attachment and quenching of excited atomic particles on the surface of a small particle, nucleation processes for small particles including coagulation, coalescence and growth of fractal aggregates, chain aggregates, fractal fibres and aerogels. Each analysis is finished by analytic formulas or simple models which allow us to calculate the rate of a certain real process with a known accuracy or to estimate this, and criteria of validity are given for these expressions obtained. Examples of real objects and processes involving small particles are analyzed.De Gruyter studies in mathematical physics ;6.Ionized gasesMicroclustersVaporsMicrostructureKinetic theory of gasesClusters.Gases.Nanoclusters.Nanoparticles.Vapors.Ionized gases.Microclusters.VaporsMicrostructure.Kinetic theory of gases.533UF 4000SEPArvkSmirnov B. M(Boris Mikhaĭlovich),1938-50046MiAaPQMiAaPQMiAaPQBOOK9910826570803321Nanoclusters and microparticles in gases and vapors4043835UNINA