Editing Sintering (section)

== General sintering ==
[[File:Sintering Tool Cross Section and Part.jpg|thumb|Cross section of a sintering tool and the sintered part]]

Sintering is generally considered successful when the process reduces [[porosity]] and enhances properties such as strength, [[electrical conductivity]], [[translucency]] and [[thermal conductivity]]. In some special cases, sintering is carefully applied to enhance the strength of a material while preserving porosity (e.g. in filters or catalysts, where gas adsorption is a priority). During the sintering process, atomic diffusion drives powder surface elimination in different stages, starting at the formation of necks between powders to final elimination of small pores at the end of the process.
 
The driving force for densification is the change in [[Free energy (thermodynamics)|free energy]] from the decrease in surface area and lowering of the surface free energy by the replacement of solid-vapor interfaces. It forms new but lower-energy solid-solid interfaces with a net decrease in total free energy. On a microscopic scale, material transfer is affected by the change in pressure and differences in free energy across the curved surface. If the size of the particle is small (and its curvature is high), these effects become very large in magnitude. The change in energy is much higher when the radius of curvature is less than a few micrometers, which is one of the main reasons why much ceramic technology is based on the use of fine-particle materials.<ref name=Kingery/>

The ratio of bond area to particle size is a determining factor for properties such as strength and electrical conductivity. To yield the desired bond area, temperature and initial grain size are precisely controlled over the sintering process. At steady state, the particle radius and the vapor pressure are proportional to (p<sub>0</sub>)<sup>2/3</sup> and to (p<sub>0</sub>)<sup>1/3</sup>, respectively.<ref name=Kingery/>

The source of power for solid-state processes is the change in free or chemical potential energy between the neck and the surface of the particle. This energy creates a transfer of material through the fastest means possible; if transfer were to take place from the particle volume or the grain boundary between particles, particle count would decrease and pores would be destroyed. Pore elimination is fastest in samples with many pores of uniform size because the boundary diffusion distance is smallest. During the latter portions of the process, boundary and lattice diffusion from the boundary become important.<ref name=Kingery/>

Control of temperature is very important to the sintering process, since grain-boundary diffusion and volume diffusion rely heavily upon temperature, particle size, particle distribution, material composition, and often other properties of the sintering environment itself.<ref name=Kingery>{{Cite book|last1 = Kingery|first1 = W. David|last2 = Bowen|first2 = H. K.|last3 = Uhlmann|first3 = Donald R.|title = Introduction to Ceramics|publisher = [[John Wiley & Sons]], [[Academic Press]]|date = April 1976|edition = 2nd|url = https://archive.org/details/introductiontoce0000king|isbn = 0-471-47860-1|url-access = registration}}</ref>