000			02072cam a2200289zu 4500
001			88963801
003			FRCYB88963801
005			20250429182149.0
006			m o d
007			cr un
008			250429s2024 fr | o|||||0|0|||eng d
020			_a9780323886543
035			_aFRCYB88963801
040			_aFR-PaCSA _ben _c _erda
100	1		_aMallakpour, Shadpour
245	0	1	_aIndustrial Applications of Nanoceramics _c['Mallakpour, Shadpour', 'Mustansar Hussain Phd, Chaudhery']
264		1	_bElsevier Science _c2024
300			_a p.
336			_btxt _2rdacontent
337			_bc _2rdamdedia
338			_bc _2rdacarrier
650		0	_a
700	0		_aMallakpour, Shadpour
700	0		_aMustansar Hussain Phd, Chaudhery
856	4	0	_2Cyberlibris _uhttps://international.scholarvox.com/netsen/book/88963801 _qtext/html _a
520			_aIndustrial Applications of Nanoceramics shows the unique processing, mechanical and surface characteristics of nanoceramics, covering their industrial application areas. These include the fabrication of capacitors, dense ceramics, corrosion-resistant coatings, solid electrolytes for fuel cells, sensors, batteries, cosmetic health, thermal barrier coatings, catalysts, bioengineering, automotive engineering, optoelectronics, computers, electronics, etc. This is an important reference source for materials scientists and engineers who are seeking to understand more about how nanoceramics are being used in a variety of industry sectors. Nanoceramics have the ability to show improved and unique properties, compared with conventional bulk ceramic materials. Zirconia (ZrO2), alumina (Al2O3), silicon carbide (SiC), silicon nitride (Si3N4) and titanium carbide fall into this category. - Outlines the superior chemical, physical and mechanical properties of nanoceramics compared with their macroscale counterparts - Includes major industrial applications of nanoceramics in energy, engineering and biomedicine - Explains the major processing techniques used for nanoceramic-based materials
999			_c1326498 _d1326498