A process related to the sol-gel route is the Pechini, or liquid mix, process (named after its American inventor, Maggio Pechini). An aqueous solution of suitable oxides or salts is mixed with an alpha-hydroxycarboxylic acid such as citric acid. Chelation, or the formation of complex ring-shaped compounds around the metal cations, takes place in the solution. A polyhydroxy alcohol is then added, and the liquid is heated to 150–250 °C (300–480 °F) to allow the chelates to polymerize, or form large, cross-linked networks. As excess water is removed by heating, a solid polymeric resin results.[1] Eventually, at still higher temperatures of 500–900 °C (930–1,650 °F), the resin is decomposed or charred, and ultimately a mixed oxide is obtained. Particle size is extremely small, typically 20 to 50 nanometres (although there is agglomeration of these particles into larger clusters), with intimate mixing taking place on the atomic scale.[2]
The Pechini method was proposed in 1967 as a technique of depositing dielectric films of titanates and niobates of lead and alkaline-earth elements in the production of capacitors. Later, the process was customised for the in-lab synthesis of multicomponent finely dispersed oxide materials.[3][4]
Pechini process
This method has been used for synthesizing over 100 mixed metal oxides including lanthanum manganite for solid oxide fuel cells and BaTiO3 (Lessing 1989).[5] Unlike the sol–gel process in which the metal alkoxide participates in the gel-forming reactions this process is based on a gelation reaction between the alcohol and acid used as solvents. A polymeric resin containing a good distribution of cations is obtained which yields the oxide upon calcination. The use of polyacrylic acid with higher functionality results in highly cross-linked resins containing a more uniform distribution of the reacting cations. The gel structures can be varied depending on the acid-to-alcohol ratio. A low organic content is preferred to decrease the calcination time and temperature in order to obtain fine-grained materials with low carbon contents.[6][7]
References
- ↑ Xinyu Lu; Tom S. Pine; Daniel R. Mumm; Jacob Brouwer (2007). "Modified Pechini synthesis and characterization of Y-doped strontium titanate perovskite". Solid State Ionics Forum. 178 (20): 1195–1199. doi:10.1016/j.ssi.2007.05.018.
- ↑ Thomas O. Mason (2016). "Encyclopedia Britannica". Advanced Ceramics.
- ↑ "Pechini method".
- ↑ A.M.Huízar-Félix; T.Hernández; S.de la Parra; J.Ibarra; B.Kharisov (2012). "Sol–gel based Pechini method synthesis and characterization of Sm1 − xCaxFeO3 perovskite 0.1 ≤ x ≤ 0.5". Powder Technology. 229: 290–293. doi:10.1016/j.powtec.2012.06.057. ISSN 0032-5910.
- ↑ Leonardo Pacheco Wendler; Kethlinn Ramos; Adriana Scoton Antonio Chinelatto; Adilson Luiz Chinelatto (2014). "Peroviskites Synthesis to SOFC Anodes". Materials Science Forum. 805: 498–503. doi:10.4028/www.scientific.net/MSF.805.498.
- ↑ Kumta, P.N. (2001). Encyclopedia of Materials: Science and Technology (Second ed.). p. 6588.
- ↑ Aluska do Nascimento Simões Braga; Rosiane Maria da Costa Farias; Danubia Lisbôa Costa; Gelmires Araújo Neves; Hélio de Lucena Lira; Romualdo Rodrigues Menezes (2012). "Synthesis of Mullite by the Pechini Method". Materials Science Forum. 820: 107–112.