Pseudoboehmite

Pseudoboehmite is an aluminium compound with the chemical composition AlO(OH). It consists of finely crystalline boehmite. However, the water content is higher than in boehmite.

History[edit]

Calvet et al. coined the name pseudoboehmite in 1952 when they synthesized pure aluminium hydroxyde gel.^[1]^[2] Its XRD pattern is similar to that of boehmite but the relative intensities of the peaks differ.

Morphology[edit]

Pseudoboehmite is essentially finely crystalline boehmite which consists of the same or similar octahedral layers in the xz plane but lacks three-dimensional order because of a restricted number of unit cells in y direction.^[3] It consists of a significant number of crystallites which contain a single unit cell along y or single octahedral layers. It contains more water which is commonly intercalated between octahedral layers, normally randomly arranged, but sometimes regularly.

The water content consists of adsorbed and chemically bound water. The higher water content compared to boehmite can be explained by a smaller crystallite size.^[4] While boehmite consists of relatively long AlOOH chains that have terminal H₂O groups, the chains in pseudoboehmite are significantly shorter. This translates into a significantly higher specific water content due to the terminal water groups:

It is a "poorly crystallized" Al³⁺ compound with the composition Al₂O₃ · x H₂O (1.0 < x < 2.0) with interplanar spacings increased in the [020]-direction to 0.67 nm in comparison with 0.617 nm for boehmite.^[5]

At higher temperatures pseudoboehmite is transformed to γ-alumina but the pore size distribution remains unchanged up to 1000 °C.^[6] At around 1100 °C however, specific area significantly decreases because of sintering related to a transformation to α-Al₂O₃.

Synthesis[edit]

Pseudoboehmite can be synthesized by aging non-crystalline aluminium hydroxide gels at pH values between 5.0 and 7.4.^[5]

Uses[edit]

Pseudoboehmite is used as binder for FCC catalysts and adsorbents. It is also a raw material for activated alumina.

References[edit]

^ Calvet, E.; Bovinet, P.; Noel, M.; Thibon, H.; Maillard, A.; Tertian, R. (1952). "Contribution a l'étude des gels d'alumine". Bulletin de la Société Chimique de France. 19: 99–108.
^ de Souza Santos, P.; Viera Coelho, A.C.; de Souza Santos, H.; Kunihiko Kiyohara, P. (2009). "Hydrothermal Synthesis of Well-Crysatllized Bohemite Crystals of Various Shapes". Materials Research. 12 (4): 437–445. doi:10.1590/S1516-14392009000400012. S2CID 37578325.
^ Tettenhorst, R.; Hofmann, D.A. (1980). "Crystal Chemistry of Boehmite". Clays and Clay Minerals. 28 (5): 373–380. doi:10.1346/CCMN.1980.0280507.
^ Baker, B.R.; Pearson, R.M. (1974). "Water Content of Pseudoboehmite: A New Model for its Structure". Journal of Catalysis. 33 (2): 265–278. doi:10.1016/0021-9517(74)90270-X.
^ ^a ^b Vieira Coelho, A.C.; et al. (2008). "Specific Surface Area and Structures of Aluminas from Fibrillar Pseudoboehmite". Revista Matéria. 13 (2): 329–341. doi:10.1590/S1517-70762008000200011.
^ Nogi, K.; Naito, M.; Yokoyama, T. Nanoparticle Technology Handbook, S. p. 204.

[calvet-1] Calvet, E.; Bovinet, P.; Noel, M.; Thibon, H.; Maillard, A.; Tertian, R. (1952). "Contribution a l'étude des gels d'alumine". Bulletin de la Société Chimique de France. 19: 99–108.

[souza_2009-2] Souza Santos, P.; Viera Coelho, A.C.; de Souza Santos, H.; Kunihiko Kiyohara, P. (2009). "Hydrothermal Synthesis of Well-Crysatllized Bohemite Crystals of Various Shapes". Materials Research. 12 (4): 437–445. doi:10.1590/S1516-14392009000400012. S2CID 37578325.

[Tettenhorst_1980-3] Tettenhorst, R.; Hofmann, D.A. (1980). "Crystal Chemistry of Boehmite". Clays and Clay Minerals. 28 (5): 373–380. doi:10.1346/CCMN.1980.0280507.

[Baker_1974-4] Baker, B.R.; Pearson, R.M. (1974). "Water Content of Pseudoboehmite: A New Model for its Structure". Journal of Catalysis. 33 (2): 265–278. doi:10.1016/0021-9517(74)90270-X.

[vieira_2008-5] Vieira Coelho, A.C.; et al. (2008). "Specific Surface Area and Structures of Aluminas from Fibrillar Pseudoboehmite". Revista Matéria. 13 (2): 329–341. doi:10.1590/S1517-70762008000200011.

[Nogi-6] Nogi, K.; Naito, M.; Yokoyama, T. Nanoparticle Technology Handbook, S. p. 204.

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