[1] G. Ferey and A. K. Cheetham, Porous materials-prospects for giant
pores, Science 283 (1999), 1125-1126.
[2] T. E. Gier and G. D. Stucky, Low temperature synthesis of hydrated
zinco(beryllo)-phosphate and arsenate molecular sieves, Nature 349
(1991), 508-510.
[3] R. C. Haushalter and L. A. Mundi, Reduced molybdenum phosphates:
Octahedral-tetrahedral framework solids with tunnels, cages, and
micropores, Chem. Mater. 4 (1992), 31-48,
[4] K. H. Lii, Y. F. Huang and V. Zima et al., Syntheses and
structures of organically templated iron phosphates, Chem. Mater. 10
(1998), 2599-2609.
[5] L. M. Meyer, R. C. Haushalter and J. Zubieta, The first vanadium
aluminophosphates: Hydrothermal synthesis and structure of and J. Solid State Chem. 125 (1996),
200-210.
[6] S. Natarajan and S. Mandal, Open-framework structures of
transition-metal compounds, Angew. Chem. Int. Ed. 47 (2008),
4798-4828.
[7] J. B. Parise, Some gallium phosphate frameworks related to the
aluminum phosphate molecular sieves: X-ray structural characterization
of J. Chem. Soc. Chem. Commun. 9 (1985),
606-607.
[8] V. Soghomonian, Q. Chen and R. C. Haushalter et al., An inorganic
double helix: Hydrothermal synthesis, structure, and magnetism of
chiral Science 259 (1993), 1596-1599.
[9] Y. Z. Wang and L. B. Liao, Hydrothermal synthesis and thermal
stability of an open framework vanadium aluminum phosphate J. Syn. Cryst. 34(1) (2005), 84-88.
[10] Y. Z. Wang and L. B. Liao, A comparative study of the thermal
stabilities of organic-templated vanadium phosphate, J. Syn. Cryst.
35(5) (2006), 1052-1056.
[11] Y. P. Zhang, A. Clearfield and R. C. Haushalter, Hydrothermal
synthesis and crystal structure of an organically templated
open-framework vanadium phosphate: Chem. Mater. 7 (1995), 1221-1225.
[12] V. Zima and K. H. Lii, Synthesis and characterization of
A new iron phosphate templated by
piperazine, J. Solid State Chem. 139 (1998), 326-331.