Prashant Jain , Naresh Dalal and Tony Cheetham

1. 2D arrays of magnetic clusters Prashant Jain, Naresh Dalal and Tony Cheetham Harold Kroto

2. Nickel 1,4-Cyclohexanedicarboxylates

3. … and thus replace present expensive top-down methods that are more environmentally harmful We should be able to lay the clusters down on a disk by simple dip chemistry

6. 1250 C Zinc Nitrate and Terephthalic Acid Solution in DMF 3 Hours SEM Images of MOF-5 crystallites grown in the PAA Channels Substrate Catalyzed Nanoparticle Growth of Metal Organic Frameworks Prashant Jain@, Harold W. Kroto@, and Anthony K. Cheetham# @Dept. of Chemistry & Biochemistry, Florida State University, USA #Materials Research Laboratory, University of California, Santa Barbara, USA Overview Metal Organic Framework and Coordination polymers have wide applications such as separation, catalysis, and potential fuel-gas storage. Numerous metal organic frameworks have been synthesised and extensively studied during the last twenty years due to their fundamental interest as well as their technological applications. In recent years, this research activity was also devoted to the synthesis and studies of these hybrid materials at the nano level regime because of their unique physical properties and owing to the need for control over the size, shape and organization for their future incorporation into devices. Here we demonstrate the growth of nano dimensional MOF-5 and Ni-CHDC on various substrate. Growth of MOF-5 in the channels of Porous Anodized Alumina Membrane PAA Membrane SEM Image of a Cross-section after the reaction PAA Membrane Filled With Reaction Mixture Particle size can be controlled by varying the membrane diameter. In the PAA membrane with the pore diameter of 200 nm, most of the particles have approximate dimensions of 70nm X 35nm which suggest that physical restriction caused by the pore diameter plays a significant role. These PAA channels decorated with nanosized coordination polymers could be used for various application like gas purification and catalysis. It also leads to the possibility of growing other inorganic materials inside the channels electrochemically decorated with these hybrid materials. Cellular Assembly of Nickel-1,4 Cyclohexanedicarboxylate on a Silicon Wafer Nickel-1,4 cyclehexanedicarboxylate on Multi Walled Carbon Nano Tubes Ni-CHDC, with the layered structure, was grown on/around the MWCNTs. Further characterization is in progress. Above cellular structures were grown in-situ. Wafer was placed inside a hydrothermal reactor and was heated to 1650 C.

8. 2D arrays of magnetic clusters

9. Session K11 Friday 09.00 am K11.5 Prashant Jain, Naresh Dalal and Tony Cheetham

10. Ni6(OH)6(chdcox)3(H2O)6.2H2O Nickel 1,4-Cyclohexanedicarboxylates Phase 3

11. Phase 3 Nickel 1,4-Cyclohexanedicarboxylates Ni6(OH)6(chdc)3 (H2O)6. 2H2O Trigonal, R -3c, trans 160-175°C Pure

12. Nickel 1,4-Cyclohexanedicarboxylates Ni6(OH)6(chdc)3(H2O)6.2H2O Phase 3 Trigonal, R-3c, trans 160-175°C Pure

13. Phase 3 Nickel 1,4-Cyclohexanedicarboxylates Ni6(OH)6(chdc)3(H2O)6.2H2O Trigonal, R-3c, trans 160-175°C Pure

14. Phase 3 Nickel 1,4-Cyclohexanedicarboxylates Ni6(OH)6(chdc)3(H2O)6.2H2O Trigonal, R-3c, trans 160-175°C Pure

15. Phase 3 Nickel 1,4-Cyclohexanedicarboxylates Ni6(OH)6(chdc)3(H2O)6.2H2O Trigonal, R-3c, trans 160-175°C Pure

16. Phase 3 Nickel 1,4-Cyclohexanedicarboxylates Ni6(OH)6(chdc)3(H2O)6.2H2O Trigonal, R-3c, trans 160-175°C Pure