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'Butterfly-shaped' palladium subnano cluster built in 3-D

Date:
February 20, 2019
Source:
Institute of Industrial Science, The University of Tokyo
Summary:
Scientists have produced a 3-D cluster molecule based on palladium. First, they created a 'butterfly-shaped' Pd4 framework, using an organosilicon compounds bearing the aromatic substitutents as both template and support for the palladium atoms. Then, using another template, they connected two butterfly-shaped Pd4 skeleton, via chlorine, into a Pd6 cluster based on edge-sharing tetrahedra. This strategy using organosilicons to design customized subnano-architectures may enable design of a range of functional materials and catalysts.
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Scientists have produced a 3-D cluster molecule based on palladium. First, they created a 'butterfly-shaped' Pd4 framework, using an organosilicon compounds bearing the aromatic substitutents as both template and support for the palladium atoms. Then, using another template, they connected two butterfly-shaped Pd4 skeleton, via chlorine, into a Pd6 cluster based on edge-sharing tetrahedra. This strategy using organosilicons to design customized subnano-architectures may enable design of a range of functional materials and catalysts.

Miniaturization is the watchword of progress. Nanoscience -- building structures on the scale of a few atoms -- has long been at the forefront of chemistry for some time now. Recently, researchers at The University of Tokyo developed the new strategy to construct the subnanosized metal aggregates, building up small metal clusters into grander 3-D architectures. Their creations could have real industrial value.

Nanochemistry offers a range of classic design shapes, such as cubes, rods, wires, and even "nanoflakes," all built from atom clusters. The team at Uni Tokyo's Institute of Industrial Science (IIS) builds nanosheets from the noble metal palladium (Pd). In a new study, they threaded these 2-D building blocks into a distinctive 3-D design.

A smart way to make nanosheets is using templates -- organic molecules that act as a framework for the metal atoms. Moving beyond purely organic templates, the IIS team used an organosilicon, a molecule based on three silicon atoms, to construct a bent or "butterfly-shaped" sheet of four Pd atoms. These metals were stabilized by bonding with benzene rings dangling from the silicons.

"Looking at the structure of the Pd4 molecule, we saw the potential to link together multiple sheets of this kind through chemical linkers," says Kento Shimamoto, co-author of the study in Chemistry -- A European Journal. "Given the right template, we reasoned, we could expand the dimensionality of our cluster from a 2-D sheet into the third dimension."

Building stable nanoclusters, even in 2-D, is not easy -- due to the lack of the appropriate template moleclues that pushes the metal species into close proximity. However, metal centers can be linked stably together, while maintaining a comfortable distance, through the use of bridging atoms like chlorine. The resulting clusters often have unique chemical properties as a result of metal -- metal interactions.

The team therefore chose a new organosilicon template with two chlorine atoms replacing part of the organic region. Reacting the palladium source with this new template produced not a 2-D sheet, but a 3-D cluster containing six Pd atoms. The metals apparently formed a pair of Pd4 tetrahedra (sharing two atoms), bridged by chlorine, which forced the Pd atoms close enough to bond with each other.

"3-D subnanoclusters have real potential as catalysts and functional materials," says lead author Yusuke Sunada. "But their function strongly depends on precise control of their shape. Organosilicons are readily available, and offer a platform for designing diverse architectures -- linking multiple clusters into larger molecules -- in an industrially feasible way."


Story Source:

Materials provided by Institute of Industrial Science, The University of Tokyo. Note: Content may be edited for style and length.


Journal Reference:

  1. Kento Shimamoto, Yusuke Sunada. Dimensionality Expansion of a Butterfly Shaped Pd4 Framework: Constructing Edge-Sharing Pd6 Tetrahedra. Chemistry - A European Journal, 2019; DOI: 10.1002/chem.201805678

Cite This Page:

Institute of Industrial Science, The University of Tokyo. "'Butterfly-shaped' palladium subnano cluster built in 3-D." ScienceDaily. ScienceDaily, 20 February 2019. <www.sciencedaily.com/releases/2019/02/190220103454.htm>.
Institute of Industrial Science, The University of Tokyo. (2019, February 20). 'Butterfly-shaped' palladium subnano cluster built in 3-D. ScienceDaily. Retrieved December 21, 2024 from www.sciencedaily.com/releases/2019/02/190220103454.htm
Institute of Industrial Science, The University of Tokyo. "'Butterfly-shaped' palladium subnano cluster built in 3-D." ScienceDaily. www.sciencedaily.com/releases/2019/02/190220103454.htm (accessed December 21, 2024).

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