The molecule changes its bonding patterns to a magnetic biradical state when heated; it then returns to a fully bonded non-magnetic closed state at room temperature. That transition, they report, can be done repeatedly without decomposition. It remains stable in the presence of both heat and oxygen.
Biradical refers to organic compounds, known as open-shell molecules, that have two free-flowing, non-bonding electrons. Producing them using techniques to control their electron spin, and thus provide semiconducting properties, in a heated state has been hampered by instability since the first synthetic biradical hydrocarbon was made in 1907.
“Potentially our approach could help to make organic solar cells more efficient than silicon solar cells, but that’s probably far in the future,” said UO doctoral student Gabriel E. Rudebusch, the paper’s lead author. “Our synthesis is rapid and efficient. We easily can make a gram of this compound, which is very stable when exposed to oxygen and heat. This stability has been almost unheard of in the literature about biradical compounds.”
The four-step synthesis of the compound — diindenoanthracene, or DIAn — and how it held up when tested in superconducting materials were detailed in a proof-of-principle paper published online May 23 by the journal Nature Chemistry. The UO team collaborated with experts in Japan, Spain and Sweden.
The molecular framework for the new molecule involves the hydrocarbon anthracene, which has three linearly fused hexagonal benzene rings, in combination with two five-membered pentagonal rings.
“The big difference between our new molecule and a lot of other biradical molecules that have been produced is those five-membered rings,” said co-author Michael M. Haley, who holds the UO’s Richard M. and Patricia H. Noyes Professorship in Chemistry. “They have the inherent ability to accept electrons or give up electrons. This means DIAn can move both negative and positive charges, which is an essential property for useful devices such as transistors and solar cells. Also, we can heat up our molecule to 150 degrees Celsius, bring it back to room temperature and heat it up again, repeatedly, and we see no decomposition in its reaction to oxygen. The unique features of DIAn are essential if these molecules are to have a use in the real world.”
Haley’s lab is now seeking to develop derivatives of the new molecule to help move the technology forward into potential applications.
Co-authors with Rudebusch and Haley were: Jonathan L. Marshall, a former doctoral researcher in Haley’s lab; Lev N. Zakharov of the UO’s Center for Advanced Materials Characterization in Oregon; Kjell Jorner and Henrik Ottosson of Sweden’s Uppsala University; Kotaro Fukuda and Masayoshi Nakano of Osaka University in Japan; Carlos J. Gómez-García of the University of Valencia in Spain; and José L. Zafra, Iratxe Arrechea-Marcos, Guzmán L. Espejo, Rocío Ponce Ortiz, and Juan Casado, all of the University of Malaga in Spain.
The National Science Foundation supported the research at the UO (grant CHE-1301485 to Haley). Additional funding support came from organizations within the governments of Spain, Japan and Sweden.