MOLECULAR CHAINS LINE UP TO FORM A NEW CHEMICAL STATE, CALLED A PROTOPOLYMER

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MOLECULAR CHAINS LINE UP TO FORM A NEW CHEMICAL STATE, CALLED A PROTOPOLYMER
07 December 2004 - Pennsylvania State University

First observation of extended chains of molecules that exhibit a strong interaction without forming chemical bonds.

A new chemical state, designated a 'protopolymer,' has been observed by Penn State researchers in chains of phenylene molecules on a crystalline copper surface at low temperature.

Protopolymers form when monomers, small molecules that link together chemically to form long chains, align and interact without forming chemical bonds. The novel structures were discovered by Paul S Weiss, professor of chemistry and physics at Penn State and Gregory S McCarty, a graduate student at time of discovery and now a research assistant professor of engineering science and mechanics. While surface-mediated pairing and other interactions have previously been seen on metal surfaces, this is the first observation of extended chains of molecules that exhibit a strong interaction without forming chemical bonds.

This type of alignment could be used to control growth and assembly of molecules and for manipulation of nanostructured materials, which are assembled on an atomic or molecular scale. Nanostructured materials often exhibit very different properties from those made by conventional techniques. A paper describing the research results, titled 'Formation and Manipulation of Protopolymer Chains,' is to be published in the Journal of the American Chemical Society on 15 December 2004.

Weiss points out that in substrate-mediated interactions, those in which the surface participates in the electronic interactions between molecules, the surface itself acts as a catalyst, holding molecules in place and enabling them to align for reaction. 'If we use substrate-mediated interactions to direct the arrangement of monomers prior to chemical bonding, we may be able to build atomically precise structures,' says Weiss. 'The key is to understand how the electronic functions of the molecule-surface interaction drive reactions and how they can be used to enhance chemical selectivity.'

The researchers carried out the experiments in a low temperature scanning tunnelling microscope (STM) under ultrahigh vacuum by exposing a close-packed copper surface to p-diiodobenzene molecules. On the surface, the molecules dissociate into phenylene (cyclic C6H4) reaction intermediates and two iodine atoms. The positions of these phenylene molecules are observed by STM. Extended structures self-assembled as long chains on the surface. While individual phenylene molecules remain mobile, molecules in the chains did not move under the imaging conditions. They were able to extract molecules from the chains, however, by applying voltage pulses to the STM tip. This suggests that the chains are not covalently bound together, but instead are held by electronic reactions between molecules that are mediated by the surface.

These chains extended across atomic steps on the copper surface where the level of the surface drops by one atom, resembling a stair step. This is a region in which electronic perturbations would be expected to disrupt the continuity. 'It amazed us that these extended structures could cross step boundaries,' Weiss says. 'These monomers have not yet formed covalent chemical bonds, which would link them together as a large molecule, but they are aligned and their interaction is much stronger than any previously observed.'

Weiss and McCarty were surprised to find that although the protopolymer is 'ready' to form a molecule, individual units can still be manipulated and even pulled out of the chain. The protopolymer chains were stationary on the copper surface, but short chains on a phenylene-coated copper surface could be moved with the STM tip. The existence of this bonding state could potentially have significant implications for supramolecular design. These intermolecular interactions could be used to place compounds together like a jigsaw puzzle into complex structures based on the choice of assembly units and substrate surfaces--one more step toward the molecular design and engineering of new nanostructured materials.

This research was funded, in part, by the National Science Foundation, the Defense Advanced Research Projects Agency (DARPA), and the Office of Naval Research.

Barbara K Kennedy
Penn State
+1 814 863 4682
science@psu.edu
Paul Weiss
+1 814 865 3693
stm@psu.edu

http://www. psu.edu

About: Pennsylvania State University
From agricultural college to world-class learning community - the story of the Pennsylvania State University is one of an expanding mission of teaching, research, and public service. But that mission was not so grandly conceived in 1855, when the Commonwealth chartered the school at the request of the Pennsylvania State Agricultural Society. The goal was to apply scientific principles to farming, a radical departure from the traditional curriculum grounded in mathematics, rhetoric, and classical languages.

Penn State has continued to respond to Pennsylvania’s changing economic and social needs. In 1989 the Pennsylvania College of Technology in Williamsport became an affiliate of the University. In 1997, Penn State and the Dickinson School of Law joined ranks. And Penn State’s new World Campus, which "graduated" its first students in 2000, uses the Internet and other new technologies to offer instruction on an "anywhere, anytime" basis.

To help meet the increasing demands placed on it, Penn State has looked to philanthropy for additional resources. President Bryce Jordan in 1984 launched a six-year effort that raised $352 million in private gifts to the University. This initiative enabled Penn State to attract world-class teachers and researchers, and assist thousands of financially needy and academically talented students. The Grand Destiny campaign (1996-2003) raised $1.37 billion, further strengthening academic programs and broadening the University's service to the Commonwealth and beyond.

The Materials Research Institute is an administrative unit that coordinates, supports and performs materials research in association with more than 200 faculty in 15 different departments and 4 colleges. The MRI is established under the Office of the Vice President for Research and Dean of the Graduate School to promote integration of research, teaching and outreach in materials research, science and engineering with a University-wide, interdisciplinary perspective. The MRI has several sister organizations with similar missions including the Institute for Life Science and the Penn State Institutes of the Environment (PSIE).

The mission of the MRI is to strategically position Penn State University - its students, research associates, faculty and corporate partners - to make important and significant advances in materials science, materials engineering, and their technological applications for communication, computers, energy, manufacturing, medicine and transportation.

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