Science & Technology | Environment | Newsroom | Administration | Directory | Visitor Info | Beyond Brookhaven
go to BNL home

A-Z Site Index

Most Recent News

News Archives

Media Contacts

About Brookhaven

Fact Sheets

Management Bios

Science Magazine

Brookhaven History

Image Library




Building 134
P.O. Box 5000
Upton, NY 11973-5000
phone 631 344-2345
fax 631 344-3368

managed for the U.S. Department of Energy
by Brookhaven Science Associates, a company
founded by Stony Brook University and Battelle

News Release

Number: 03-27
Released: November 5, 2003
Contact: Diane Greenberg, 631 344-2347 or Mona S. Rowe, 631 344-5056

Unique Molecular Structure Offers Insight Into Nanoscale Self-Assembly, Solution Chemistry

UPTON, NY - Scientists at the U.S. Department of Energy’s Brookhaven National Laboratory and the University of Bielefeld, Germany, have discovered a new type of hollow spherical vesicles formed by large-scale, wheel-shaped inorganic molecules. These vesicles, described in the November 6, 2003, issue of Nature, represent a new kind of self-assembly in nature with implications for the emerging field of nanoscience as well the solution behavior of other types of particles or systems previously thought to be unrelated.

“These vesicles are totally different from the common vesicles formed by other types of molecules, such as the biolipids of cell membranes and surfactants used in soaps,” said Brookhaven physicist Tianbo Liu, lead author on the paper. In those cases, he explains, the molecules have both hydrophilic (“water-loving”) and hydrophobic (“water-hating”) parts. The water-hating portions all line up facing one another, leaving the water-loving parts exposed to the surface so the entire vesicle can exist in an aqueous environment.

But the molecules described by Liu and his co-authors — giant wheel-shaped polyoxo-molybdate (POM) molecules, composed of hundreds or even thousands of molybdenum and oxygen atoms — have no hydrophobic parts. Each wheel-shaped molecule also carries some negative charge, which should make the wheels repel one another. Yet, by using light scattering and transmission electron microscope (TEM) techniques, Liu and his coworkers found that, in dilute solution, more than 1,000 of these wheel-shaped POMs associate and evenly distribute onto the surface of 90-nanometer-wide hollow spheres. The TEM measurements were performed by Brookhaven biologist Huilin Li.

Individual wheel-shaped polyoxomolybdate (POM) molecules, composed of molybdenum (blue) and oxygen (red) atoms (above), self-assemble to form 90-nanometer-wide spheres, or vesicles (below), in aqueous solution. The scientists suggest that increased hydrogen bonding among the water molecules confined in the tiny spaces between POM wheels essentially "freezes" the wheels in place.

> Download high-resolution, 300-dpi images of POM molecule wheel and sphere.

The study helps elucidates how these spheres form. It turns out that hydrogen bonds formed between water molecules play an important role. “In the nanometer-size spaces between the wheel molecules, the viscosity of water could increase by several orders of magnitude,” says Liu. This happens, he explains, because the water molecules are confined in the tiny spaces, so hydrogen bonds readily form between adjacent water molecules. “The properties of this heavily hydrogen-bonded water are more like those of ice than liquid water,” he adds. “So the water between the wheel-shaped molecules acts like a glue that overcomes the repulsive electrostatic forces and ‘freezes’ the wheels in place.”

The electrically charged POM molecules can be thought of as large, single, inorganic ions, but also as polyelectrolytes — substances made of repeating subunits that carry an overall electric charge (like proteins or DNA). They can also behave in ways similar to colloidal suspensions, where large particles such as nanoparticles, dust, or aerosols are dispersed but not truly dissolved in another substance like a liquid or air. With these three simultaneous identities, the POMs can serve as a perfect model system for studying how these other substances behave in solution, which, prior to the discovery of this “missing link,” were all independent fields, Liu says.

In the fields of nanoscience and nanotechnology, the POM giant molecules may offer another “dual-personality” benefit: They possess the advantages of single molecules, such as well-defined structures and uniform size and mass, as well as those of nanoparticles, such as complex and variable electronic, magnetic, and colloidal properties. This combination of properties, especially the molecules’ monodispersed nature and adjustable chemical and physical properties, could help to develop more diverse nanomaterials than were previously thought possible.

This work builds on more than 200 years of curiosity about molybdenum solutions, which often have a distinctive blue color. Before anyone knew the element molybdenum at valence state +5 (MoV) was responsible for the blue color, Native Americans gave the name “Blue Waters” to certain fountains near today’s Idaho Springs and the Valley of the Ten Thousand Smokes. Even after the secret of the color was revealed some 200 years ago, the detailed molecular structures of the solutes remained unclear. Then, in the last decade, a series of nanoscale, wheel-shaped, blue color, POM molecules were identified by a German group led by Achim Müller, a co-author of the current paper. This progress introduced the more fascinating puzzle of how these giant molecules dissolve in water. The current study offers an explanation for the mechanism of vesicle formation, and opens a new avenue of exploration for scientists interested in what happens as inorganic molecules reach the nanometer scale.

This research was funded by the Division of Materials Science within the Department of Energy’s Office of Science and direct funding from Brookhaven Lab (LDRD funding).