Paper highlight: Solvent-mediated end-to-end assembly of gold nanorods

September 23rd, 2010 in Nanotechnology / Nanophysics
Paper highlight: Solvent-mediated end-to-end assembly of gold nanorods
Transmission-electron-microscope image of 70-nm-long gold nanorods assembled end to end via solvent-mediated interactions.


Transmission-electron-microscope image of 70-nm-long gold nanorods assembled end to end via solvent-mediated interactions.

Argonne National Laboratory scientists have developed a new method for the controlled end-to-end assembly of rod-shaped gold nanoparticles.

The nanoparticles are synthesized chemically using an established technique, producing high-quality gold nanorods with lengths of approximately 70 nm and diameters of approximately 15 nm, stabilized in water by hydrophilic surfactant molecules.

The sides of the rods are better protected by the surfactants than the ends, so that when additional ligand molecules that bind to gold are added to the solution, they preferentially attach to the ends of the rods.

If these ligands are hydrophobic, then the rods will spontaneously organize end to end when they are placed in an appropriate mixture of organic solvents and water.

Analysis of assembly kinetics showed that this solvent-mediated process is very different from the assembly processes that have previously been used to arrange nanorods, such as covalent bonding and bonding.

The analysis also demonstrates the conditions necessary for obtaining selective end-to-end assembly; in particular, it was found that nanorod samples need to be aged for several days between and assembly.

The results thus provide a new means of arranging anisotropic nanoparticles into controlled configurations, allowing for the bottom-up production of functional .

More information: Y. Wang, A.E. DePrince III, S.K. Gray, X.-M. Lin, and M. Pelton, J. Phys. Chem. Lett., 1, 2692 (2010)

Provided by Argonne National Laboratory

"Paper highlight: Solvent-mediated end-to-end assembly of gold nanorods." September 23rd, 2010. http://phys.org/news204443465.html