Materials

Super-thin electrical wires are made from tiny diamond bits

Super-thin electrical wires are made from tiny diamond bits
When tens of thousands of the new diamondoid nanowires created by Stanford University and SLAC are clumped together, they are visible to the naked eye
When tens of thousands of the new diamondoid nanowires created by Stanford University and SLAC are clumped together, they are visible to the naked eye
View 5 Images
A graphical representation of the new nanowire diamondoid structure
1/5
A graphical representation of the new nanowire diamondoid structure
The creators believe that the new method used to create this nanowire could one day be employed to make minuscule wires for a range of applications
2/5
The creators believe that the new method used to create this nanowire could one day be employed to make minuscule wires for a range of applications
An illustration showing the molecular cage of diamondoids self-assembling around the nanowire core
3/5
An illustration showing the molecular cage of diamondoids self-assembling around the nanowire core
Molecular models of the new diamondoid nanowire structure
4/5
Molecular models of the new diamondoid nanowire structure
When tens of thousands of the new diamondoid nanowires created by Stanford University and SLAC are clumped together, they are visible to the naked eye
5/5
When tens of thousands of the new diamondoid nanowires created by Stanford University and SLAC are clumped together, they are visible to the naked eye
View gallery - 5 images

Physicists from Stanford University say they have just invented the world's narrowest electrical wire, just three atoms wide, using diamandoids (the smallest component parts of a diamond) to do so. The creators believe that the new method used to create this nanowire could one day be employed to make minuscule wires for a range of applications, including electricity-generating fabrics, optoelectronic devices, and even superconducting materials that conduct electricity with almost no loss.

Composed of interlocking cages of carbon and hydrogen, diamondoids occur naturally in petroleum fluids. For this research, the tiny molecules were extracted and separated by the researchers and a sulphur atom was attached to each one. In a solution, the sulphur-loaded diamondoids were made to bond with copper ions to create the nanowire building blocks.

In the solution, the building blocks clumped together via a phenomenon known as the van der Waals force, that defines such things as the way certain molecules are attracted or repelled from each other and how geckos are able to walk on glass.

An illustration showing the molecular cage of diamondoids self-assembling around the nanowire core
An illustration showing the molecular cage of diamondoids self-assembling around the nanowire core

"Much like LEGO blocks, they only fit together in certain ways that are determined by their size and shape," said Stanford graduate student Fei Hua Li. "The copper and sulfur atoms of each building block wound up in the middle, forming the conductive core of the wire, and the bulkier diamondoids wound up on the outside, forming the insulating shell."

The resultant atomic scale of these wires and their conductivity is an important part of their usefulness, the team says, as materials that are constructed in one or two dimensions behave very differently to normal-sized wires, particularly in regard to quantum mechanical effects that tend to limit electron flow.

Building on previous research where Stanford scientists created a diode from diamondoids, the team has also used diamondoids to create one-dimensional nanowires of cadmium, zinc, iron, and silver.

"You can imagine weaving those into fabrics to generate energy," said Stanford associate professor Nicholas Melosh. "This method gives us a versatile toolkit where we can tinker with a number of ingredients and experimental conditions to create new materials with finely tuned electronic properties and interesting physics."

The results of this research have been published in the journal Nature Materials.

Source: SLAC/Stanford University

View gallery - 5 images
1 comment
1 comment
yawood
If they can use these to produce materials that are superconducting at room temperature it would seem to be great for maglev trains etc.