“This work pushes the miniaturization of electronics to its final frontier,” said Federico Capasso, physics research vice president at Bell Labs. “It may become the cornerstone of a new nanoelectronics era.”

The breakthrough is described in an article published today by the journal Science on their Science Express web site (www.sciencexpress.org).

Scientists have been looking for alternatives to conventional silicon electronics for many years because they anticipate that the continuing miniaturization of silicon-based integrated circuits will peter out in approximately a decade as fundamental physical limits are reached. Some of this research has been aimed at producing molecular-scale transistors, in which single molecules are responsible for the transistor action - switching and amplifying electrical signals.

Bell Labs’ “nanotransistors” - so-called because they are approximately a nanometer, or one-billionth of a meter, in size - appear to rival conventional silicon transistors in performance. They are made using a class of organic (carbon-based) semiconductor material known as thiols. In addition to carbon, thiols contain hydrogen and sulfur.

The main challenges in making nanotransistors are fabricating electrodes that are separated by only a few molecules and attaching electrical contacts to the tiny devices. The Bell Labs researchers were able to overcome these hurdles by using a self-assembly technique and a clever design.

They carved a notch into a silicon wafer and deposited a layer of gold at the bottom to function as one of the transistor’s three electrodes. Then they dipped the wafer into a solution that contained a mixture of thiol molecules and some inert organic molecules, and let it dry. The purpose of adding the inert molecules was to dilute the concentration of thiols. As the solution evaporated from the wafer, a film exactly one molecule thick was left behind on the gold electrode. By carefully adjusting the ratio of the thiol to the inert molecules, the scientists were able to statistically ensure that just one active molecule was present in the area on top of the gold electrode. They then deposited another gold electrode on top of this film, while they built the transistor’s third electrode on one side of the silicon notch.

“It is virtually impossible to attach three electrodes to a microscopically small molecule,” said Bao. “We overcame this problem by letting the molecule find these contacts and attach itself to them, a process called ’self-assembly.’ ”

The chemical self-assembly technique is relatively easy and inexpensive and, unlike silicon, does not require clean room technology.

“Our experiment shows that it is possible to realize transistor action in a single molecule without sophisticated fabrication procedures,” said Schon.

Using two nanotransistors, the Bell Labs scientists built a voltage inverter, a standard electronic circuit module commonly used in computer chips that converts a “0″ to a “1″ or vice versa. Though just a prototype, the success of this simple circuit suggests that nanotransistors could one day be used in microprocessors and memory chips, squeezing thousands of times as many transistors onto each chip than is possible today.

David Goldhaber-Gordon, a professor at Stanford University, commented that the Bell Labs scientists “have achieved several impressive advances toward nanoelectronics. The fabrication technique is particularly elegant in its simplicity.”

Bell Labs has a long and illustrious connection with transistors. William Shockley, John Bardeen and Walter Brattain invented the transistor at Bell Labs in 1947. Their invention spawned the digital age and earned them the Nobel Prize for Physics in 1956. Over the years, Bell Labs scientists have made many of the important contributions that have helped make transistors smaller, faster and more powerful. The technology curve has culminated with the latest development of single-molecule nanotransistors.