Select your localized edition:

Close ×

More Ways to Connect

Discover one of our 28 local entrepreneurial communities »

Be the first to know as we launch in new countries and markets around the globe.

Interested in bringing MIT Technology Review to your local market?

MIT Technology ReviewMIT Technology Review - logo


Unsupported browser: Your browser does not meet modern web standards. See how it scores »

{ action.text }

For years now, people have been talking up carbon nanotubes and their potential to be used for far-out applications including strong space-elevator cables, robust electrical transmission lines, and high-performance nanotube computers. These things may still be a decade off, but several advances this year make them sound less like fantasies.

Researchers at Rice University refined methods for spinning acid solutions of carbon nanotubes into fibers hundreds of meters long (“Making Carbon Nanotubes into Long Fibers”). Their process, which could be used industrially (it’s similar to how Kevlar is made), is the culmination of eight years of work begun by the late Richard Smalley, who shared the Nobel Prize in chemistry in 1996 for the discovery of carbon nanomaterials (“Wires of Wonder”). In order to make electrical transmission lines, researchers still need to perfect a process for growing pure batches of metallic nanotubes. Today they come out mixed with semiconducting tubes, and the two must be separated. Still, the Rice demonstration of making nanotubes into large structures is a major accomplishment.

On the nanotube electronics front, the year started out strong. The company Unidym, which makes transparent electrodes from carbon nanotubes, demonstrated its products, and companies including Samsung tested them in displays (“Clear Carbon-Nanotube Films”). Unidym’s nanotube films could be incorporated into flexible displays and replace the expensive, brittle materials currently used to make display electrodes.

The year also brought major accomplishments in making more sophisticated nanotube devices for displays, including the integrated circuits that drive them (“Practical Nanotube Electronics”). One of the major advantages of nanotube display circuits is that they could be printed like newspaper, which should bring down costs. And this month at the International Electron Devices Meeting, researchers at Stanford presented the first three-dimensional nanotube circuits (“Complex Integrated Circuits Made of Carbon Nanotubes”). The processes their nanotube circuits can carry out, like adding and storing numbers, are about as sophisticated as what silicon could do in the mid-1960s.

Meanwhile, researchers at Cornell made an interesting basic science demonstration: single nanotubes can be wired up to make extremely efficient solar cells (“Superefficient Solar from Nanotubes”). While conventional solar materials can only produce one electron per striking photon, carbon nanotubes can produce two if the photon has enough energy.

Nanomaterials, Big Energy

Activity in academic labs and companies this year showed that energy-storage materials structured on the nanoscale have a greater capacity than their conventional counterparts. This concept launched two startups that received government funding. FastCAP Systems of Cambridge, MA, is developing ultracapacitors based on carbon nanotubes, which can store a large amount of electrical charge because of their huge surface area (“Ultracapacitor Startup Gets a Big Boost”). The company received an ARPA-E grant for $5.35 million over two-and-a-half years. And Amprius of Menlo Park, CA, received $3 million from the National Institute of Standards and Technology to develop high-performance lithium-ion battery anodes made from silicon nanowires (“More Energy in Batteries”). Both companies are aiming for the electric-car market, hoping to make energy-storage devices that will allow cars to run longer between charges.

Nanomaterials continued to prove their promise in solar cells. Researchers determined that solar cells patterned with nanoscale pillars can convert more energy than smooth ones. The upshot: the performance of cheap materials can be boosted without adding expense, and it’s possible to make them on aluminum foil (“Nanopillar Solar Cells”). This work was done at the University of California, Berkeley, by one of Technology Review’s 35 young innovators of 2009, Ali Javey. Another Berkeley researcher on our young innovators list, Cyrus Wadia, analyzed the abundance and properties of unconventional solar materials and then made strides in developing them. One of the materials is pyrite, also known as fool’s gold, which Wadia is growing as nanocrystals (“Mining Fool’s Gold for Solar”). The advantage of nanocrystals for solar cells is that they can be made into inks and cheaply printed. Meanwhile, one of Wadia’s mentors, Paul Alivisatos, interim director of the Lawrence Berkeley National Laboratory, founded a company to develop high-efficiency, low-cost solar cells based on nanomaterials. Solexant of San Jose, CA, hopes to sell printed nanocrystal solar cells with 10 percent efficiencies for $1 per watt (“Thin-Film Solar with High Efficiency”).

0 comments about this story. Start the discussion »

Tagged: Energy, Materials

Reprints and Permissions | Send feedback to the editor

From the Archives


Introducing MIT Technology Review Insider.

Already a Magazine subscriber?

You're automatically an Insider. It's easy to activate or upgrade your account.

Activate Your Account

Become an Insider

It's the new way to subscribe. Get even more of the tech news, research, and discoveries you crave.

Sign Up

Learn More

Find out why MIT Technology Review Insider is for you and explore your options.

Show Me