Using the scanning tunneling microscope (STM), electron formations can be viewed. At left, electrons are surrounded by 48 iron atoms, individually positioned with the same STM used to image them. The image was created and colorized at the IBM Almaden research laboratory in California.
The transition of nanotechnology research into manufactured products is limited today, but some products moved relatively quickly to the marketplace and already are having significant impact. For example, a new form of carbon, —the nanotube—was discovered by Sumio Iijima in 1991. In 1995, it was recognized that carbon nanotubes were excellent sources of field-emitted electrons. By 2000, the “jumbotron lamp,” a nanotube-based light source that uses these field-emitted electrons to bombard a phosphor, was available as a commercial product. (Jumbotron lamps light many athletic stadiums today.) By contrast, the period of time between the modeling of the semiconducting property of germanium in 1931 and the first commercial product (the transistor radio) was 23 years. The discovery of another nanoscale carbon form, C60, the fullerene (also called the buckyball) brought the Nobel Prize in Chemistry in 1996 to Robert F. Curl Jr., Sir Harold W. Kroto, and Richard E. Smalley. It also started an avalanche of research into not only the novel characteristics of C60, but also other nanoscale materials.Nanoscale science was enabled by advances in microscopy, most notably the electron, scanning tunneling and atomic force microscopes, among others. The 1986 Nobel Prize for Physics honored three of the inventors of the electron and scanning tunnel microscopes, Ernst Ruska, Gerd Binnig and Heinrich Rohrer.