The Nanotechnology Research Institute (NRI) of the National Institute of Advanced Industrial Science and Technology (AIST), an independent administrative institution, has developed thins film of oriented single wall carbon nanotubes that emit polarized light.

Preparing high quality thin films is an important prerequisite for many industrial applications of single-wall carbon nanotubes (SWNTs). For conventional methods of making SWNT films, however, it has been very difficult to prevent tubes from aggregating to form bundles. If bundled, strong electronic interactions among tubes would hinder them from exhibiting intrinsic semiconductor properties of SWNT, especially light emission and photoelectric conversion.

The NRI-AIST has succeeded in preparing thin films of uniformly dispersed individual tubes by using gelatin, a biopolymer, as a dispersion medium, and further in orienting separate tubes in a fixed direction by mechanical stretching. (See Photo.) When the film is illuminated with (non- polarized) visible light, an emission of near-infrared rays strongly polarized in the direction of tube alignment is observed (Fig. 1). This is the first implementation of light emitting SWNT film, and the additional feature of polarization is expected to provide a significant momentum for exploiting the optoelectronic functions of SWNTs, as well as for enhancing the understanding of their electronic properties.

The result of the present study appeared in the February 14 issue of the Applied Physics Letters, published by the American Institute of Physics: "Highly polarized adsorption and photoluminescence of stretch-aligned single-wall carbon nanotubes dispersed in gelatin films", Y. Kim, N. Minami and S. Kazaoui, Appl. Phys. Lett. 86, 073103 (2005).

Single wall carbon nanotube (SWNT) is characterized by a tubular structure as if a graphite sheet is rolled up, and has a unique property of becoming either metallic or semiconducting, depending on in which direction the sheet is rolled. Other unique features include energy gap scaling with inverse of the tube diameter despite its single-element (carbon) constitution, marked anisotropy presenting different physical properties in axial and radial directions, and placing all the constituent elements on the surface. Owing to these extraordinary properties, SWNT is expected to work as an unprecedented type of semiconductor. While a number of studies have been made on the use of semiconducting SWNTs for field effect transistors (FET), little progress has been achieved for the use of another important feature of semiconductors, namely, optoelectronics such as photoelectric conversion and electroluminescence. Earlier works showed that surfactant-aided dispersion of SWNTs in water emit light, but thin films prepared from such a system lose the light-emitting capability because of SWNT aggregation. This makes it difficult to investigate the optoelectronic properties of SWNT-based films.

The NRI-AIST has been intensively working on SWNT films over couples of years, in the belief that realization of light-emitting SWNT films must open the way to the practical application of unique optoelectronic features of SWNT.

The NRI-AIST had already succeeded in preparing homogeneous thin films of aligned SWNT by the Langmuir-Blodgett (LB) technique. [AIST Today, October 2002; Japanese Journal of Applied Physics, Part 1, December 2003; and Patent filed July 2004.] While the LB process has an advantage of layer-by-layer deposition, strong aggregation of tubes inevitably occurs during the chemical synthesis of solubilized SWNTs, hindering the intrinsic optoelectronic features of semiconducting SWNTs from being exhibited.

For exploiting the optoelectronic features of the SWNT system, it is essential to isolate and align individual tubes; this is what has been achieved in the present study taking advantage of gelatin's favorable properties, dispersing ability and stretchability.