The Photonics Research Institute (PRI) of the National Institute of Advanced Industrial Science and Technology (AIST), an independent administrative institution, has succeeded in developing, first in the world, a bio-photosensor (biological photo-electronic converter device) to transform light to electricity by combining bio-conjugated materials with semiconductor devices, in collaboration with a study group consisting of scientists from Science University of Tokyo, University of Tokyo, Shizuoka University, and Tokyo Institute of Technology.

This R&D work has been carried out under the Ministry of Education and Science (MEXT) Program, “Creation of Bio-Conjugate Photosensor Nano-Materials”, FY2002~2004, leader: PRI- AIST.

An array of photosensors, i.e. photo-electronic transducers, is called an imaging device. Currently, the main stream of imaging device is filled by semiconductor devices, represented by charge-coupled devices (CCD). The miniaturization of CCD results in a photo acceptance element, as small as 1μm square (1μm=1/1,000,000m). Such a highly integrated device involves certain troubles such as heat dissipation and thermal noises preventing sensitivity from being raised. As a breakthrough solution for this situation, the PRI succeeded in developing a key technology for biological photo-electronic transducer based on the application of bio-conjugated materials in an imaging device.

In this device, photoreceptor protein extracted from cyanobacteria living in a hot spring is combined with conductive molecular wire prepared through organic synthesis and impregnated with gold nano-particles. With an imaging device consisting of assemblies with bio-conjugated materials integrated on semiconductor devices (FET), the operation of bio-electronic transducer was confirmed.

The work will be extended in future to the development of a bio-electronic imaging device with higher degree of integration, leading to the establishment of bio-electronic industrial technology and innovative materials science.

Fig. 1 A schematic drawing of bio-photosensor. A photoreceptor illuminated by light emits electrons, which are led through integrated molecular wirings to gold flow gate of FET and given out as electrical signals.

It is no exaggeration to say that the semiconductor industry is ever seeking for ultra-fast processing and ultra-high packing density, but technological limitations occur one after another. It is claimed that nano-technology is a key technology for solving these troubles and leading the industry of next generation. There is another move to implement innovative devices of ultra-high speed and ultra-high packing density through entirely new technology based on synthetic approach involving molecular and supramolecular components.

While technologies handling biological materials and molecular devices are still in a rudimentary stage, it is expected that they will enable new type of devices characterized by ultra-high packing density and energy saving, which could not be achieved with the semiconductor technology.