Fujitsu, University of Tokyo develop 10G quantum dot laser with temperature-independent output

September 13, 2004 Tokyo--Fujitsu Ltd. and a research group at the University of Tokyo led by Professor Yasuhiko Arakawa, announced the joint development of a quantum dot laser that succeeds in minimizing temperature-sensitive output fluctuations, which was not possible with semiconductor lasers in the past.

Quantum dots are nano-size semiconductors which have completely quantized energy states, thereby enabling the realization of semiconductor lasers featuring extremely high efficiency. Research and development efforts are actively underway to use
indium arsenide quantum dots as optical transmitters in photonic networks. Quantum dot lasers, which incorporate the use of quantum dots in the active light-emitting area region of semiconductor lasers, were proposed in 1982 by Professor Arakawa and Professor
Sakaki of the University of Tokyo

The newly developed quantum dot laser achieves high-speed operation of 10-Gbit/sec across a temperature range of 20°C to 70°C without electrical current adjustments, and has minimal output fluctuations caused by changes in temperature. This breakthrough technology will pave the way for compact, low-cost, and low power-consumption optical transmitters targeting optical metro-access systems and high-speed optical LAN for which further development continues.

Research for this technology was conducted as part of a project supported by the IT program, "The Focused Research and Development Program for the Realization of the World's Most Advanced IT Nation," of Japan's Ministry of Education, Culture, Sports, Science and Technology, and by a project commissioned to the Optoelectronic Industry and Technology Development Associations by the New Energy and Industrial Technology Development Organization of Japan.

Details of the new technology were presented as a post-deadline paper at the European Conference and Exhibition on Optical Communication 2004 that was held in Stockholm last week.

In order to achieve smaller size, lower power consumption, and lower cost, semiconductor lasers used as optical transmitters in metro access optical networks and high-speed optical LANs, there is a need for the lasers to operate at high speeds even at high temperatures without a cooler. Currently, by using strained quantum-wells in the light-emitting area of lasers, semiconductor lasers known as strained quantum-well lasers which operate at high-speeds of 10 Gbits/sec and temperatures up to 85°C are being commercialized for optical networks.

Due to the fact that the optical output of strained quantum-well lasers is sensitive to changes in ambient temperature, it is necessary for the driving current to be adjusted accordingly to ambient temperatures. As such, peripheral circuits are required, thereby hampering reductions of size, cost, and power consumption that are needed for optical metro-access systems and high speed optical LANs.

The new semiconductor laser features extremely minimal characteristic changes that are due to temperature fluctuations, and uses 3-dimensional nano-structured quantum dots in the light-emitting area. Professor Yasuhiko Arakawa of the University of Tokyo theorized in 1982 that the operation of quantum dot lasers does not rely on temperature, but such temperature-independent operation had only been realized at low temperatures thus far.

By increasing optical gain through multi-layering quantum dots into 10 layers, raising the density of each layer, p-doping (inserting a p-type impurity in close proximity to the quantum dots), and by using a laser structure that features low parasitic capacitance for optimized high-speed modulation, the new technology successfully achieves high-speed operation of lasers with temperature-independent output at temperatures exceeding room temperature.

The newly developed quantum dot laser realized high-speed operation of 10 Gbits/sec at wavelengths of 1.3 micrometers which are used for optical transmission systems, for a temperature range from 20°C to 70°C without drive current adjustments. The achieved 10-Gbit/sec high-speed operation is the world's fastest for a quantum dot laser for use in optical telecommunication systems.

Optical output characteristics of the new quantum dot laser were measured and recorded in increments of 10°C. The optical output characteristics were nearly stable independent of temperature, for a 20°C to 50°C range. Even for temperatures exceeding 50°C, efficiency (slope of the characteristics curve) was constant, with minimal variances up to 70°C. In comparison to the performance of conventional strained quantum-well lasers of the past, the new quantum dot laser achieves significantly higher stability of temperature.

The 10-Gbit/sec modulation waveforms of the new quantum dot laser at 20°C and 70°C without constant drive current were verified. Although the current used for the laser is the same at both temperatures, a distinct light output diagram is achieved with the extinction ratio of 7dB. Waveforms for a strained quantum-well laser under the same conditions showed output degradation and pattern disfigurement, with indistinct waveforms.

Average optical output variances measured for 10-Gbit/sec modulation operation across various temperatures depicted that for strained quantum-well lasers, the average optical output dropped significantly at higher temperatures, while the average light output variance for the new quantum dot laser was less than 5% and minimal.

The results achieved with the newly developed quantum dot laser will enable major simplification of circuits to drive lasers, thereby paving the way for optical transmitters that are compact, low-cost, and low power-consuming, for future optical metro-access systems and high-speed optical LANs.

Fujitsu and the University of Tokyo will continue development to extend the temperature range for adjustment-free operation and to achieve single-mode lasing, targeting practical commercial application of this technology by 2007. For more information, visit the web site of the Nanoelectronics Collaborative Research Center, University of Tokyo.