Jun 28, 2024 |
(Nanowerk News) South Korean researchers have developed technology to mass-produce quantum dot lasers, widely used in data centers and quantum communications. This breakthrough could reduce semiconductor laser production costs to one-sixth of their current level.
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The Electronics and Telecommunications Research Institute (ETRI) announced that they have, for the first time in Korea, developed technology to mass-produce quantum dot lasers, which were previously limited to research applications. This was achieved using Metal-Organic Chemical Vapor Deposition (MOCVD) systems.
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ETRI’s Optical Communication Components Research Section successfully developed indium arsenide/gallium arsenide (InAs/GaAs) quantum dot laser diodes on gallium-arsenic (GaAs) substrates, suitable for the 1.3 µm wavelength band (1260~1360nm) used in optical communications.
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They reported tehir findings in Journal of Alloys and Compounds (“High-temperature continuous wave-operation of all MOCVD grown InAs/GaAs quantum dot laser diodes with highly strained InGaAs layer and low temperature p-AlGaAs cladding layer”).
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The ETRI Optical Communication Components Research Section has successfully developed indium arsenide/gallium arsenide (InAs/GaAs) quantum dot laser diodes on gallium-arsenic (GaAs) substrates, which are suitable for the 1.3 µm wavelength band (1260~1360nm) used in optical communications.
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Comparison of 2-inch and 6-inch compound semiconductor substrates. (Image: ETRI)
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Traditionally, quantum dot laser diodes were produced using Molecular Beam Epitaxy (MBE), but this method was inefficient due to its slow growth speed, making mass production challenging. By utilizing MOCVD, which has higher production efficiency, the research team has significantly enhanced the productivity of quantum dot laser manufacturing. Quantum dot lasers are known for their excellent temperature characteristics and strong tolerance to substrate defects, allowing for larger substrate areas and consequently lower power consumption and production costs.
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The newly developed quantum dot manufacturing technology boasts high density and good uniformity. The produced quantum dot semiconductor lasers demonstrated continuous operation at temperatures up to 75 degrees Celsius, showing a world-leading achievement in the results obtained via MOCVD.
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Previously, optical telecommunication devices used expensive 2-inch indium phosphide (InP) substrates, resulting in high manufacturing costs. The new technology, using GaAs substrates, which are less than one-third the cost of InP substrates, is projected to reduce the manufacturing cost of communication semiconductor lasers to less than one-sixth.
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This technology’s ability to use large-area substrates enables significant reductions in process time and material costs.
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The research team plans to further optimize and verify this technology to enhance its reliability and transfer it to domestic optical communication companies. These companies will receive key technology and infrastructure support through ETRI’s semiconductor foundry, accelerating the commercialization timeline.
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The anticipated reduction in development time and production costs will enhance product price competitiveness, potentially increasing market share internationally. This advancement is expected to boost the domestic optical communication component industry.
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In modern society, optical communication serves as the backbone of our industry. The research team’s achievement is set to revolutionize the development of optical sources, connecting apartment complexes to large cities and undersea optical cables.
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Professor Dae Myung Geum from Chungbuk National University, a participant in this research, remarked, “The mass production technology for quantum dots can significantly lower the production costs of high-priced optical communication devices, enhancing the competitiveness of the national optical communication component industry and contributing substantially to basic science research.”
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Dr. Ho Sung Kim from ETRI’s Optical Communication Components Research Section stated, “This research outcome is a prime example of securing both commercial viability and fundamental innovation, potentially changing the paradigm of the semiconductor laser industry for optical communications.”
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