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Next-Generation Magnetic Devices That Control Light

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Next-Generation Magnetic Devices That Control Light

Magnetic Device That Controls Light

Researchers have developed a new method for creating transparent magnetic materials using laser heating. This breakthrough is crucial for integrating magneto-optical materials with optical circuits, a major challenge in the field. It promises advancements in compact magneto-optical isolators, miniaturized lasers, high-resolution displays, and small optical devices. Credit: SciTechDaily.com

A new laser heating technique by a Japanese research team paves the way for advanced optical communication devices by enabling the integration of transparent magnetic materials into optical circuits.

In a significant advancement in optical technology, researchers from Tohoku University and Toyohashi University of Technology have developed a new method for creating transparent magnetic materials using laser heating. This breakthrough, recently published in the journal Optical Materials, presents a novel approach to integrating magneto-optical materials with optical devices, a long-standing challenge in the field.

“The key to this achievement lies in creating ‘Cerium-substituted Yttrium Iron Garnet (Ce:YIG)’, a transparent magnetic material, employing a specialized laser heating technique,” points out Taichi Goto, associate professor at Tohoku University’s Electrical Communication Research Institute (RIEC) and co-author of the study. “This method addresses the key challenge of integrating magneto-optical materials with optical circuits without damaging them – a problem that has hindered advancements in miniaturizing optical communication devices.”

Laser Heating Transparent Magnetic Material

Laser heating setup for preparing a transparent magnetic material. Credit: Taichi Goto et al.

Magneto-Optical Isolators in Optical Communication

Magneto-optical isolators are vital for ensuring stable optical communication. They act like traffic directors for light signals, allowing them to move in one direction but not the other. Integrating these isolators into silicon-based photonic circuits is challenging due to the high-temperature processes typically involved.

As a result of this conundrum, Goto and his colleagues focused their attention on laser annealing – a technique that selectively heats specific areas of a material by laser. This allows for precise control, influencing only the targeted regions without affecting surrounding areas.

Previous studies had used this to selectively heat bismuth-substituted yttrium iron garnet (Bi: YIG) films deposited on a dielectric mirror. This allows the Bi:YIG to crystalize without affecting the dielectric mirror.

However, when working with Ce:YIG, an ideal material for optical devices due to its magnetic and optical properties, problems arise because exposure to the air results in unwanted chemical reactions.

To avoid this, the researchers engineered a new device that heats materials in a vacuum, i.e., without air, using a laser. This allowed for precise heating of small areas (about 60 micrometers) without altering the surrounding material.

Implications for Optical Technology

“The transparent magnetic material created through this method is expected to significantly enhance the development of compact magneto-optical isolators, crucial for stable optical communication,” adds Goto. “Additionally, it opens avenues for creating powerful miniaturized lasers, high-resolution displays, and small optical devices.”

Reference: “Vacuum laser annealing of magnetooptical cerium-substituted yttrium iron garnet films” by Hibiki Miyashita, Yuki Yoshihara, Kanta Mori, Takumi Koguchi, Pang Boey Lim, Mitsuteru Inoue, Kazushi Ishiyama and Taichi Goto, 14 November 2023, Optical Materials.
DOI: 10.1016/j.optmat.2023.114530

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