Yukihiro Shinozaki

Title: Innovations of Yukihiro Shinozaki

Introduction

Yukihiro Shinozaki is a notable inventor based in Tokyo, Japan. He has made significant contributions to the field of materials science, particularly in the evaluation of thermal properties of glass materials. His innovative approach has led to advancements in understanding the acoustic properties of ultra-low-expansion glass.

Latest Patents

Shinozaki holds a patent for an "Evaluation method for coefficient of thermal expansion of ultra-low-expansion glass material." This patent involves measuring the frequency dependence of acoustic velocities and attenuation coefficients of bulk waves, including longitudinal and shear waves. By analyzing these properties along with density, he reveals fundamental acoustic characteristics and prepares a standard specimen for system calibration. His method allows for the absolute calibration of acoustic velocities and establishes relationships between acoustic properties and the coefficient of thermal expansion. This evaluation method is particularly useful in cases where there is a distribution of characteristics due to periodic striae, enabling accurate assessments of acoustic property distributions.

Career Highlights

Throughout his career, Yukihiro Shinozaki has worked with esteemed institutions such as Tohoku University and Chuo Precision Industrial Co., Ltd. His work has been instrumental in advancing the understanding of material properties, particularly in the context of ultra-low-expansion glass.

Collaborations

Shinozaki has collaborated with notable colleagues, including Jun-ichi Kushibiki and Mototaka Arakawa. These collaborations have further enriched his research and contributed to the development of innovative solutions in materials science.

Conclusion

Yukihiro Shinozaki's contributions to the field of materials science, particularly through his patent on evaluating thermal expansion in glass materials, highlight his role as a significant inventor. His work continues to influence advancements in the understanding of acoustic properties in materials.