sugeta atsushi

スゲタアツシ | sugeta atsushi

Affiliation and department：

Research field (1)： Machine materials and mechanics

Research theme for competitive and other funds (29)：

2022 - 2025 CN実現のための軽量マルチマテリアル輸送車体用高耐損傷性革新的異材接合技術の開発
2019 - 2022 Development of innovative dissimilar material joining technology with high strength and high damage resistance to realize a lightweight multi-material structure
2017 - 2020 Development of innovative welding technology "Ring-shaped welding technology RSW" with high strength and durability
2014 - 2017 Development of Evaluation Method of Film Delamination Strength, and Improvement by Nano-wire
2013 - 2016 Development of high-strength advanced joining technology by fatigue damage mechanism elucidation of joints on the basis of the microscopic internal observation

2012 - 2015 Elucidation of fatigue damage mechanism of adhesive bonding material in severe wet environment by in- situ microscopy

2009 - 2011 Development of Microscopic Observation system based on Atomic Force Microscopy of Fatigue Damage Process under Hydrogen Environment And Investigation of Damage Mechanism

2008 - 2010 Increase in Adhesion Strength of SiC Film with Super Low Friction Coefficient by Formation Technique of Nano-precipitates at Interface

2007 - 2009 How heat treatment reinforces human dentin in pulpless teeth

2006 - 2008 STUDY ON FATIGUE DAMAGE ACCUMULATION UNDER VARIABLE AMPLITUDE LOADING IN ULTRA-HIGH CYCLE REGIME

2006 - 2008 微視損傷機構解明・結晶方位測定による高リサイクル性・耐損傷性ナノ結晶材の創製

2006 - 2007 Fabrication of SiC Film with Ultra-low Friction Coefficient and Evaluation of Friction Property and Delamination Strength

2004 - 2006 Development of Mechanical and Fatigue Testing System for Micro Elements

2003 - 2005 The Production of nanocrystal materials with high fatigue damage resistance based on clarification of non-scale fatigue damage mechanism

2000 - 2002 An Effect of Load Variation on High-cycle Fatigue Behavior and Fatigue Life

2000 - 2001 Meso-scale Nondestructive Observation System of Self-organized Dislocation Network using Scanning Electron Acoustic Microscopy

1999 - 2001 Development of Nano-scale Dynamic Observation System on Fatigue Crack Growth Behavior using Image Processing Technique

1998 - 2000 先進セラミックスの実働荷重における疲労損傷加速現像のナノメカニズム的研究

1997 - 1999 Nano-Fractography Study of Fatigue Crack Growth under Service Loading in Ceramics

1997 - 1999 Fatigue Fracture Mechanism of Advanced Composite Materials (Micro-, Meso- and Macroscopic Approach)

1995 - 1997 Construction of fatigue failure database and development of AI system for failure prevention

1994 - 1995 Study on the mechanism of cumulative fatigue damage of advanced engineering materials under service loadings

1994 - 1994 画像処理を援用したレーザースペックル法による先進複合材料の疲労き裂発生機構の解明

1993 - 1993 多層配線IC基板用絶縁セラミックコーティング簿膜の破壊強度に関する研究

1993 - 1993 高硬度脆性新素材の極高温領域を含む広義疲労特性の破壊力学的研究

1992 - 1993 金属基複合材料の疲労破壊機構の解明

1987 - 1988 Development of Environment Adjusting Device for Fatigue Testing Apparatus Installed to Field Emission Type Scanning Electron Microscope and Study on Crack Closure Mechanism

1987 - 1988 Study on Fatigue Crack Growth Mechanism under Service Loadings with the Aid of Direct Observations by Scanning Electron Microscope

1985 - 1986 Study on Elastic-Plastic Fatigue Crack Growth under Service Loading Conditions

Show all

Papers (231)：

Jinta Arakawa, Hiroki Sato, Ryosuke Handa, Yukihiko Kimura, Shotaro Hashimoto, Hiroyuki Akebono, Atsushi Sugeta. An evaluation of fatigue crack initiation in Ti-6Al-4V alloy by Schmid factor. Materials Science and Technology (United Kingdom). 2023. 39. 5. 557-566
Lei He, Zhilei Wang, Yuki Ogawa, Hiroyuki Akebono, Atsushi Sugeta, Yoshiichirou Hayashi. Machine-learning-based investigation into the effect of defect/inclusion on fatigue behavior in steels. International Journal of Fatigue. 2022. 155. 106597-106597
Yuki Ogawa, Ichiro Ohara, Jinta Arakawa, Hiroyuki Akebono, Atsushi Sugeta. Effects of welding defects on the fatigue properties of spot welded automobile steel sheets and the establishment of a fatigue life evaluation method. Welding in the World. 2022
MINEOKA Seiaro, NAKAHARA Fumiya, ARAKAWA Jinta, OGAWA Yuki, AKEBONO Hiroyuki, Tanaka Kojiro, SUGETA Atsushi. Evaluation of Fatigue Properties Under Repeated Two Step Loading of Al/CFRP Different Material Spot Welding Joints. The Proceedings of the Materials and Mechanics Conference. 2021. 2021. OS0826
Selvaraj, Thomasprabhu, Ishida, Shogo, Arakawa, Jinta, Akebono, Hiroyuki, Sugeta, Atsushi, Aoki, Yasuhiro, Fujii, Hidetoshi. Elucidation of fatigue characteristics and fracture mechanism of friction stir spot-welded tension-shear joint steels. FATIGUE & FRACTURE OF ENGINEERING MATERIALS & STRUCTURES. 2021. 44. 1. 74-84

ｍore...

MISC (101)：

SUGETA Atsushi, AKEBONO Hiroyuki, SHIRAI Yoshihisa, NAKAYAMA Eisuke. GS0214-320 Atomic Force Microscopy of Fatigue Crack Initiation Behavior in α+β Ti-6Al-4V Alloy. 2015. 2015. "GS0214-320-1"-"GS0214-320-2"
Takeuchi Yushi, Akebono Hiroyuki, Kato Masahiko, Sugeta Atsushi. OS8-15 AFM Observation of Small Fatigue Crack Growth Behavior in extruded Mg-Alloy AZ31(Fatigue crack propagation,OS8 Fatigue and fracture mechanics,STRENGTH OF MATERIALS). Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics. 2015. 2015. 14. 125-125
KATO Masahiko, ADACHI Hiranori, AKEBONO Hiroyuki, SUGETA Atsushi. J0470102 Influence of Nano-wire Formed at Interface on Delamination Strength of SiC Film. Mechanical Engineering Congress, Japan. 2015. 2015. "J0470102-1"-"J0470102-4"
KAWASAKI Kenta, AKEBONO Hiroyuki, KATO Masahiko, SUGETA Atsushi. 210 Evaluation of Vacuum Friction Coefficient of SiC Film with Projection Formed by Nanowires. 2015. 2015. 53. "210-1"-"210-2"
KATO Masahiko, FUJITA Tsuguto, AKEBONO Hiroyuki, SUGETA Atsushi. J0410304 Evaluation of Delamination Strength of Hard Film by Convex Edge Indent Method. Mechanical Engineering Congress, Japan. 2014. 2014. "J0410304-1"-"J0410304-5"

ｍore...

※ Researcher’s information displayed in J-GLOBAL is based on the information registered in researchmap. For details, see here.

Return to Previous Page