John Botsis

EPFL STI-DO
ME A2 400 (Bâtiment ME)
Station 9
1015 Lausanne

+41 21 693 29 69
Local: ME A2 400
EPFL > STI > STI-DEC > PH-STI

+41 21 693 29 69
EPFL > STI > STI-SGM > SGM-ENS

Domaines de compétences

- Solid and structural mechanics
- Experimental mechanics of advanced materials
- Fracture, fatigue & failure analysis
- Biomechanics & biomaterials

Mission

To develop and use novel experimental techniques to study elementary events of deformation, damage, fracture and fatigue in advanced materials, biomaterials, bone and dental biomechanics as well as durability and reliability of structural components. The experimental results are supported by analytical methods and contemporary numerical tools in order to expand the knowledge base on these fields by basic and applied research, offer the necessary support to industry and provide the best possible quality of training.

Biographie

John (Ioannis) Botsis obtained his diplôme in civil engineering at the University of Patras, Greece in 1979. He continued his education at Case Institute of Technology in Cleveland Ohio/USA, where he received his MS and Ph.D. in 1984. After two years at the research center for national defense in Athens he was nominated assistant professor at the University of Illinois in Chicago, associate in 1991 and full professor in 1995. In 1996, he was nominated professor of solids and structural mechanics at the EPFL.
At EPFL he teaches mechanics of structures and mechanics of continuous media´ at the bachelors level and Fracture mechanics at the masters and doctoral levels. His research covers the mechanics of solids and structures, fracture mechanics and micromechanics of polymers, metals and their composites as well as biomechanics. He is also actively involved in full-filed optical methods for surface strain measurements as well as internal strain measurements using fiber Bragg grating sensors, aimed at characterizing micromechanics of fracture, residual strains and strain distribution in composite laminates for structural monitoring. Funding for his research comes from the Swiss National Science Foundation, State Secretariat for Education and Research and Swiss industry. He retired on February 28, 2020.

Publications

Sélection de publications

G. A. PAPPAS & J. BOTSIS Composites Science and Technology, 197, 2020, 108172	Towards a geometry independent traction-separation and angle relation due to large scale bridging in DCB configuration
L. P. CANAL, M. ALFANO & J. BOTSIS Composites Science and Technology, 139, 2017, pp. 90-98.	A multi-scale based cohesive zone model for the analysis of thickness scaling effects in fiber bridging
L. P. CANAL, G. PAPPAS & J. BOTSIS Composites Science and Technology, 126, 2016, pp. 52-59.	Large scale fiber bridging in mode I intralaminar fracture. An embedded cell approach
J. CUGNONI, R. AMACHER, S. KOHLER, J. BRUNNER, E. KRAMER, C. DRANSFELD, W. SMITH, K. SCOBBIE, L. SORENSEN & J. BOTSIS, ‘ Composites Science and Technology, 168, 2018, pp. 467-477.	Towards Aerospace Grade thin-Ply Composites: Effects of ply thickness, Fibre, Matrix and Interlayer Toughening on Strength and Damage Tolerance
R. AMACHER, J. CUGNONI, J. BOTSIS,, L. SORENSEN, W. SMITH & C. DRANSFELD Composites Science and Technology, 101, 2014, pp. 121132.	Thin Ply Composites: An Experimental Characterization of the Size Effect
G. PAPPAS, L. P. CANAL & J. BOTSIS Composites Part A, 91, 2016, pp. 117–126.	Characterization of intralaminar mode I fracture of AS4/PPS composite using inverse identification and micromechanics
E. FARMAND-ASHTIANI, D. ALANIS, J. CUGNONI & J. BOTSIS Composites Science and Technology, 119, 2015, pp. 85-92.	Delamination in cross-ply laminates: Identification of traction-separation relations and cohesive zone modeling
E. FARMAND-ASHTIANI, J. CUGNONI & J. BOTSIS, Composites Science and Technology, 137, (2016), pp. 52-59.	Effects of large scale bridging in load controlled fatigue delamination of unidirectional carbon-epoxy specimens
F. NAYA, G. PAPPAS & J. BOTSIS Composite Structures, 210, 2019, pp. 877–891	Micromechanical study on the origin of fiber bridging under interlaminar and intralaminar mode I failure
E. FARMAND-ASHTIANI, J. CUGNONI & J. BOTSIS, International Journal of Solids and Structures, 55, 2015, pp. 5865.	Specimen thickness dependence of large scale fiber bridging in mode I interlaminar fracture of carbon epoxy composite
G. PAPPAS & J. BOTSIS International Journal of Solids and Structures, 85-86, 2016, pp. 114-124.	Intralaminar fracture of unidirectional carbon/epoxy composite: experimental results and numerical analysis
C. BLONDEAU, G. PAPPAS & J. BOTSIS Composite Structures, 216, 2019, pp. 464–476	Influence of ply-angle on fracture in anti-symmetric interfaces of CFRP laminates
C. BLONDEAU, G. A. PAPPAS, & J. BOTSIS, Composite Structures, 256, 2021, 113002	Crack propagation in CFRP laminates under Mode I monotonic and fatigue loads: A methodological study
B. D. MANSHADI, A. P. VASSILOPOULOS & J. BOTSIS Composites Science and Technology, 83, 2013, pp. 32�39.	A combined experimental/numerical study of the scaling effects on mode-I delamination of GFRP
G. FROSSARD, J. CUGNONI, T. GMÜR & J. BOTSIS Composites Part A, 91, 2016, pp.1-8.	Mode I Interlaminar Fracture of Carbon Epoxy Laminates: Effects of Ply Thickness
G. A. PAPPAS & J BOTSIS International Journal of Solids and Structures, 191-192, 2020 pp. 42-55	Variations on R-curves and traction-separation relations in DCB specimens loaded under end opening forces or pure moments
M. HERRÁEZ, N. PICHLER, G. PAPPAS, C. BLONDEAU & J. BOTSIS Composites Part A, 134, 2020, 105886	Experimental and Numerical Modelling on Angle-Ply Laminates under Remote Mode II Loading
N. PICHLER, M. HERRÁEZ, J. BOTSIS Composites Part B, 197, 2020, 108089	Mixed-Mode Fracture Response of Anti-symmetric Laminates: Experiments and Modelling
M. HERRÁEZ, N. PICHLER & J. BOTSIS Composite Structures, 247, 2020, 112422	Improving Delamination Resistance through Tailored Defects
G. PAPPAS, S. JONCAS, V. MICHAUD & J. BOTSIS Composite Structures, 181, 2017, pp. 379-390	The Influence of Through-Thickness Reinforcement Geometry and Pattern on Delamination of Fiber-Reinforced Composites: Part II - Modelling
G. PAPPAS, S. JONCAS, V. MICHAUD, & J. BOTSIS Composite Structures, 184, 2018, pp 924-934	The Influence of Through-Thickness Reinforcement Geometry and Pattern on Delamination of Fiber-Reinforced Composites: Part I - Experimental results
S. STUTZ, J. CUGNONI & J. BOTSIS Composites Science and Technology, Vol. 71, 2011, pp. 443-449.	Studies of mode I delamination in monotonic and fatigue loading using FBG wavelength multiplexing

Autres publications

Mechanics of Continuous Media: an Introduction

John Botsis
Michel Deville
2018, First Edition, EPFL Press
CH-1015, Lausanne

Mécanique des milieux continus Une introduction

JOHN BOTSIS
MICHEL DEVILLE
Deuxième édition
2016, Presses polytechniques et universitaires romandes
CH - 1015 Lausanne

INTRODUCTION A LA MECANIQUE DES SOLIDESS ET DES ST

MICHEL DEL PEDRO
THOMAS GMÜR
JOHN BOTSIS
3e édition
2012, Presses polytechinques et universitaires romandes
CH - 1015 Lausanne

Enseignement & Phd

Enseignement

Mechanical Engineering

A dirigé les thèses EPFL de

Bergomi Marzio , Borotto Marco , Farmand Ashtiani Ebrahim , Frieden Jeannot , Frossard Guillaume , Galli Matteo , Kohler Sébastien , Lai Marco , Maleki Milad , Nasri Nassima , Pappas Georgios , Piccinini Marco , Rhême Martin , Sivasubramaniam Venkatesh , Stutz Samuel ,

Cours

Solid mechanics

Modéliser le comportement des solides dans les régimes élastiques, viscoélastiques, et plastiques dans les cas des grandes déformations et déformations infinitésimales.