Silvestre Taveira Pinho is a Professor in Mechanics of Composites at Imperial College London. His group has developed various analytical and numerical models for failure of composites, some of which currently ship natively in both Abaqus and LS-Dyna. His group has also developed bio-inspired microstructures for composites which lead to an over fivefold increase in energy dissipation during failure.
Silvestre was awarded in 2010 by the European Society for Composite Materials (ESCM) the prize for best young researcher in Composites active in Europe. Silvestre is a member of the Executive Council of the International Community for Composite Materials since 2017 and of the Royal Aeronautical Society Structures & Materials Specialist Committee since 2018. He also served as a member of the Council and of the Executive Committee of the European Society for Composite Materials from 2012 to 2022. Silvestre was awarded two distinct fellowships from the UK’s Engineering and Physical Sciences Research Council (2014 and 2022).
PhD student and research assistant opportunities are often available. Please get in touch if you would like to join my lab.
Silvestre currently supervises with other academics several PhD students and Research Associates. Current and past funding bodies include Research Councils and Industry (EU, EPSRC, FCT, MoD, Airbus, Renault F1 team, Rolls-Royce, BAe systems, amongst others).
You can link to Silvestre's research group by following the link below:
da Costa ROSS, Pinho ST, 2023, Topology optimisation for robust design of large composite structures, Composite Structures, Vol:321, ISSN:0263-8223
et al., 2023, A novel bio-inspired microstructure for improved compressive performance of multidirectional CFRP laminates, Composites Part B: Engineering, Vol:264, ISSN:1359-8368
et al., 2023, Bio-inspired interleaved hybrids: Novel solutions for improving the high-velocity impact response of carbon fibre-reinforced polymers (CFRP), Composites Part B: Engineering, Vol:264, ISSN:1359-8368, Pages:1-11
et al., 2023, Novel zone-based hybrid laminate structures for high-velocity impact (HVI) in carbon fibre-reinforced polymer (CFRP) composites, Composites Science and Technology, Vol:241, ISSN:0266-3538, Pages:1-10
et al., 2023, A novel profiling concept leading to a significant increase in the mechanical performance of metal to composite joints, Composites Part B: Engineering, Vol:261, ISSN:0961-9526, Pages:1-15