R3c / Pisces Trading Company LLC / Macmillan Publishers Limited. / South Bay Technology / Suzuki / Baker S. P. / /
Country
United States / Mexico / / /
Facility
MIT Institute / Massachusetts Institute of Technology / /
IndustryTerm
energy dissipation efficiency resulting / indentation site / energy-dissipating mechanisms / transparent armour systems / nanoscopic energy dissipation processes / energy dissipation / biological structural material systems / energy dissipation density / inelastic energy dissipating mechanisms / steel plates / considerable energy / online version / driven energy dissipating deformation mechanisms / higher total deformation energy / electron microscopy imaging / material systems / Energy dissipation enhancement resulting / electron microscopic imaging / e-type / increased energy dissipation / increased energy dissipation efficiency / energy dissipation mechanisms / imaging / space / penetration site / increased energy dissipation density / energy / /
Organization
MIT Center for Materials Science and Engineering / US Army Research Office / National Science Foundation / Cornell / Department of Materials Science and Engineering / MIT Institute for Soldier Nanotechnologies / Massachusetts Institute of Technology / /
Person
SPM IIIA / Barber / Ling Li / J. C. Weaver / Christine Ortiz / carried out using a Digital Instruments Multimode SPM IIIA / /
Position
Author / D. J. / Assistant Secretary of Defense for Research and Engineering / Representative / /
Pervasive nanoscale deformation twinning as a catalyst for efficient energy dissipation in a bioceramic armour