We analysed and exploited the complex interactions between instabilities and nonlinear dynamics of deformable rods, combining different kinds of instabilities, to obtain new structural behaviours.
We invented a bistable and tetrastable metainterface element, exhibiting nonlinear dynamics and providing a structured material interface for a novel approach to vibration attenuation.
An innovative design of a constrained rod led to a multifaceted bifurcation pattern, with single and double restabilizations. We designed a force-limiter capable of delivering a complex force response upon application of a continuous displacement.
We developed a new theory of thin-walled cylinders characterized by nonlinear hyperelastic constitutive laws to model the necking in thin-walled tubes experimentally observed by us for the first time. Results find applications to the mechanics of soft pneumatic robot arms, arteries, catheters, and stents.
We investigated the effects of new loadings on structural elements, involving transverse, fluidic, configurational, and follower forces. These forces were theoretically and experimentally analyzed when applied to the external coating of an elastic disc, in view of their application to coated fibres, mechanical rollers, morphogenesis of fruits, flexible electronics, and cable-actuated robot arms.
Configurational forces on an elastic rod led to the invention of a new Kapitza inverted pendulum, now made elastic, continuous, and of variable length. The pendulum can yield vibration-based devices with an extended frequency range.
We formulated a new homogenization scheme for 2D grids of elastic rods. We demonstrated that it is possible to design a material that loses stability as the load increases, but then regains stability as the load continues to increase. The structural model introduces a key distinction: ‘islands’ of instability emerge within a broad zone of stability. This unique feature leads to unexpected behaviour, where shear bands appear, vanish and reappear along radial stress paths originating from the unloaded state. This is a groundbreaking result in the design of architected materials.
The design of new materials is a challenge for solid mechanics. We focused the latter on instabilities and fracture, the phenomena that we want to analyse with architected materials.
We investigated shear band and fracture formation, growth, and interaction in materials containing inclusions or voids. We found new strategies for the design of super-resistant materials. In addition, we modelled an apatite used for medical applications.
Architected materials are the contact point between solids and structures, where microstructures are designed and conceived to generate materials with outstanding properties, including the possibility of surpassing the concept of hyper-elasticity. We developed a new homogenization approach (which includes rigid elements, sliders, and Timoshenko deformability) to design new materials yielding unprecedented mechanical properties.