PiolaG.Intorno alle equazioni fondamentali del movimento di corpi qualsivogliono, considerati secondo la naturale loro forma e costituzione. Mem Mat Fis Soc Ital Sci Modena1848; 24(ParteI): 1–186.
2.
dell’IsolaFSeppecherP.Edge contact forces and quasi-balanced power. Meccanica1997; 32(1): 33–52.
3.
AlibertJJSeppecherPdell’IsolaF.Truss modular beams with deformation energy depending on higher displacement gradients. Math Mech Solids2003; 8(1): 51–73.
4.
SeppecherPAlibertJJdell’IsolaF.Linear elastic trusses leading to continua with exotic mechanical interactions. J Phys: Conf Ser2011; 319(1): 012018–012113.
5.
dell’IsolaFSeppecherP.The relationship between edge contact forces, double forces and interstitial working allowed by the principle of virtual power. CR Acad Sci II B1995; 321(8): 303–308.
6.
dell’IsolaFHutterK.Continuum mechanical modelling of the dissipative processes in the sediment-water layer below glaciers. CR Acad Sci II B1997; 325(8): 449–456.
7.
TurcoEMisraAPawlikowskiM, et al. Enhanced Piola-Hencky discrete models for pantographic sheets with pivots without deformation energy: numerics and experiments. Int J Solid Struct2018; 147: 94–109.
8.
BarchiesiEEugsterSRdell’isolaF, et al. Large in-plane elastic deformations of bi-pantographic fabrics: asymptotic homogenization and experimental validation. Math Mech Solids2020; 25(3): 739–767.
9.
dell’IsolaFTurcoEMisraAVangelatosZ, et al. Force-displacement relationship in micro-metric pantographs: experiments and numerical simulations. CR Mécanique2019; 347(5): 397–405.
10.
AugerPLavigneTSmaniottoB, et al. Poynting effects in pantographic metamaterial captured via multiscale DVC. J Strain Anal Eng Des2021; 56(7): 462–477.
11.
SpagnuoloMdell’IsolaFCazzaniA.The study of the genesis of novel mathematical and mechanical theories provides an inspiration for future original research. In: dell’IsolaFEugsterSRSpagnuoloM, et al. (eds) Evaluation of scientific sources in mechanics. Cham: Springer, 2022, pp. 1–73.
12.
dell’IsolaFAndreausUPlacidiL.At the origins and in the vanguard of peridynamics, non-local and higher-gradient continuum mechanics: an underestimated and still topical contribution of Gabrio Piola. Math Mech Solids2015; 20(8): 887–928.
13.
dell’IsolaFDella CorteAGiorgioI.Higher-gradient continua: the legacy of Piola, Mindlin, Sedov and Toupin and some future research perspectives. Math Mech Solids2017; 22(4): 852–872.
14.
EugsterSRdell’IsolaF.Exegesis of the Introduction and Sect. I from “Fundamentals of the Mechanics of Continua” by E. Hellinger. ZAMM-Z Angew Math Mech2017; 97(4): 477–506.
15.
EugsterSRdell’IsolaF.Exegesis of Sect. II and III. A from “Fundamentals of the Mechanics of Continua” by E. Hellinger. ZAMM-Z Angew Math Mech2018; 98(1): 31–68.
16.
EugsterSRdell’IsolaF.Exegesis of Sect. III. B from “Fundamentals of the Mechanics of Continua” by E. Hellinger. ZAMM-Z Angew Math Mech2018; 98(1): 69–105.
17.
WinterTN.The mechanical problems in the corpus of Aristotle. Lincoln, NE: Faculty Publications, Classics and Religious Studies, University of Nebraska at Lincoln, 2007.
dell’IsolaF.Big-(wo)men, tyrants, chiefs, dictators, emperors and presidents. Singapore: Springer, 2019.
20.
QuiligottiSMauginGAdell’IsolaF.An Eshelbian approach to the nonlinear mechanics of constrained solid-fluid mixtures. Acta Mechanica2003; 160(1): 45–60.
21.
SciarraGdell’IsolaFCoussyO.Second gradient poromechanics. Int J Solids Struct2007; 44(20): 6607–6629.
22.
LekszyckiTdell’IsolaF.A mixture model with evolving mass densities for describing synthesis and resorption phenomena in bones reconstructed with bio-resorbable materials. ZAMM-Z Angew Math Mech2012; 92(6): 426–444.
23.
GiorgioIdell’IsolaFAndreausU, et al. On mechanically driven biological stimulus for bone remodeling as a diffusive phenomenon. Biomech Model Mech2019; 18(6): 1639–1663.
24.
RosiGPougetJdell’IsolaF.Control of sound radiation and transmission by a piezoelectric plate with an optimized resistive electrode. Eur J Mech-A/Solids2010; 29(5): 859–870.
25.
DarleuxRLossouarnBGiorgioI, et al. Electrical analogs of curved beams and application to piezoelectric network damping. Math Mech Solids2022; 27(4): 578–601.
26.
dell’IsolaFGiorgioIPawlikowskiM, et al. Large deformations of planar extensible beams and pantographic lattices: heuristic homogenization, experimental and numerical examples of equilibrium. Proc R Soc A: Math Phys Eng Sci2016; 472(2185): 20150790–20150791.
27.
Della CorteAdell’IsolaFEspositoR, et al. Equilibria of a clamped Euler beam (Elastica) with distributed load: large deformations. Math Model Meth Appl Sci2017; 27(8): 1391–1421.
28.
CarcaterraAdell’IsolaFEspositoR, et al. Macroscopic description of microscopically strongly inhomogenous systems: a mathematical basis for the synthesis of higher gradients metamaterials. Arch Ration Mech Anal2015; 218(3): 1239–1262.
29.
dell’IsolaFLekszyckiTPawlikowskiM, et al. Designing a light fabric metamaterial being highly macroscopically tough under directional extension: first experimental evidence. ZAMP-Z Angew Math Phys2015; 66(6): 3473–3498.
30.
TurcoEdell’IsolaFCazzaniA, et al. Hencky-type discrete model for pantographic structures: numerical comparison with second gradient continuum models. ZAMP-Z Angew Math Phys2016; 67: 85–81.
31.
EugsterSdell’IsolaFSteigmannD.Continuum theory for mechanical metamaterials with a cubic lattice substructure. Math Mech Compl Syst2019; 7(1): 75–98.
32.
GiorgioIVaranoVdell’IsolaF, et al. Two layers pantographs: a 2D continuum model accounting for the beams’ offset and relative rotations as averages in SO(3) Lie groups. Int J Solid Struct2021; 216: 43–58.
33.
SteigmannDJdell’IsolaF.Mechanical response of fabric sheets to three-dimensional bending, twisting, and stretching. Acta Mech Sin2015; 31(3): 373–382.
34.
GiorgioIHarrisonPdell’IsolaF, et al. Wrinkling in engineering fabrics: a comparison between two different comprehensive modelling approaches. Proc R Soc A: Math Phys Eng Sci2018; 474(2216): 201800631.
35.
EremeyevVAdell’IsolaFBoutinC, et al. Linear pantographic sheets: existence and uniqueness of weak solutions. J Elasticity2018; 132(2): 175–196.
36.
EremeyevVAdell’IsolaF.On weak solutions of the boundary value problem within linear dilatational strain gradient elasticity for polyhedral Lipschitz domains. Math Mech Solids2022; 27(3): 433–445.
37.
dell’IsolaFSofoneaMSteigmannD (eds) Mathematical modelling in solid mechanics. Singapore: Springer, 2017.
38.
dell’IsolaFEremeyevVAPorubovA (eds) Advances in echanics of microstructured media and structures. Cham: Springer, 2018.
39.
AbaliBAltenbachHdell’IsolaF, et al. (eds) New achievements in continuum mechanics and thermodynamics. Cham: Springer, 2019.
40.
dell’IsolaFSteigmannDJ (eds) Discrete and continuum models for complex metamaterials. Cambridge: Cambridge University Press, 2020.
41.
dell’IsolaFIgumnovL (eds) Dynamics, strength of materials and durability in multiscale mechanics. Cham: Springer, 2021.
42.
dell’IsolaFEugsterSRSpagnuoloM, et al. (eds) Evaluation of scientific sources in mechanics. Cham: Springer, 2022.
43.
GiorgioIPlacidiLBarchiesiE, et al. (eds) Theoretical analyses, computations, and experiments of multiscale materials. Cham: Springer, 2022.
