LandauLDLifshitzEM. The Classical Theory of Fields. Oxford: Pergamon Press, 1960.
4.
WatsonA. Physics – where the action is. New Scientist, 30January1986, 42–44.
5.
DiracPAM. The Lagrangian in quantum mechanics. Phys Z Sowyetunion1933; 3(1): 64–72.
6.
EpsteinMMauginGA. Thermomechanics of volumetric growth in uniform bodies. Int J Plasticity2000; 16: 951–978.
7.
GrilloAFedericoSGiaquintaGHerzogWLa RosaG. Restoration of the symmetries broken by reversible growth in hyperelastic bodies. Theoret Appl Mech2003; 30(4): 311–331.
8.
FedericoSGrilloALa RosaGGiaquintaGHerzogW. A transversely isotropic, transversely homogeneous microstructural-statistical model of articular cartilage. J Biomech2005; 38(10): 2008–2018.
9.
GinzburgVLLandauLD. On the theory of superconductivity. Zh Eksperiment Teoret Fiz1965; 20: 1064–1082. [Published in English in: Landau LD, collected papers. Oxford: Pergamon Press, 1965, 546.]
10.
GinzburgVL. On superconductivity and superfluids. In: Nobel Lecture, p. 96–127 (2003)
11.
GrilloACarfagnaMFedericoS. An Allen–Cahn approach to the remodelling of fibre-reinforced anisotropic materials. J Eng Math2018; 109(1): 139–172.
12.
CuomoM. Continuum model of microstructure induced softening for strain gradient materials. Math Mech Solids2019; 24(8): 2374–2391.
13.
EpsteinMde LeónM. Material groupoids and algebroids. Math Mech Solids2019; 24(3): 796–806.
14.
MićunovićMKudrjavcevaL. On inelasticity of damaged quasi rate independent anisotropic materials. Math Mech Solids2019; 24(3): 778–795.
15.
Lo GiudiceAGiammancoGFransosDPreziosiL. Modelling sand slides by a mechanics-based degenerate parabolic equation. Math Mech Solids2019; 24(8): 2558–2575.
16.
WittumRNaegelAHeisigMWittumG. Mathematical modelling of the viable epidermis: Impact of cell shape and vertical arrangement. Math Mech Solids2020; 25(5): 1046–1059.
