# Analysis of Nonlinear Partial Differential Equations

Lead Research Organisation:
University of Oxford

Department Name: Mathematical Institute

### Abstract

Partial differential equations (PDEs) are equations that relate the partial derivatives, usually with respect to space and time coordinates, of unknown quantities. They are ubiquitous in almost all applications of mathematics, where they provide a natural mathematical description of phenomena in the physical, natural and social sciences, often arising from fundamental conservation laws such as for mass, momentum and energy. Significant application areas include geophysics, the bio-sciences, engineering, materials science, physics and chemistry, economics and finance. Length-scales of natural phenomena modelled by PDEs range from sub-atomic to astronomical, and time-scales may range from nanoseconds to millennia. The behaviour of every material object can be modelled either by PDEs, usually at various different length- or time-scales, or by other equations for which similar techniques of analysis and computation apply. A striking example of such an object is Planet Earth itself.Linear PDEs are ones for which linear combinations of solutions are also solutions. For example, the linear wave equation models electromagnetic waves, which can be decomposed into sums of elementary waves of different frequencies, each of these elementary waves also being solutions. However, most of the PDEs that accurately model nature are nonlinear and, in general, there is no way of writing their solutions explicitly. Indeed, whether the equations have solutions, what their properties are, and how they may be computed numerically are difficult questions that can be approached only by methods of mathematical analysis. These involve, among other things, precisely specifying what is meant by a solution and the classes of functions in which solutions are sought, and establishing ways in which approximate solutions can be constructed which can be rigorously shown to converge to actual solutions. The analysis of nonlinear PDEs is thus a crucial ingredient in the understanding of the world about us.As recognized by the recent International Review of Mathematics, the analysis of nonlinear PDEs is an area of mathematics in which the UK, despite some notable experts, lags significantly behind our scientific competitors, both in quantity and overall quality. This has a serious detrimental effect on mathematics as a whole, on the scientific and other disciplines which depend on an understanding of PDEs, and on the knowledge-based economy, which in particular makes increasing use of simulations of PDEs instead of more costly or impractical alternatives such as laboratory testing.The proposal responds to the national need in this crucial research area through the formation of a forward-looking world-class research centre in Oxford, in order to provide a sharper focus for fundamental research in the field in the UK and raise the potential of its successful and durable impact within and outside mathematics. The centre will involve the whole UK research community having interests in nonlinear PDEs, for example through the formation of a national steering committee that will organize nationwide activities such as conferences and workshops.Oxford is an ideal location for such a research centre on account of an existing nucleus of high quality researchers in the field, and very strong research groups both in related areas of mathematics and across the range of disciplines that depend on the understanding of nonlinear PDEs. In addition, two-way knowledge transfer with industry will be achieved using the expertise and facilities of the internationally renowned mathematical modelling group based in OCIAM which, through successful Study Groups with Industry, has a track-record of forging strong links to numerous branches of science, industry, engineering and commerce. The university is committed to the formation of the centre and will provide a significant financial contribution, in particular upgrading one of the EPSRC-funded lectureships to a Chair

### Publications

Kristensen J
(2009)

*Relaxation of signed integral functionals in BV*in Calculus of Variations and Partial Differential Equations
Kreisbeck C
(2015)

*Thin-film limits of functionals on A-free vector fields*in Indiana University Mathematics Journal
Kreisbeck C
(2011)

*Thin-film limits of functionals on A-free vector fields*
Koch G
(2009)

*Liouville theorems for the Navier-Stokes equations and applications*in Acta Mathematica
Knezevic D
(2009)

*A heterogeneous alternating-direction method for a micro-macro dilute polymeric fluid model*in ESAIM: Mathematical Modelling and Numerical Analysis
Knezevic D
(2009)

*BAIL 2008 - Boundary and Interior Layers*
Knezevic D
(2008)

*Spectral Galerkin approximation of Fokker-Planck equations with unbounded drift*in ESAIM: Mathematical Modelling and Numerical Analysis
Kirr E
(2009)

*Asymptotic stability of ground states in 2D nonlinear Schrödinger equation including subcritical cases*in Journal of Differential Equations
Kirchheim B
(2011)

*Automatic convexity of rank-1 convex functions*in Comptes Rendus Mathematique
Kay D
(2009)

*Discontinuous Galerkin Finite Element Approximation of the Cahn-Hilliard Equation with Convection*in SIAM Journal on Numerical Analysis
Jones GW
(2010)

*Modelling apical constriction in epithelia using elastic shell theory.*in Biomechanics and modeling in mechanobiology
Iyer G
(2012)

*Coercivity and stability results for an extended Navier-Stokes system*in Journal of Mathematical Physics
Hudson T
(2015)

*Analysis of Stable Screw Dislocation Configurations in an Antiplane Lattice Model*in SIAM Journal on Mathematical Analysis
Hudson T
(2014)

*Existence and Stability of a Screw Dislocation under Anti-Plane Deformation*in Archive for Rational Mechanics and Analysis
Hopper C
(2016)

*Partial Regularity for Holonomic Minimisers of Quasiconvex Functionals*in Archive for Rational Mechanics and Analysis
Herrmann M
(2010)

*Action Minimising Fronts in General FPU-type Chains*in Journal of Nonlinear Science
Herrmann M
(2009)

*Self-similar solutions for the LSW model with encounters*in Journal of Differential Equations
Herrmann M
(2011)

*On selection criteria for problems with moving inhomogeneities*in Continuum Mechanics and Thermodynamics
Herrmann M
(2009)

*Self-similar solutions with fat tails for a coagulation equation with nonlocal drift*in Comptes Rendus Mathematique
Herrmann M
(2012)

*Kramers and Non-Kramers Phase Transitions in Many-Particle Systems with Dynamical Constraint*in Multiscale Modeling & Simulation
HERRMANN M
(2012)

*OSCILLATORY WAVES IN DISCRETE SCALAR CONSERVATION LAWS*in Mathematical Models and Methods in Applied Sciences
Herrmann M
(2010)

*On selection criteria for problems with moving inhomogeneities*Description | This was a broad grant designed to help consolidate research on nonlinear partial differential equations in the UK. In particular the Oxford Centre for Nonlinear PDE was founded as a result of the grant and is now a leading international centre. As regards specific research advances, these were in various areas of applications of PDE, for example to fluid and solid mechnaics, liquid crystals, electromagnetism, and relativity. |

Exploitation Route | Through publications and consultation with current and former members of OxPDE. |

Sectors | Aerospace, Defence and Marine,Chemicals,Construction,Electronics,Energy,Environment |

URL | https://www0.maths.ox.ac.uk/groups/oxpde |

Description | Advanced Investigator Grant |

Amount | € 2,006,998 (EUR) |

Funding ID | 291053 |

Organisation | European Research Council (ERC) |

Sector | Public |

Country | Belgium |

Start | 03/2012 |

End | 03/2017 |