The Calderón problem for third order nonlocal wave equations with time-dependent nonlinearities and potentials

In this article, we study the Calderón problem for nonlocal generalizations of the semilinear Moore–Gibson–Thompson (MGT) equation and the Jordan–Moore–Gibson–Thompson (JMGT) equation of Westervelt-type. These partial differential equations are third order wave equations that appear in nonlinear acoustics, describe the propagation of high-intensity sound waves and exhibit finite speed of propagation. For semilinear MGT equations with nonlinearity g and potential q , we show the following uniqueness properties of the Dirichlet to Neumann (DN) map Λ q , g : (i) If g is a polynomial-type nonlinearity whose m -th order derivative is bounded, then Λ q , g uniquely determines q and ( ∂ τ ℓ g ( x , t , 0 ) ) 2 ≤ ℓ ≤ m . (ii) If g is a polyhomogeneous nonlinearity of finite order L , then Λ q , g uniquely determines q and g . The uniqueness proof for polynomial-type nonlinearities is based on a higher order linearization scheme, while the proof for polyhomogeneous nonlinearities only uses a first order linearization. Finally, we demonstrate that a first linearization suffices to uniquely determine Westervelt-type nonlinearities from the related DN maps. We also remark that all the unknowns, which we wish to recover from the DN data, are allowed to depend on time.