Imogen Camp

DPhil Student
University of Oxford


I am a DPhil student in the Condensed Matter Theory group at the University of Oxford, supervised by Nick G. Jones. My research focuses on mathematical descriptions of interacting quantum many-body systems. Currently, I am studying aspects of the Onsager-integrable chiral clock models, using their underlying algebraic properties to find exact eigenstates and correlations.
  • Matrix-product state skeletons in Onsager-integrable quantum chains
    Imogen Camp, Nick G Jones
    Journal of Statistical Physics
    Matrix-product state (MPS) skeletons are connected networks of Hamiltonians with exact MPS ground states that underlie a phase diagram. Such skeletons have previously been found in classes of free-fermion models. For the translation-invariant BDI and AIII free-fermion classes, it has been shown that the underlying skeleton is dense, giving an analytic approach to MPS approximation of ground states anywhere in the class. In this paper, we partially expose the skeleton in certain interacting spin chains: the N-state Onsager-integrable chiral clock families. We construct MPS that form a dense MPS skeleton in the gapped regions surrounding a sequence of fixed-point Hamiltonians (the generators of the Onsager algebra). Outside these gapped regions, these MPS remain eigenstates, but no longer give the many-body ground state. Rather, they are ground states in particular sectors of the spectrum. Our methods also allow us to find further MPS eigenstates; these correspond to low-lying excited states within the aforementioned gapped regions. This set of MPS excited states goes beyond the previous analysis of ground states on the N = 2 free-fermion MPS skeleton. As an application of our results, we find a closed form for the disorder parameter in a family of interacting models. Finally, we remark that many of our results use only the Onsager algebra and are not specific to the chiral clock model representation.
  • Two-dimensional gauge anomalies and p-adic numbers
    Imogen Camp, Ben Gripaios, Khoi Le Nguyen Nguyen
    Journal of High Energy Physics
    We show how methods of number theory can be used to study anomalies in gauge quantum field theories in spacetime dimension two. To wit, the anomaly cancellation conditions for the abelian part of the local anomaly admit solutions if and only if they admit solutions in the reals and in the p-adics for every prime p and we use this to build an algorithm to find all solutions.