Quantum and Gravitational Theory Group

January 15, 2026

Title:

"Filtering" CFTs at large N: Euclidean Wormholes, Closed Universes, and Black Hole Interiors

Abstract: 

Despite its successes, the large-N holographic dictionary remains incomplete. Key features of gravitational path integrals--most notably Euclidean wormholes and the associated failure of factorization--lack a clear interpretation in the standard large-N framework. A related challenge is the possibility of erratic N-dependence in CFT observables, behavior with no evident semiclassical gravitational counterpart.

We argue that these puzzles point to a missing ingredient in the dictionary: a large-N filter. This filter projects out the erratic N-dependence of CFT quantities when mapping them to semiclassical bulk physics, providing an intrinsic boundary definition of gravitational "averages." It also offers a boundary explanation of wormhole contributions and a boundary prediction of their amplitudes, thereby giving a natural resolution of the factorization puzzle. In addition, we derive an infinite tower of inequalities constraining wormhole amplitudes and argue that internal wormholes do not induce random couplings in the low-energy effective theory.

Beyond resolving factorization, the large-N filter supplies a generalized framework from which richer Lorentzian spacetime structures can emerge, including closed universes and black hole interiors. We argue that, as a consequence of erratic large-N behavior, both closed universes and black hole interiors are quantum volatile, and that an AdS spacetime entangled with a baby universe is likewise quantum volatile. This volatility may allow an observer in AdS to infer the existence of the baby universe, whereas for an infalling observer, the ability to make measurements near a black hole horizon may become fundamentally limited--even if they may not live long enough to notice.

January 29, 2026

Title: Comments on the Hartle--Hawking state and quantum mechanics for de Sitter observers

February 5, 2026

Title: Haar random codes attain the quantum Hamming bound, approximately

Abstract: We study the error correcting properties of Haar random codes, in which a K-dimensional code space ⊆ ℂ^N is chosen at random from the Haar distribution. Our main result is that Haar random codes can approximately correct errors up to the quantum Hamming bound, meaning that a set of m Pauli errors can be approximately corrected so long as mK ≪ N. This is the strongest bound known for any family of quantum error correcting codes (QECs), and continues a line of work showing that approximate QECs can significantly outperform exact QECs.

Joint work with Fermi Ma and John Wright: https://arxiv.org/abs/2510.07158 [arxiv.org]

February 12, 2026

Title: Universal randomness in many-body dynamics

Abstract: I will talk about a recent series of works where we discover a universal form of randomness manifest by the simplest kind of quantum many-body dynamics: evolution under a time-independent Hamiltonian. Motivated by initial experimental observations, we find that under a very general set of conditions including evolution under local, physical Hamiltonians, the trajectory of a quantum state traces out a probability distribution over Hilbert space equal to the Haar ensemble deformed to satisfy energy conservation. This is known as the Scrooge ensemble, a family of probability distributions that reveal as little information as possible. This universal behavior allows for quantum information protocols to be adapted to analog quantum dynamics, including fidelity estimation and noise learning. If time permits, I will remark on ongoing work that studies the effect of symmetries on this universality.

Based on PRX 14, 041051 (2024), PRX 15, 031001 (2025), and upcoming work.

February 26, 2026

March 5, 2026

March 19, 2026

March 26, 2026

April 16, 2026

April 23, 2026