Mile Gu
CQT Fellow
Centre for Quantum Technologies
Associate Professor
School of Physical & Mathematical Sciences – Division of Physics & Applied Physics, Nanyang Technological University
S15-04-18C
Mile Gu is originally from New Zealand and obtained his PhD at the University of Queensland in 2009 under supervision of Michael Nielsen, after which he joined CQT as a Research Fellow. After a faculty position at Tsinghua at the Institute for Interdisciplinary Information Science as a China 1000 Talent in 2013, he returned to Singapore in 2016 as Singapore’s National Research Foundation Fellow. He presently leads the quantum and complexity science initiative – focusing at topics bridging quantum, complexity and information science, and holds joint affiliations with Nanyang Technological University, the Centre for Quantum Technologies and MajuLab.
Preprints & Publications
Quantum-optimal information encoding using noisy passive linear optics
Quantum Limits of Covert Target Detection
Implementing quantum dimensionality reduction for non-Markovian stochastic simulation
Surveying structural complexity in quantum many-body systems
Probe optimization for quantum metrology via closed-loop learning control
Quantifying memory capacity as a quantum thermodynamic resource
Interfering trajectories in experimental quantum-enhanced stochastic simulation
Superior memory efficiency of quantum devices for the simulation of continuous-time stochastic processes
Causal Asymmetry in a Quantum World
Practical unitary simulator for non-Markovian complex processes
The classical-quantum divergence of complexity in modelling spin chains
Overarching framework between Gaussian quantum discord and Gaussian quantum illumination
How discord underlies the noise resilience of quantum illumination
The power of one qumode for quantum computation
Replicating the benefits of closed timelike curves without breaking causality
Local convertibility and edge states in quantum many body systems
Experimental Quantum Computing to Solve Systems of Linear Equations
Local characterization of 1d topologically ordered states
Quantum mechanics can reduce the complexity of classical models
Quantum phases with differing computational power
Encoding Universal Computation in the Ground States of Ising Lattices
Observing the Operational Significance of Discord Consumption
Coherent and incoherent contents of correlations
Reduced-complexity numerical method for optimal gate synthesis
An efficient computational method for the optimal control of higher dimensional quantum systems
Quantum computing with continuous-variable clusters
Gate complexity using dynamic programming
Quantum control via geometry: An explicit example
Building Gaussian cluster states by linear optics
Quantum computation as geometry
Optimal control, geometry, and quantum computing
Entangled-state cycles from conditional quantum evolution
Information-theoretic bound on the energy cost of stochastic simulation
Genuine Multipartite Maximally Nonlocal Mixed States
When is simpler thermodynamically better?
Using quantum theory to reduce the complexity of input-output processes
Continuous variable qumodes as non-destructive probes of quantum systems
Classically Spoofing System Linear Cross Entropy Score Benchmarking
