1. Research
  2. Publications

Publications

Export 1260 results:
[ Author(Desc)] Title Type Year
A B C D E F G H I J K L M N O P Q R S T U V W X Y Z 
C
A. M. Childs and Kothari, R., Limitations on the simulation of non-sparse Hamiltonians, 2009.
A. M. Childs and Li, T., Efficient simulation of sparse Markovian quantum dynamics, Quantum Information and Computation, vol. 17, pp. 901-947, 2017.
A. M. Childs, Leung, D. W., and Nielsen, M. A., Unified derivations of measurement-based schemes for quantum computation, Physical Review A, vol. 71, no. 3, 2005.
A. M. Childs and Gosset, D., Levinson's theorem for graphs II, Journal of Mathematical Physics, vol. 53, no. 10, p. 102207, 2012.
A. M. Childs, Universal computation by quantum walk, Physical Review Letters, vol. 102, no. 18, 2009.
A. M. Childs, Farhi, E., Goldstone, J., and Gutmann, S., Finding cliques by quantum adiabatic evolution, 2000.
A. M. Childs, Li, T., Liu, J. - P., Wang, C., and Zhang, R., Quantum Algorithms for Sampling Log-Concave Distributions and Estimating Normalizing Constants, Advances in Neural Information Processing Systems (NeurIPS 2022), vol. 35, no. 23205, 2022.
A. M. Childs, Leung, D., Mancinska, L., and Ozols, M., Interpolatability distinguishes LOCC from separable von Neumann measurements, Journal of Mathematical Physics, vol. 54, no. 11, p. 112204, 2013.
A. M. Childs and Kothari, R., Simulating sparse Hamiltonians with star decompositions, 2010.
A. M. Childs, Reichardt, B. W., Spalek, R., and Zhang, S., Every NAND formula of size N can be evaluated in time N^1/2+o(1) on a quantum computer , 2007.
C. Chin, Vuletic, V., Kerman, A. J., Chu, S., Tiesinga, E., Leo, P. J., and Williams, C. J., Ultracold Cs$_2$ Feshbach Spectroscopy, 2003.
C. Chin, Grimm, R., Julienne, P., and Tiesinga, E., Feshbach Resonances in Ultracold Gases, Reviews of Modern Physics, vol. 82, no. 2, pp. 1225 - 1286, 2010.
E. Chitambar, Miller, C., and Shi, Y., Deciding Unitary Equivalence Between Matrix Polynomials and Sets of Bipartite Quantum States, Quantum Information and Computation, vol. 11, no. 9-10, pp. 813–819, 2011.
E. Chitambar, Miller, C., and Shi, Y., Matrix pencils and entanglement classification, Journal of Mathematical Physics, vol. 51, no. 7, p. 072205, 2010.
A. Chotia, Neyenhuis, B., Moses, S. A., Yan, B., Covey, J. P., Foss-Feig, M., Rey, A. Maria, Jin, D. S., and Ye, J., Long-lived dipolar molecules and Feshbach molecules in a 3D optical lattice , Physical Review Letters, vol. 108, no. 8, 2012.
S. - K. Chu, Zhu, G., Garrison, J. R., Eldredge, Z., Curiel, A. Valdés, Bienias, P., Spielman, I. B., and Gorshkov, A. V., Scale-Invariant Continuous Entanglement Renormalization of a Chern Insulator, Phys. Rev. Lett, vol. 122, no. 120502, 2019.
S. - K. Chu, Ma, C. - T., and Wu, C. - H., Two-Dimensional Dilaton Gravity Theory and Lattice Schwarzian Theory, 2018.
K. - M. Chung, Lee, Y., Lin, H. - H., and Wu, X., Constant-round Blind Classical Verification of Quantum Sampling, 2020.
M. Ciamp, Cojocaru, A., Kashefi, E., and Mantri, A., Secure Quantum Two-Party Computation: Impossibility and Constructions, 2020.
Z. - P. Cian, Zhu, G., Chu, S. - K., Seif, A., DeGottardi, W., Jiang, L., and Hafezi, M., Photon pair condensation by engineered dissipation, Phys. Rev. Lett. , vol. 123, no. 063602, 2019.
Z. - P. Cian, Hafezi, M., and Barkeshli, M., Extracting Wilson loop operators and fractional statistics from a single bulk ground state, 2022.
R. Clifton, Bub, J., and Halvorson, H., Characterizing quantum theory in terms of information-theoretic constraints, Foundations of Physics, vol. 33, no. 11, pp. 1561 - 1591, 2002.
I. C. Cloët, Dietrich, M. R., Arrington, J., Bazavov, A., Bishof, M., Freese, A., Gorshkov, A. V., Grassellino, A., Hafidi, K., Jacob, Z., McGuigan, M., Meurice, Y., Meziani, Z. - E., Mueller, P., Muschik, C., Osborn, J., Otten, M., Petreczky, P., Polakovic, T., Poon, A., Pooser, R., Roggero, A., Saffman, M., VanDevender, B., Zhang, J., and Zohar, E., Opportunities for Nuclear Physics & Quantum Information Science, 2019.
N. J. Coble and Coudron, M., Quasi-polynomial Time Approximation of Output Probabilities of Constant-depth, Geometrically-local Quantum Circuits, Accepted to QIP 2021, 2020.
N. J. Coble, Coudron, M., Nelson, J., and Nezhadi, S. Sajjad, Hamiltonians whose low-energy states require $\Omega(n)$ T gates, 2023.