The union result for locally connected subsets I give here may be useful. Rana, S., Parashar, P., Lewenstein, M.: Trace-distance measure of coherence. Shao, L.H., Xi, Z.J., Fan, H., Li, Y.M.: Fidelity and trace-norm distances for quantifying coherence. Theurer, T., Egloff, D., Zhang, L.J., Plenio, M.B.: Quantifying operations with an application to coherence. Korzekwa, K., Czachórski, S., Puchała, Z., Życzkowski, K.: Coherifying quantum channels. A 94, 012326 (2016)ĭana, K.B., Díaz, M.G., Mejatty, M., Winter, A.: Resource theory of coherence: Beyond states. Hu, X.Y.: Channels that do not generate coherence. Yu, X.D., Zhang, D.J., Xu, G.F., Tong, D.M.: Alternative framework for quantifying coherence. Monras, A., Chȩcińska, A., Ekert, A.: Witnessing quantum coherence in the presence of noise. Luo, S.L.: Quantum versus classical uncertainty. 113, 170401 (2014)īromley, T.R., Cianciaruso, M., Adesso, G.: Frozen quantum coherence. Contact us More ways to get Coherence Bundle with Unite Unite allows you to turn any website into a heavily customizable, WebKit-based app. Girolami, D.: Observable measure of quantum coherence in finite dimensional systems. Long, G.L.: Collapse-in and collapse-out in partial measurement in quantum mechanics and its wise interpretation, Science China Physics. Ma, T., Zhao, M.J., Zhang, H.J., Fei, S.M., Long, G.L.: Accessible coherence and coherence distribution. Napoli, C., Bromley, T.R., Cianciaruso, M., Pliani, M., Johnston, N., Adesso, G.: Robustness of coherence: an operational and observable measure of quantum coherence. Huelga, S.F., Plenio, M.B.: Vibrations, quanta and biology. Li, C.M., Lambert, N., Chen, Y.N., Chen, G.Y., Nori, F.: Witnessing quantum coherence: from solid-state to biological systems. Against Sufficiency: The Input and Isolation Arguments Against Sufficiency: The Alternative Coherent Systems Argument Against Necessity: Feasibility. Rebentrost, P., Mohseni, M., Aspuru-Guzik, A.: Role of quantum coherence and environmental fluctuations in chromophoric energy transport. Plenio, M.B., Huelga, S.F.: Dephasing-assisted transport: quantum networks and biomolecules. There are more than 10 alternatives to Coherence X for a variety of platforms, including Mac, Windows, Linux, Online / Web-based and Android. Xu, S.Z., Zhao, T., Chen, Q., Liang, X.G., Guo, Z.Y.: State functions/quantities in thermodynamics and heat transfer. H., Dong, H., Quan, H.T., Sun, C.P.: The uniqueness of the integration factor associated with the exchanged heat in thermodynamics. Watanabe, G.: Heat engines using small quantum systems. Lostaglio, M., Korzekwa, K., Jennings, D., Rudolph, T.: Quantum coherence, time-translation symmetry, and thermodynamics. Lostaglio, M., Jennings, D., Rudolph, T.: Description of quantum coherence in thermodynamic processes requires constraints beyond free energy. Narasimhachar, V., Gour, G.: Low-temperature thermodynamics with quantum coherence. Gour, G., Müller, M.P., Narasimhachar, V., Spekkens, R.W., Halpern, N.Y.: The resource theory of informational nonequilibrium in thermodynamics. It has since been updated to cover the latest Coherence CE 22.06 and Helidon 2.5 releases. 2, 30 (2020)īrandão, F.G.S.L., Horodecki, M., Oppenheim, J., Renes, J.M., Spekkens, R.W.: Resource theory of quantum states out of thermal equilibrium. This article was originally published in Java Magazine, on August 14, 2020. Gyongyosi, L.: Correlation measure equivalence in dynamic causal structures of quantum gravity. Scully, M.O.: Enhancement of the index of refraction via quantum coherence. Glauber, R.J.: Coherent and incoherent states of the radiation field.
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