There are no coherence theorems was mostly a list of many pre-existing results, none of which proved the underlying claim. I will then discuss what variations of the claim we could think off. I will make the underlying claim more precise, at least according to my intuition, and prove that it is false in general. Ie, any strategy that is not a utility maximisation could be made strictly better. Rev.In There are no coherence theorems EJT defines a "coherence theorem" as a theorem that proves maximizing expected utility is the only way to play a game that is not dominated. 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. 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. 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. 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.
#Coherence x alternative free
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. 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. 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.
0 kommentar(er)
