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Quantum gate teleportation

This article will address the topic of Quantum gate teleportation, which has been the subject of great interest and debate in recent decades. Quantum gate teleportation has captured the attention of academics, professionals and the general public due to its impact on various aspects of contemporary society. Throughout this article, Quantum gate teleportation will be analyzed in depth, exploring its origin, evolution, implications and possible future scenarios. Different perspectives, theories and studies will be examined that will shed light on this phenomenon, allowing the reader to obtain a comprehensive and critical understanding of Quantum gate teleportation. Through the detailed examination of this topic, we seek to promote reflection and dialogue around Quantum gate teleportation, contributing to understanding and generating new ideas and approaches to address the challenges it presents.

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Applying a CNOT gate by using gate teleportation. Uses Bell basis measurement (decomposed here into a CNOT, an H, and two measurements), Bell basis initialization (decomposed here into two resets, an H, and a CNOT), and classical feedback in the form of Pauli operations controlled by the measurement results.

Quantum gate teleportation is a quantum circuit construction where a gate is applied to target qubits by first applying the gate to an entangled state and then teleporting the target qubits through that entangled state. [1][2]

This separation of the physical application of the gate from the target qubit can be useful in cases where applying the gate directly to the target qubit may be more likely to destroy it than to apply the desired operation. For example, the KLM protocol can be used to implement a Controlled NOT gate on a photonic quantum computer, but the process can be prone to errors that destroy the target qubits. By using gate teleportation, the CNOT operation can be applied to a state that can be easily recreated if it is destroyed, allowing the KLM CNOT to be used in long-running quantum computations without risking the rest of the computation. Additionally, gate teleportation is a key component of magic state distillation, a technique that can be used to overcome the limitations of the Eastin-Knill theorem. [3]

Quantum gate teleportation has been demonstrated in various types of quantum computers, including linear optical, [4] superconducting quantum computing, [5] and trapped ion quantum computing. [6]

References

  1. ^ Jozsa, Richard (2005). "An introduction to measurement based quantum computation". NATO Science Series, III: Computer and Systems Sciences. Quantum Information Processing-From Theory to Experiment, 199, 137-158. arXiv:quant-ph/0508124. Bibcode:2005quant.ph..8124J.
  2. ^ Colin P. Williams (2010). Explorations in Quantum Computing. Springer. pp. 633–641. ISBN 978-1-4471-6801-0.
  3. ^ Gottesman, Daniel; Chuang, Isaac L. (1999). "Quantum Teleportation is a Universal Computational Primitive". Nature. 402 (6760): 390–393. arXiv:quant-ph/9908010. Bibcode:1999Natur.402..390G. doi:10.1038/46503. S2CID 4411647.
  4. ^ Chou, K.S.; Blumoff, J.Z.; Wang, C.S.; Reinhold, P.C.; Axline, C.J.; Gao, Y.Y.; Frunzio, L.; Devoret, M.H.; Jiang, Liang; Schoelkopf, R.J. (2010). "Teleportation-based realization of an optical quantum two-qubit entangling gate". PNAS. 107 (49): 20869–20874. arXiv:1011.0772. Bibcode:2010PNAS..10720869G. doi:10.1073/pnas.1005720107. PMC 3000260. PMID 21098305.
  5. ^ Gao, Wei-Bo; Poulin, David (2018). "Deterministic teleportation of a quantum gate between two logical qubits". Nature. 561 (7723): 368–373. arXiv:1801.05283. Bibcode:2018Natur.561..368C. doi:10.1038/s41586-018-0470-y. PMID 30185908. S2CID 3820071.
  6. ^ Wan, Yong; Kienzler, Daniel; Erickson, Stephen D.; Mayer, Karl H.; Tan, Ting Rei; Wu, Jenny J.; Vasconcelos, Hilma M.; Glancy, Scott; Knill, Emanuel; Wineland, David J.; Wilson, Andrew C.; Leibfried, Dietrich (2019). "Quantum gate teleportation between separated qubits in a trapped-ion processor". Science. 364 (6443): 875–878. arXiv:1902.02891. Bibcode:2019Sci...364..875W. doi:10.1126/science.aaw9415. PMC 11533827. PMID 31147517. S2CID 119088844.
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