omg blueprint for trapped ion quantum computing with metastable states

被引：43

作者：

Allcock, D. T. C. ^{[1
]}

Campbell, W. C. ^{[2
,3
,4
]}

Chiaverini, J. ^{[5
,6
]}

Chuang, I. L. ^{[7
]}

Hudson, E. R. ^{[2
,3
,4
]}

Moore, I. D. ^{[1
]}

Ransford, A. ^{[2
,8
]}

Roman, C. ^{[2
,8
]}

Sage, J. M. ^{[5
,6
]}

Wineland, D. J. ^{[1
]}

机构：

[1] Univ Oregon, Dept Phys, Eugene, OR 97403 USA

[2] Univ Calif Los Angeles, Dept Phys & Astron, Los Angeles, CA 90095 USA

[3] Univ Calif Los Angeles, Ctr Quantum Sci & Engn, Los Angeles, CA 90095 USA

[4] Univ Calif Los Angeles, Challenge Inst Quantum Computat, Los Angeles, CA 90095 USA

[5] MIT, Lincoln Lab, Lexington, MA 02420 USA

[6] MIT, 77 Massachusetts Ave, Cambridge, MA 02139 USA

[7] MIT, Dept Phys, Dept Elect Engn & Comp Sci, Ctr Ultracold Atoms, Cambridge, MA 02139 USA

[8] Honeywell Quantum Solut, Broomfield, CO 80021 USA

来源：

APPLIED PHYSICS LETTERS | 2021年 / 119卷 / 21期

关键词：

All Open Access; Green;

D O I：

10.1063/5.0069544

中图分类号：

O59 [应用物理学];

学科分类号：

摘要：

Quantum computers, much like their classical counterparts, will likely benefit from flexible qubit encodings that can be matched to different tasks. For trapped ion quantum processors, a common way to access multiple encodings is to use multiple, co-trapped atomic species. Here, we outline an alternative approach that allows flexible encoding capabilities in single-species systems through the use of long-lived metastable states as an effective, programmable second species. We describe the set of additional trapped ion primitives needed to enable this protocol and show that they are compatible with large-scale systems that are already in operation. Published under an exclusive license by AIP Publishing.

引用

页数：6

共 50 条

[31] Reversible Measurement on Quantum States of Trapped-Ion Qubits
Xu You-Yang
Zhou Fei
COMMUNICATIONS IN THEORETICAL PHYSICS, 2010, 53 (03) : 469 - 472
[32] Experimental Creation and Measurement of Motional Quantum States of a Trapped Ion
Meekhof, D. M.
Leibfried, D.
Monroe, C.
King, B. E.
Itano, W. M.
Wineland, D. J.
BRAZILIAN JOURNAL OF PHYSICS, 1997, 27 (02) : 178 - 192
[33] Generation of squeezed quantum states of a single trapped cold ion
Zhang Miao
Jia Huan-Yu
Ji Xiao-Rui
Si Kun
Wei Lian-Fu
ACTA PHYSICA SINICA, 2008, 57 (12) : 7650 - 7657
[34] Quantum computing with trapped ions
Monroe, C.
Itano, W.M.
Kielpinski, D.
King, B.E.
Myatt, C.J.
Sackett, C.A.
Turchette, Q.A.
Wineland, D.J.
IQEC, International Quantum Electronics Conference Proceedings, 1999,
[35] Quantum computing with trapped ions
Hughes, RJ
METHODS FOR ULTRASENSITIVE DETECTION, 1998, 3270 : 120 - 130
[36] Quantum computing with trapped ions
Haffner, H.
Roos, C. F.
Blatt, R.
PHYSICS REPORTS-REVIEW SECTION OF PHYSICS LETTERS, 2008, 469 (04): : 155 - 203
[37] Blueprint for quantum computing using electrons on helium
Kawakami E.
Chen J.
Benito M.
Konstantinov D.
Physical Review Applied, 2023, 20 (05)
[38] Hybrid Quantum Computing with Conditional Beam Splitter Gate in Trapped Ion System
Gan, H. C. J.
Maslennikov, Gleb
Tseng, Ko-Wei
Nguyen, Chihuan
Matsukevich, Dzmitry
PHYSICAL REVIEW LETTERS, 2020, 124 (17)
[39] Motional quantum states of a trapped ion: Measurement and its back action
Wallentowitz, S
Vogel, W
PHYSICAL REVIEW A, 1996, 54 (04): : 3322 - 3334
[40] Preparation of motional macroscopic quantum-interference states of a trapped ion
Zheng, Shi-Biao
Physical Review A. Atomic, Molecular, and Optical Physics, 1998, 58 (01):

← 1 2 3 4 5 →