On the Complexity of Commuting Local Hamiltonians, and Tight Conditions for Topological Order in Such Systems

D. Aharonov, Lior Eldar
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引用次数: 62

Abstract

The local Hamiltonian problem plays the equivalent role of SAT in quantum complexity theory. Understanding the complexity of the intermediate case in which the constraints are quantum but all local terms in the Hamiltonian commute, is of importance for conceptual, physical and computational complexity reasons. Bravyi and Vyalyi showed in 2003, using a clever application of the representation theory of C*-algebras, that if the terms in the Hamiltonian are all two-local, the problem is in NP, and the entanglement in the ground states is local. The general case remained open since then. In this paper we extend this result beyond the two-local case, to the case of three-qubit interactions. We then extend our results even further, and show that NP verification is possible for three-wise interaction between qutrits as well, as long as the interaction graph is planar and also " nearly Euclidean & quot, in some well-defined sense. The proofs imply that in all such systems, the entanglement in the ground states is local. These extensions imply an intriguing sharp transition phenomenon in commuting Hamiltonian systems: the ground spaces of 3-local " physical & quot, systems based on qubits and qutrits are diagonalizable by a basis whose entanglement is highly local, while even slightly more involved interactions (the particle dimensionality or the locality of the interaction is larger) already exhibit an important long-range entanglement property called Topological Order. Our results thus imply that Kitaev's celebrated Toric code construction is, in a well defined sense, optimal as a construction of Topological Order based on commuting Hamiltonians.
这类系统中可交换局部哈密顿量的复杂性及拓扑有序的紧条件
局部哈密顿问题在量子复杂性理论中起着与SAT等价的作用。理解中间情况的复杂性,其中约束是量子的,但都是哈密顿交换中的局部项,对于概念、物理和计算复杂性的原因是重要的。Bravyi和Vyalyi在2003年通过对C*代数表示理论的巧妙应用表明,如果哈密顿函数中的项都是双局部的,那么问题就在NP中,基态的纠缠是局部的。从那以后,这个案子一直悬而未决。在本文中,我们将这一结果从双局部情况扩展到三量子比特相互作用的情况。然后,我们进一步扩展了我们的结果,并表明只要交互图是平面的,并且在某种定义良好的意义上“接近欧几里得”,那么对于元素之间的三向交互,NP验证也是可能的。证明表明,在所有这样的系统中,基态的纠缠都是局域的。这些扩展暗示了交换哈密顿系统中一个有趣的尖锐跃迁现象:基于量子位和量子位的三局部“物理”系统的地面空间可以通过纠缠高度局域的基对角化,而甚至稍微涉及更多的相互作用(粒子维度或相互作用的局域性更大)已经表现出重要的远程纠缠特性,称为拓扑顺序。因此,我们的结果表明,Kitaev著名的托利码结构,在一个明确的意义上,作为基于交换哈密顿算子的拓扑序结构是最优的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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