NLTS Conjecture
In quantum information theory, the No Low-Energy Trivial State (NLTS) conjecture is a precursor to a Quantum PCP theorem (qPCP) and posits the existence of families of Hamiltonians with all low energy states of non-trivial complexity.[1][2][3][4] An NLTS proof would be a consequence of one aspect of qPCP problems --- the inability to certify an approximation of local Hamiltonians via NP-completeness.[2] In other words, an NLTS proof would be one consequence of the QMA complexity of qPCP problems.[5] On a high level, if proved, NLTS would be one property of the non-Newtonian complexity of quantum computation.[5] NLTS and qPCP conjectures posit the near-infinite complexity involved in predicting the outcome of quantum systems with many interacting states.[6] These calculations of complexity would have implications for quantum computing such as the stability of entangled states at higher temperatures, and the occurrence of entanglement in natural systems.[7][6] There is currently a proof of NLTS conjecture published in preprint.[8]
NLTS property
The NLTS property is the underlying set of constraints that forms the basis for the NLTS conjecture.[citation needed]
Definitions
Local hamiltonians
A k-local Hamiltonian (quantum mechanics) [math]\displaystyle{ H }[/math] is a Hermitian matrix acting on n qubits which can be represented as the sum of [math]\displaystyle{ m }[/math] Hamiltonian Terms acting upon at most [math]\displaystyle{ k }[/math] qubits each.
[math]\displaystyle{ H = \sum_{i=1}^m H_i }[/math]
The general k-local Hamiltonian problem is, given a k-local Hamiltonian [math]\displaystyle{ H }[/math], to find the smallest eigenvalue [math]\displaystyle{ \lambda }[/math] of [math]\displaystyle{ H }[/math].[9] [math]\displaystyle{ \lambda }[/math] is is also called the ground state energy of the Hamiltonian.
The family of local Hamiltonians thus arises out of the k-local problem. Kliesch states the following as a definition for local hamiltonians in the context of NLTS:
Let I ⊂ N be an index set. A family of local Hamiltonians is a set of Hamiltonians {H(n)}n∈I, where each H(n) is defined on n finite-dimensional subsystems (in the following taken to be qubits), that are of the form
H(n) = H(n)m
where each Hm(n) acts non-trivially on O(1) qubits. Another constraint is the operator norm of Hm(n) is bounded by a constant independent of n and each qubit is only involved in a constant number of terms Hm(n).[2]
Topological order
In physics, topological order[10] is a kind of order in the zero-temperature phase of matter (also known as quantum matter). In the context of NLTS, Kliesch states "a family of local gapped Hamiltonians is called topologically ordered if any ground states cannot be prepared from a product state by a constant-depth circuit."[2]
NLTS property
Kliesch defines the NLTS property thus:
Let I be an infinite set of system sizes. A family of local Hamiltonians {H(n)}n∈I has the NLTS property if there exists ε > 0 and a function f : N → N such that
- for all n ∈ I, H(n) has ground energy 0
- { 0n | U†H(n)U | 0n i } > εn for any depth-d circuit U consisting of two qubit gates and for any n ∈ I with n ≥ f(d).[2]
NLTS conjecture
There exists a family of local Hamiltonians with the NLTS property.[2]
Quantum PCP conjecture
Proving the NLTS conjecture is an obstacle for resolving the qPCP conjecture, an even harder theorem to prove.[1] The qPCP conjecture is a quantum analogue of the classical PCP theorem. The classical PCP theorem states that satisfiability problems like 3SAT are NP-hard when estimating the max number of clauses that can be simultaneously satisfied in a hamiltonian system.[7] In layman's terms, classical PCP describes the near-infinite complexity involved in predicting the outcome of a system with many resolving states, such as a water bath full of hundreds of magnets.[6] qPCP increases the complexity by trying to solve PCP for quantum states.[6] Though it hasn't been proven yet, a positive proof of qPCP would imply that quantum entanglement in Gibbs states could remain stable at higher energy states above Absolute zero.[7]
NLETS proof
NLTS on its own is difficult to prove, though a simpler No Low-Error Trivial States (NLETS) has been proven, and that proof is a precursor for NLTS.[11]
NLETS is defined as: Let k > 1 be some integer and {Hn}n∈N be a family of k-local Hamiltonians. {Hn}n∈N is NLETS if there exists a constant ε > 0 such that any ε-impostor family F = {ρn}n∈N of {Hn}n∈N is non-trivial.[11]
References
- ↑ 1.0 1.1 "On the NLTS Conjecture" (in en). 2021-06-30. https://simons.berkeley.edu/talks/nlts-conjecture.
- ↑ 2.0 2.1 2.2 2.3 2.4 2.5 Kliesch, Alexander (2020-01-23). "The NLTS conjecture". https://www-m5.ma.tum.de/foswiki/pub/M5/Allgemeines/HS_ResearchSemQIT2019/NLTSConjecture.pdf.
- ↑ Anshu, Anurag; Nirkhe, Chinmay (2020-11-01). Circuit lower bounds for low-energy states of quantum code Hamiltonians. Leibniz International Proceedings in Informatics (LIPIcs). 215. pp. 6:1–6:22. doi:10.4230/LIPIcs.ITCS.2022.6. ISBN 9783959772174. https://ui.adsabs.harvard.edu/abs/2020arXiv201102044A.
- ↑ Freedman, Michael H.; Hastings, Matthew B. (January 2014). "Quantum Systems on Non-$k$-Hyperfinite Complexes: a generalization of classical statistical mechanics on expander graphs". Quantum Information and Computation 14 (1&2): 144–180. doi:10.26421/qic14.1-2-9. ISSN 1533-7146. http://dx.doi.org/10.26421/qic14.1-2-9.
- ↑ 5.0 5.1 "Circuit lower bounds for low-energy states of quantum code Hamiltonians". 2020-11-03. https://deepai.org/publication/circuit-lower-bounds-for-low-energy-states-of-quantum-code-hamiltonians.
- ↑ 6.0 6.1 6.2 6.3 "Computer Science Proof Lifts Limits on Quantum Entanglement" (in en). 2022-07-18. https://www.quantamagazine.org/computer-science-proof-lifts-limits-on-quantum-entanglement-20220718/.
- ↑ 7.0 7.1 7.2 "Research Vignette: Quantum PCP Conjectures" (in en). 2014-09-30. https://simons.berkeley.edu/news/research-vignette-qhc2014.
- ↑ Anshu, Anurag; Breuckmann, Nikolas P.; Nirkhe, Chinmay (2022-07-20). NLTS Hamiltonians from good quantum codes. http://arxiv.org/abs/2206.13228.
- ↑ Morimae, Tomoyuki; Takeuchi, Yuki; Nishimura, Harumichi (2018-11-15). "Merlin-Arthur with efficient quantum Merlin and quantum supremacy for the second level of the Fourier hierarchy". Quantum 2: 106. doi:10.22331/q-2018-11-15-106. ISSN 2521-327X. http://dx.doi.org/10.22331/q-2018-11-15-106.
- ↑ Wen 1990
- ↑ 11.0 11.1 Eldar, Lior (2017). "Local Hamiltonians Whose Ground States are Hard to Approximate". http://ieee-focs.org/FOCS-2017-Papers/3464a427.pdf.