Modeling Quantum Dot Systems as Random Geometric Graphs with Probability Amplitude-Based Weighted Links

This paper focuses on modeling a disorder ensemble of quantum dots (QDs) as a special kind of Random Geometric Graphs (RGG) with weighted links. We compute any link weight as the overlap integral (or electron probability amplitude) between the QDs (=nodes) involved. This naturally leads to a weighted adjacency matrix, a Laplacian matrix, and a time evolution operator that have meaning in Quantum Mechanics. The model prohibits the existence of long-range links (shortcuts) between distant nodes because the electron cannot tunnel between two QDs that are too far away in the array. The spatial network generated by the proposed model captures inner properties of the QD system, which cannot be deduced from the simple interactions of their isolated components. It predicts the system quantum state, its time evolution, and the emergence of quantum transport when the network becomes connected.

Download Full-text

Complexity growth in integrable and chaotic models

Journal of High Energy Physics ◽

10.1007/jhep07(2021)011 ◽

2021 ◽

Vol 2021 (7) ◽

Author(s):

Vijay Balasubramanian ◽

Matthew DeCross ◽

Arjun Kar ◽

Yue Li ◽

Onkar Parrikar

Keyword(s):

Time Evolution ◽

Evolution Operator ◽

Linear Growth ◽

Conjugate Points ◽

Majorana Fermions ◽

Time Evolution Operator ◽

Free Theory ◽

Group Manifold ◽

Geodesic Length ◽

Evolution Trajectory

Abstract We use the SYK family of models with N Majorana fermions to study the complexity of time evolution, formulated as the shortest geodesic length on the unitary group manifold between the identity and the time evolution operator, in free, integrable, and chaotic systems. Initially, the shortest geodesic follows the time evolution trajectory, and hence complexity grows linearly in time. We study how this linear growth is eventually truncated by the appearance and accumulation of conjugate points, which signal the presence of shorter geodesics intersecting the time evolution trajectory. By explicitly locating such “shortcuts” through analytical and numerical methods, we demonstrate that: (a) in the free theory, time evolution encounters conjugate points at a polynomial time; consequently complexity growth truncates at O($$ \sqrt{N} $$ N ), and we find an explicit operator which “fast-forwards” the free N-fermion time evolution with this complexity, (b) in a class of interacting integrable theories, the complexity is upper bounded by O(poly(N)), and (c) in chaotic theories, we argue that conjugate points do not occur until exponential times O(eN), after which it becomes possible to find infinitesimally nearby geodesics which approximate the time evolution operator. Finally, we explore the notion of eigenstate complexity in free, integrable, and chaotic models.

Download Full-text

Disentangling the Time-Evolution Operator of a Single Qubit

Journal of Physics Conference Series ◽

10.1088/1742-6596/839/1/012015 ◽

2017 ◽

Vol 839 ◽

pp. 012015 ◽

Cited By ~ 3

Author(s):

M Enríquez ◽

S Cruz y Cruz

Keyword(s):

Time Evolution ◽

Evolution Operator ◽

Time Evolution Operator ◽

Single Qubit

Download Full-text

Stochastic averaging of the time-evolution operator for quantum systems driven by Ornstein-Uhlenbeck colored noise: A nonperturbative cluster cumulant method

Physical Review E ◽

10.1103/physreve.47.2336 ◽

1993 ◽

Vol 47 (4) ◽

pp. 2336-2356

Author(s):

S. Guha ◽

G. Sanyal ◽

S. H. Mandal ◽

D. Mukherjee

Keyword(s):

Time Evolution ◽

Colored Noise ◽

Evolution Operator ◽

Stochastic Averaging ◽

Quantum Systems ◽

Time Evolution Operator ◽

Cumulant Method

Download Full-text

Statistical Properties of the Time Evolution Operator for Two Coupled Oscillators

Journal of Modern Optics ◽

10.1080/09500349314551411 ◽

1993 ◽

Vol 40 (7) ◽

pp. 1369-1385 ◽

Cited By ~ 11

Author(s):

M. Sebawe Abdalla

Keyword(s):

Time Evolution ◽

Coupled Oscillators ◽

Evolution Operator ◽

Statistical Properties ◽

Time Evolution Operator

Download Full-text

Preparation of Approximate Eigenvector by Unitary Operations on Eigenstate in Abrams-Lloyd Quantum Algorithm

Journal of Computational Methods in Physics ◽

10.1155/2013/235624 ◽

2013 ◽

Vol 2013 ◽

pp. 1-5

Author(s):

Latha S. Warrier

Keyword(s):

Time Evolution ◽

Programming Language ◽

Spin Chain ◽

Evolution Operator ◽

Unitary Operator ◽

Language Model ◽

Quantum Algorithm ◽

Basis Vector ◽

Unitary Matrix ◽

Time Evolution Operator

The Abrams-Lloyd quantum algorithm computes an eigenvalue and the corresponding eigenstate of a unitary matrix from an approximate eigenvector Va. The eigenstate is a basis vector in the orthonormal eigenspace. Finding another eigenvalue, using a random approximate eigenvector, may require many trials as the trial may repeatedly result in the eigenvalue measured earlier. We present a method involving orthogonalization of the eigenstate obtained in a trial. It is used as the Va for the next trial. Because of the orthogonal construction, Abrams-Lloyd algorithm will not repeat the eigenvalue measured earlier. Thus, all the eigenvalues are obtained in sequence without repetitions. An operator that anticommutes with a unitary operator orthogonalizes the eigenvectors of the unitary. We implemented the method on the programming language model of quantum computation and tested it on a unitary matrix representing the time evolution operator of a small spin chain. All the eigenvalues of the operator were obtained sequentially. Another use of the first eigenvector from Abrams-Lloyd algorithm is preparing a state that is the uniform superposition of all the eigenvectors. This is possible by nonorthogonalizing the first eigenvector in all dimensions and then applying the Abrams-Lloyd algorithm steps stopping short of the last measurement.

Download Full-text