One of the unique features of discrete-time quantum walks is called trapping, meaning the inability of the quantum walker to completely escape from its initial position, although the system is translationally invariant. The effect is dependent on the dimension and the explicit form of the local coin. A four-state discrete-time quantum walk on a square lattice is defined by its unitary coin operator, acting on the four-dimensional coin Hilbert space. The well-known example of the Grover coin leads to a partial trapping, i.e., there exists some escaping initial state for which the probability of staying at the initial position vanishes. On the other hand, some other coins are known to exhibit strong trapping, where such an escaping state does...
Quantum Walk (QW) has very different transport properties to its classical counterpart due to interf...
In this paper discrete quantum walks with different coins used for odd and even time steps are studi...
Abstract Quantum Walk (QW) has very different transport properties to its classical counterpart due ...
One of the unique features of discrete-time quantum walks is called trapping, meaning the inability ...
Localization phenomena of quantum walks makes the propagation dynamics of a walker strikingly differ...
Quantum walks, both discrete (coined) and continuous time, form the basis of several recent quantum ...
We examine the physical implementation of a discrete time quantum walk with a four-dimensional coin....
Quantum random walk in a two-dimensional lattice with randomly distributed traps is investigated. Di...
In discrete time, coined quantum walks, the coin degrees of freedom offer the potential for a wider ...
We propose a novel implementation of discrete time quantum walks for a neutral atom in an array of o...
Quantum walks have emerged as an interesting approach to quantum information processing, exhibiting ...
In this paper, we present a study of discrete time quantum walks whose underlying graph is a d-dimen...
In this article, we undertake a detailed study of the limiting behavior of a three-state discrete-ti...
25 pages, 13 figuresThe aim of this paper is to build quantum circuits that implement discrete-time ...
The quantum random walk has been much studied recently, largely due to its highly nonclassical behav...
Quantum Walk (QW) has very different transport properties to its classical counterpart due to interf...
In this paper discrete quantum walks with different coins used for odd and even time steps are studi...
Abstract Quantum Walk (QW) has very different transport properties to its classical counterpart due ...
One of the unique features of discrete-time quantum walks is called trapping, meaning the inability ...
Localization phenomena of quantum walks makes the propagation dynamics of a walker strikingly differ...
Quantum walks, both discrete (coined) and continuous time, form the basis of several recent quantum ...
We examine the physical implementation of a discrete time quantum walk with a four-dimensional coin....
Quantum random walk in a two-dimensional lattice with randomly distributed traps is investigated. Di...
In discrete time, coined quantum walks, the coin degrees of freedom offer the potential for a wider ...
We propose a novel implementation of discrete time quantum walks for a neutral atom in an array of o...
Quantum walks have emerged as an interesting approach to quantum information processing, exhibiting ...
In this paper, we present a study of discrete time quantum walks whose underlying graph is a d-dimen...
In this article, we undertake a detailed study of the limiting behavior of a three-state discrete-ti...
25 pages, 13 figuresThe aim of this paper is to build quantum circuits that implement discrete-time ...
The quantum random walk has been much studied recently, largely due to its highly nonclassical behav...
Quantum Walk (QW) has very different transport properties to its classical counterpart due to interf...
In this paper discrete quantum walks with different coins used for odd and even time steps are studi...
Abstract Quantum Walk (QW) has very different transport properties to its classical counterpart due ...