Abstract
Quantum walks can be used to model processes such as transport in spin chains and bio-molecules. The enhanced spreading and mixing properties of quantum walks compared with their classical counterparts have been well-studied on regular structures and also shown to be sensitive to defects and imperfections. Using numerical simulation, we study the spreading properties of quantum walks on percolation lattices for both bond and site percolation. The randomly missing edges or sites provide a controlled amount of disorder in the regular Cartesian lattice. In one dimension (the line) we introduce a simple model of quantum tunneling to allow the walk to proceed past the missing edges or sites. This allows the quantum walk to spread faster than a classical random walk for short times, but at longer times the disorder localises the quantum walk. In two dimensions, we observe fractional scaling of the spreading with the number of steps of the walk. For percolation above the 85% level, we obtain faster spreading than classical random walks on the full lattice. © Published under licence by IOP Publishing Ltd 2011.
Original language | English |
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Article number | 012053 |
Number of pages | 6 |
Journal | Journal of Physics: Conference Series |
Volume | 286 |
DOIs | |
Publication status | Published - 4 Apr 2011 |
Event | Condensed Matter and Materials Physics Conference (CMMP10) - Warwick, United Kingdom Duration: 14 Dec 2010 → 16 Dec 2010 |
Keywords
- condensed matter physics
- random processes
- solvents
- Cartesian lattices
- classical counterpart
- fractional scaling
- modeling process
- percolation lattices
- quantum tunneling
- regular structure
- spreading property
- quantum chemistry