Abstract
A quantum simulator is a well-controlled quantum system that can follow the evolution of a prescribed model whose behaviour may be difficult to determine. A good example is the simulation of a set of interacting spins, where phase transitions between various spin orders can underlie poorly understood concepts such as spin liquids. Here we simulate the emergence of magnetism by implementing a fully connected non-uniform ferromagnetic quantum Ising model using up to 9 trapped 171Yb+ ions. By increasing the Ising coupling strengths compared with the transverse field, the crossover from paramagnetism to ferromagnetic order sharpens as the system is scaled up, prefacing the expected quantum phase transition in the thermodynamic limit. We measure scalable order parameters appropriate for large systems, such as various moments of the magnetization. As the results are theoretically tractable, this work provides a critical benchmark for the simulation of intractable arbitrary fully connected Ising models in larger systems.
| Original language | English |
|---|---|
| Article number | 377 |
| Journal | Nature Communications |
| Volume | 2 |
| Issue number | 1 |
| DOIs | |
| State | Published - 2011 |
Funding
We thank D. Huse for help with theoretical understanding of the quantum Ising model and finite-size scaling. This work is supported under Army Research Office under Award No. 911NF0710576 with funds from the DARPA Optical Lattice Emulator Program, IARPA under ARO contract, the NSF Physics at the Information Frontier Program, the European Program on Atomic Quantum Technologies, and the NSF Physics Frontier Center at JQI.