Quantum simulation, a subdiscipline of quantum computation, can provide valuable insight into difficult quantum problems in physics or chemistry. Ultracold fermi gases we first consider quantum simulation of ultracold fermi gases with attractive interactions. Ultracold dipolar gas of fermionic 23na40k molecules in their absolute ground state jee woo park, sebastian a. In the last twenty years, ultracold quantum gases have emerged as a flexible platform for. The muri program quantum simulations of condensed matter systems using ultra cold atomic gases has had tremendous impact on the field of quantum simulations. Engineered potentials and dynamics of ultracold quantum gases.
New quantum simulations with ultracold ytterbium gases. Frustrated quantum magnetism with bose gases in triangular. In the first part of the thesis we develop a general method applicable to atoms or molecules or even nanoparticles, to decelerate a hot fast gas beam to zero velocity by using an optical cavity. The high degree of controllability, the novel detection possibilities and the extreme physical parameter regimes that can be reached in these artificial solids provide an exciting complementary setup compared with natural. It has lead to a number of major experimental and theoretical breakthroughs in many research groups. We first consider quantum simulation of ultracold fermi gases. Quantum simulation with ultracold atomic gases in an optical lattice. Often, our work is motivated by unresolved problems from condensed matter physics, which we emulate with trapped atomic gases.
Highlights include the pioneering of quantum gas microscopy, the realization of. Internationaldoctorateinatomic andmolecularphotonics cicloxxx coordinatore prof. The wilhelm and else heraeus seminar research frontiers in ultracold quantum gases, which will bring together about 80 participants in bad honnef germany in december 2018, will provide a comprehensive survey of the different facets of this rapidly evolving subject. Robertorighini new quantum simulations with ultracold ytterbium gases. Both digital and analog quantum simulator constructions for and u 1 lattice gauge theories, with and without matter fields, are presented and related experiments are discussed. In particular, samples of groundstate molecules at ultralow temperatures and high number densities will allow novel quantum gas studies and future applications in quantum information science. Quantum simulations with ultracold quantum gases the examples of implementing analog quantum simulation with cold atoms. Rovibronic groundstate molecules near quantum degeneracy. Quantum simulations of condensed matter systems using. The phenomenon of feshbach resonance provides a means to tune the strength of interactions between atoms over several orders of. The first quantum simulation studies with ultracold fermionic atoms focused on the study of super. Quantum simulation of relativistic fermions with cold atoms. Anindya rastogi successfully defended his msc thesis lightmatter interactions in ultracold gases for quantum simulation and. Examples include experiments conducted on ultracold atoms, quantum simulations, and precision measurements.
In particular, we are interested in questions related to how strong interactions, reduced dimensionality. By following the dynamics of a quantum system of strongly correlated ultracold atoms in an optical lattice, a team of physicists has demonstrated the superiority of a dynamical quantum simulator over stateoftheart numerical calculations. Quantum simulations with ultracold atoms in optical. This is unprecedented in the physics of ultracold quantum gases, says francesca ferlainos team member albert frisch. Quantum gas microscope offers glimpse of quirky ultracold atoms 4 november 2009 a sketch of a quantum gas microscope that images individual ultracold atoms in an optical lattice. Quantum simulators permit the study of quantum systems that are difficult to study in the laboratory and impossible to model with a supercomputer. Ultracold atoms as quantum simulators scitechdaily. Today, his dream has become a reality in laboratories around the world. Quantum simulation of the hubbard model with ultracold fermions in.
Quantum link models extend the concept of lattice gauge theories beyond the wilson formulation, and are well suited for both digital and analog quantum simulation using ultracold atomic gases in optical lattices. A checkerboard pattern of correlations grows over time in quantum gases of ultracold rydberg atoms. Each site of the grid contains one atom that can either be in a rydberg state white or in the ground electronic state black. Quantum gases of dipolar molecules promise to become a platform for precision measurements, quantum information processing, highspeed quantum simulation. Michelle sullivan joins the lab as an msc student, and anindya rastogi continues on as a phd in the group. In our experiments, we use ultracold atom clouds to understand how complex quantum systems behave. In ultracold atom experiments specifically, a bias magnetic field will often serve as a quantization axis and be applied for zeeman splitting. Since quantum simulators do not suffer from the notorious sign problem, they open the door to studies of the realtime evolution of. In this instance, simulators are special purpose devices designed to provide insight about specific physics problems. These properties put these systems in an ideal position for simulating problems that are out of reach for classical computers.
Ultracold quantum gases in triangular optical lattices. We consider the prospects for quantum simulation of condensed matter models exhibiting strong electronphonon coupling using a hybrid platform of trapped lasercooled ions interacting with an ultracold atomic gas. Ultracold quantum gases as a quantum simulator for strongly interacting fluids. Quantum simulation with the use of ultracold atomic gases in optical lattices 6,7. Ultracold dipolar gas of fermionic superscript 23na. The concept of abelian lattice gauge fields is then extended to quantum link models, which are well. Ultracold atoms in optical lattices represent an ideal platform for simulations of quantum manybody problems. Overall, we have accomplished a roadmap of selected areas undergoing rapid progress in quantum optics. Ultracold fermi gases we employ ultracold atomic fermi gases to study quantum manybody physics. Introduction since the achievement of boseeinstein condensation bec we have witnessed enormous progress in experimental and theoretical research on ultracold quantum gases 1. Lindsay j leblanc ultracold quantum gases laboratory. Ultracold atomic gases consist of neutral atoms trapped and cooled.
Quantum simulations with ultracold quantum gases nature. A ultralow noise magnetic field is essential for many branches of scientific research. Quantum simulations of abelian lattice gauge theories with. Pdf ultracold quantum gases offer a unique setting for quantum simulation of interacting.
On the one hand, they can be viewed as experimental quantum simulators for exploring challenging problems of condensedmatter physics such as. H34 a quantum simulator for carrying out complex physics calculations. Fluctuations in quantum degenerate fermi gases by christian sanner abstract ultracold neutral fermi gases provide a novel platform for the experimental quantum simulation of correlated manybody systems. In condensed matter physics, abelian u1 lattice gauge theories arise in the description of certain quantum spin liquids. Volume 91, july 2009 book january 2011 with 297 reads how we measure reads.
Quantum simulation with ultracold atoms conclusion. We are developing experiments to produce and trap ultracold lithium gases and ultracold rubidium gases simultaneously. Ultracold atom in optical lattices is a powerful platform for quantum simulation of condensed matter systems 11. Quantum gas microscope offers glimpse of quirky ultracold. Though very little of the growing body of quantum simulation work has addressed ultrafast phenomena, a robust toolkit exists for controlling and measuring excitations in trapped gases. Ultracold quantum gases offer a unique setting for quantum simulation of interacting manybody systems. This thesis explores feynmans idea of quantum simulations by using ultracold quantum gases. Abelian and nonabelian gauge theories are of central importance in many areas of physics. Quantum simulators may be contrasted with generally programmable digital quantum computers, which would be capable of solving a.
Within this setting, quantum gas microscopes enable single atom observation and manipulation in large samples. Sketch of the superresolution imaging scheme demonstrated by chins team. Quantum gauge theories and ultracold atoms synthetic gauge. Quantum simulation of ultrafast dynamics using trapped. Unprecedented developments in experimental design and precision control have led to quantum gases becoming the preferred playground for designer quantum manybody systems. In the last years these systems have emerged as an ideal playground for the simulation of manybody quantum phenomena thanks. Ultracold atomic gases provide an excellent platform to engineer the models underlying these phenomena, allowing us to study manybody quantum systems in a clean and very well controlled environment.
The key prospect of a quantum simulator is to access ne. Since quantum simulators do not suffer from the notorious sign problem, they open the door to studies of the real. This system naturally posesses a phonon structure, in contrast to the standard optical lattice scenarios usually employed with ultracold atoms in which the. Within this setting,quantumgasmicroscopesenablesingleatomobservationandmanipulationinlarge. These socalled optical lattices act as versatile potential landscapes to trap ultracold quantum gases of bosons and fermions.
Quantum simulation of strongly correlated condensed matter. Quantum simulation with ultracold quantum gases, trapped. A checkerboard pattern of correlations grows over time in quantum gases of ultracold rydberg atoms, mimicking the formation of an antiferromagnetic phase. An overlapping standing wave created by lasers dashed line, displaced by. The 1995 observation of boseeinstein condensation in dilute atomic vapours spawned the field of ultracold, degenerate quantum gases. First, atoms are usually trapped and precooled via laser cooling in a. Undergraduates scott hubele, timothy lee, and daniel to join the lab as summer nserc usracoop researchers. Ultracold atoms platform unprecedented control and versatility in hamiltonians design. Large scale quantum simulations using ultracold atomic gases in optical lattices mo. Quantum simulation of gauge potentials with cold atoms in. It is possible for achieve strongly interacting regime where the fluid becomes. At these temperatures the atoms quantum mechanical properties become important to reach such low temperatures, a combination of several techniques typically has to be used. Leblanc full cv, pdf assistant professor canada research chair in ultracold gases for quantum simulation fellow, canada institute for advanced research quantum materials program lindsay. Our research group at the physikalisches institut of heidelberg university performs fundamental research in the fields of quantum and atomic physics.
Novel quantum states of matter have been successfully achieved for the first time by using ultracold ytterbium atoms in optical lattices. Pdf ultracold quantum gases in triangular optical lattices. These gases constitute a model system of interacting fermions, whose physical behaviour is very rich2 4. Physics watching a quantum magnet grow in ultracold atoms.
Ultracold atoms provide such a window of opportunity designer models achieved through tuning interaction strength, dynamic control, and new experimental probes emulation of simple models relies on a separation of length or energy scales. Our longterm objective is to use these gases as the starting point for producing ultracold lirb molecules, and using them for quantum chemistry, matterwave optics, quantum. Merging of dirac points in a shaken honeycomb lattice. Cesium atoms blue shaded areas are trapped at the sites of an optical lattice.
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