Saturday 21 March 2009

Rydberg Bohr atoms

Inspired by this post on the Uncertain Principles blog, and a talk I attended by Barry Dunning, I have recently become interested in Rydberg Bohr atoms. When quantum theory was in its infancy, Bohr proposed that electrons orbit atomic nucleii in certain classical orbits, much as planets orbit the Sun in our solar system. However, the biggest problem for this theory was that classical physics requires that charged particles, such as electrons, radiate light as they accelerate, and consequently lose energy. Such electrons would therefore be expected to spiral into the atomic nucleus whilst continuously emitting radiation.

Modern quantum mechanics tells us that electrons are not localised in space, but behave rather as waves, and their classical properties such as positions, momenta, energies and angular momenta may be only fuzzily defined (i.e., we can only know probabilistically the outcomes of their measurements). The electrons only radiate light when they are stimulated to by interacting with passing light (stimulated emission), or by interacting with the vacuum (spontaneous emission).

We expect quantum physics to reduce to classical physics in some limit; the nature of this limit is not well established - it could be the limit of large objects or many interactions with the environment. Rydberg atoms are atoms with an electron excited to a high energy state, such that the electron is likely to be found far away from the nucleus of the atom. In these two recent papers, atoms are excited to a superposition of such Rydberg states so that their outer electrons are fairly localised in space, and orbit the atomic nucleii, much in the way of the Bohr atom. This is a classical limit, in the sense that the electron follows a classical trajectory, however, spontaneous emission of light from such atoms is fairly well suppressed (since the rate of emission scales in inverse proportion of the energy cubed). It actually seems that the lifetimes of the orbits are limited by the dephasing of the wavepacket (i.e., the orbit's quantum nature becomes important), rather than by spontaneous emission.

Nevertheless, it would be interesting to look at the spontaneous emission as a function of the expected angular momentum or position, and compare it to the classical radiation from an orbiting charge. Actually, I think I may attempt these calculations myself. I would normally be loath to describe my research ideas in a public forum incase I get scooped; however, I suspect that no-one reads this blog anyway.

I conclude with a picture of a Bohr atom taken from Wikipedia:
File:Bohr Model.svg

Friday 13 March 2009

Cold Atoms in Optical Lattices

When I told my mum that my research involved optical lattices she said, "lattices - like in pastry". In fact, optical lattices are means of trapping atoms in regular positions by overlapping laser beams. Trapping atoms in such an ordered way has many uses - for instance as a quantum register, or to simulate the behaviour of electrons in metals and semi-conductors (where the lattice is provided by an array of positively charged ions). 

Immanuel Bloch has already written a very good popular-science article about quantum gasses in optical lattices, so I will not re-write it here, but I will take the opportunity to discuss some of the theoretical approaches to modelling such systems. I been asked questions about the Bose-Hubbard model by interested experimentalists, so I will start there:

When there are relatively few atoms in each lattice site, and the lattice is sufficiently strong compared with the energy of the atoms, then the Hubbard (for Fermions) or Bose-Hubbard (for Bosons) model describes the system effectively. I will concentrate on the Bosonic case, since that is closest to my interests.  In this model, the atoms’ behaviour is governed by a tunneling parameter between neighbouring lattice sites, and a parameter describing the interaction between atoms in the same site  (see Dieter Jaksch et al. Phys. Rev. Lett. 81 3108 for details). 

In the Bose-Hubbard system there is a quantum phase transition between superfluid behaviour (the atoms flow freely between lattice sites) and Mott insulator behaviour (atoms become trapped in individual sites) when the tunneling between lattice sites becomes sufficiently weak. The insulating phase is useful when we want, for instance, one atom to be localised in each lattice site to use as a quantum register.

When the number of atoms becomes large, the Hilbert space of the Bose-Hubbard model may become too large to be practical. In this case, in the superfluid (weak lattice) phase, the Gross-Pitaevskii equation describing the mean-field of all the atoms as a single wavefunction is a good model (see Morsch and Oberthaler's review article). I will take this opportunity to publicise my boss's paper on what happens when, for large atom numbers, you start with a superfluid and then ramp up the lattice potential. It turns out that Mott insulator states are hard to achieve in this case. It may be possible to achieve a Mott insulator with large atom numbers, but it looks like doing so will be a challenge.

Much more physics has been done, of course, in optical lattices than I have described. However, I hope this post has given a flavour of the subject.

Sunday 8 March 2009

Hello world

Hello, my name is Andrew, I am a theoretical atomic physicist, and I have spied a "gap in the market" for a blog with the theme of physics of ultra-cold atoms. Inspired by blogs about what are popularly perceived to be the sexier areas of physics (e.g., Cosmic Variance), I think that the exciting and rapidly expanding area of ultra-cold physics is worthy of a blog, and perhaps I am the man to start it. Note that like all bloggers I reserve the right to be self indulgent and blog about other subjects that interest me, even if they are off topic.

A quick word on why the subject of ultra-cold atoms is one of the most interesting in physics: 
Ultra-cold atoms are those cooled and trapped (usually by lasers) at a temperature close to absolute zero. At this temperature, the atoms obey the rules of quantum mechanics and may display the famous effects at which we all like to marvel, such as behaving as waves rather than particles, existing in two places at once, etc. Atoms may entangle with each other allowing amazing technologies that sound like science fiction, such as atomic teleportation, quantum computation and quantum cryptography. The Nobel prize in physics has been awarded to ultra-cold atomic physicists in  19972001   and 2005. Notice that Steve Chu  a Nobel prize winner in 1997 is Obama's new energy secretary.

I hope that the world is as interested in this stuff as much as me. If you work in the field of atomic physics, or are just interested in the subject, if you would like to write posts for this blog let me know using the comments section.