Opening Statement
Press conference on Fermionic Condensates, Jan. 28, 2004
Deborah S. Jin
NIST physicist, JILA Fellow, and CU adjoint associate professor
Good morning. I am delighted to be here today
to tell you about some exciting new results from our lab. I will
start with a brief description
of what we see in these experiments after which I will be happy
to answer questions. Also, before we get started, I'd like to introduce
my co-authors on this paper published today. This is Cindy Regal,
a
CU graduate student in physics, and Markus Greiner, a CU postdoctoral
researcher.
What we report in this paper is the first observation
of a fermionic condensate in an ultracold gas of atoms. This is
a new form of matter
that is related to a Bose-Einstein condensate and related to
superconductivity. But our fermionic condensate is not a Bose-Einstein
condensate and
not a superconductor but really something new that may link these
two behaviors. Let me try to explain further.
First of all, what we actually do in the lab
is to cool a small amount of gas down to temperatures very near
absolute zero. This gas is confined
inside an ultrahigh vacuum chamber and we manipulate and study
it using magnetic fields and laser light. Now this gas happens
to be made up
of potassium atoms that are fermions.
Let me remind you that all particles, including
atoms, can be classified as fermions or bosons. (This is basic
quantum mechanics). Bosons by
their nature are copy cats; this can lead to Bose-Einstein condensation
where all the bosons do exactly the same thing. Fermions, which
by the way are the building blocks of all visible matter, are instead
by their nature independent thinkers. They never do the same
thing.
Yet we report today a condensate in a gas of
fermionic atoms. How is this possible? It is possible through pairing
of fermions to make bosons.
This is similar to what happens to electrons in superconductivity.
To explain this I will use an analogy illustrated in this poster.
The dancers in the top picture are our individualistic fermionic
atoms.
They look like they are moving quite independent of one another,
and yet if we look more closely there are pairs in this gas. It
is subtle
but you can identify the pairs by the dancers' eye contact and
body language. These pairs are bosons and can undergo condensation.
But how can we see this condensation of pairs
of fermions? We suddenly bring together the two atoms (or dancers
here) in each of these subtle
pairs, as in the bottom picture. When we look at the motion of
these bound pairs, the condensation becomes apparent.
It is this condensation of pairs of fermions
that we created and observed in our very cold potassium gas. In
this poster are three images of
the fermionic condensate, taken for different strengths of the
attraction that causes the pairing. The fermionic condensate appears
in these
images as the large central spike, which corresponds to pairs
of atoms that have near zero velocity.
This fermionic condensate is closely related
to what happens in a superconductor. However, in order to compare
to a superconductor, you have to realize
that our atoms are much heavier than electrons and our gas is
much less dense than a solid. When you account for these differences,
our
atoms are more strongly attracted to each other. And if you could
make electrons in a superconductor do this, you would get a room
temperature
superconductor.
To sum it up, our work, creating this exotic
form of matter æ a
Fermi condensate in an ultracold gas æ provides a new example
of a dramatic quantum behavior. This work gives the scientific community
a new tool for understanding the basic physics behind superconductivity.
At this point, I will be happy to answer your
questions.
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