Nonuniversal Effects in Bose-Einstein Condensation
In 1924 Albert Einstein predicted the existence of a special type of matter now known as Bose-Einstein condensation. However, it was not until 1995 that simple BEC (Bose-Einstein condensation) was observed in a low-density Bosonic gas. This recent experimental breakthrough has led to renewed theoretical interest in BEC. The focus of my research is to more accurately determine basic properties of homogeneous Bose gases. In particular nonuniversal effects of the energy density and condensate fraction will be explored. The validity of the theoretical predictions obtained is verified by comparison to numerical data from the paper begin{it}Ground State of a Homogeneous Bose Gas: A Diffusion Monte Carlo Calculation end{it} by Giorgini, Boronat, and Casulleras.
end{abstract}
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section{Introduction}
The Bose-Einstein condensation of trapped atoms allows the experimental study of Bose gases with high precision. It is well known that the dominant effects of interactions between the atoms can be characterized by a single number $a$ called the S-wave scattering length. This property is known as begin{it}universalityend{it}. Increasingly accurate measurements will show deviations from universality. These effects are due to sensitivity to aspects of the interatomic interactions other than the scattering length. These effects are known as begin{it}nonuniversalend{it} effects. Intensive theoretical investigations into the homogeneous Bose gas revealed that properties could be calculated using a low-density expansion in powers of $sqrt{na^3}$, where $n$ is the number density. For example the energy density has the expansion
begin{equation}
frac{E}{N} = frac{2 pi na {hbar}^2}{m} Bigg( 1 + frac{128}{15sqrt{pi}}sqrt{na^3} + frac{8(4pi-3sqrt{3})}{3}na^3 (ln(na^3)+c) + ... Bigg)
label{en}
end{equation}
The first term in this expansion is the mean-field approximation and was calculated by Bogoliubov cite{Bog}. The corrections to the mean-field approximation can be calculated using perturbation theory. The coefficient of the $(na^3)^{3/2}$ term was calculated by Lee, Huang, and Yang cite{LHY} and the last term was first calculated by Wu cite{wu}. Hugenholtz and Pines cite{hp} have shown that the constant $c_1$ and the higher-order terms in the expansion are all nonuniversal. Giorgini, Boronat, and Casulleras cite{GBC} have studied the ground state of a homogeneous Bose gas by exactly solving the N-bodied Schr"odinger (to within statistical error) using a diffusion Monte Carlo method.
In section II of this paper, theoretical background relevant to this problem is presented. Section III is a brief summary of the numerical data from Giorgini, Boronat, and Casulleras.
In this experiment there were eight different equations used and they were, molecular equation, total ionic equation, net ionic equation, calculating the number of moles, calculating the theoretical yield and limiting reagent, calculating the mass of〖PbCrO〗_4, calculating actual yield, calculating percent yield (Lab Guide pg.83-85).
The amazing transformation the study of physics underwent in the two decades following the turn of the 20th century is a well-known story. Physicists, on the verge of declaring the physical world “understood”, discovered that existing theories failed to describe the behavior of the atom. In a very short time, a more fundamental theory of the ...
(Misturelli, F. and Hefferman, C., 2008). I wrote this paper in a way that challenges you to put
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Johnson, J. S., & Newport, E. L. (1991). Critical period effects on universal properties of
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In 1924, the Indian physicist S. N. Bose developed an alternate law of radiation which modified Planck's laws to include a new variety of particles, namely, the boson. He sent off his theory to Einstein for revision and translation, and Einstein swiftly came up with some additions to the theory. He expanded the laws to incorporate the mass of the boson, and in doing so theorized a strange phenomenon. He predicted that when atoms of a gas came together under cold enough temperatures, and slowed down significantly, that they would all assume the exact same quantum state. He knew that this slow quantum gas would have strange properties, but wasn't able to get much further by theorizing. This phenomenon, which came to be known as a Bose-Einstien condensate, was an incredible leap in quantum theory, but it wasn't demonstrated until 1995 when Eric A. Cornell, Wolfgang Ketterle and Carl E. Wieman made the first Bose-Einstein condensate with supercooled alkali gas atoms. Although this development didn't come until late in the 20th century, many of these strange properties were observed in supercooled He4 by Dr. Pyotr Kapitsa. Helium became the standard for observing superfluid phenomenon, and most new superfluid properties are still observed first in Helium 4.
Barbara Mowat and Paul Warstine. New York: Washington Press, 1992. Slethaug, Gordon. A. See "Lecture Notes" for ENGL1007.
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... middle of paper ... ... Berk, L. (2007). The 'Standard'.
In my experiment, I will use an overall volume of 50 cm³ of 2moles of
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Kirkpatrick, Larry D. and Gerald F. Wheeler. Physics: A World View, 4th ed. Orlando, FL. Harcourt College Publishers: 2001. p- 365-71