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20 - Techniques for the Quantum Hall Effect

Published online by Cambridge University Press:  24 October 2017

Ramamurti Shankar
Ramamurti Shankar
Affiliation:
Yale University, Connecticut
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Summary

The quantum Hall effect (QHE) has captivated the attention of theorists and experimentalists following its discovery. First came the astounding integer quantum Hall effect (IQHE) discovered by von Klitzing, Dorda, and Pepper in 1980 [1]. Then came the even more mysterious discovery of the fractional quantum Hall effect (FQHE) by Tsui, Störmer, and Gossard in 1982 [2]. Obviously I cannot provide even an overview of this vast subject. Instead, I will select two techniques that come into play in the theoretical description of the FQHE. Along the way I will cover some aspects of IQHE. However, of necessity, I will be forced to leave out many related developments, too numerous to mention. The books in [3–7] and online notes in [8] may help you with further reading.

The first technique is due to Bohm and Pines (BP) [9], and was used to describe an excitation of the electron gas called the plasmon. Since the introduction by BP of this technique in first quantization, it has been refined and reformulated in the diagrammatic framework. I will stick to the wavefunction-based approach because it is very beautiful, and because two of the great problems in recent times – the theory of superconductivity and the theory of the FQHE – were first cracked open by ingenious trial wavefunctions that captured all the essentials. I will introduce the BP approach in terms of the electron gas.

The second technique is Chern–Simons field theory. Originally a product of the imaginations of the mathematicians S. S. Chern and J. Simons, it first entered particle physics in the work of Deser, Jackiw, and Templeton [10], and then condensed matter [11–14]. I will describe its role in the FQHE after introducing the problem to you.

The Bohm–Pines Theory of Plasmons: The Goal

Consider a system of N spinless fermions experiencing the Coulomb interaction

Invoking the Fourier transformation (in unit spatial volume)

we find that

is the density operator (in first quantization), and the q=0 component is presumed to have been neutralized by some background charge.

Type
Chapter
Information
Quantum Field Theory and Condensed Matter
An Introduction
 , pp. 384 - 434
Publisher: Cambridge University Press
Print publication year: 2017

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References

[1] K., von Klitzing, G., Dorda, and M., Pepper, Physical Review Letters, 45, 494 (1980).CrossRef
[2] D., Tsui, H., Stromer, and A., Gossard, Physical Review Letters, 48, 1599 (1982).
[3] R. E., Prange and S. M., Girvin (eds.), The Quantum Hall Effect, Springer-Verlag (1990).
[4] T., Chakraborty and P., Pietiäïnen, The Fractional Quantum Hall Effect: Properties of an Incompressible Quantum Fluid, Springer Series in Solid State Sciences, vol. 85, Springer-Verlag (1988).
[5] A. H., MacDonald (ed.), Quantum Hall Effect: A Perspective, Kluwer (1989).
[6] A., Karlhede, S. A., Kivelson, and S. L., Sondhi, in Correlated Electron Systems, ed. V. J., Emery, World Scientific (1993).
[7] S. D., Sarma and A., Pinczuk, Perspectives in Quantum Hall Effects, Wiley (1997).
[8] There are lectures for entire courses on many websites, for example C. Nayak, “Quantum Condensed Matter Physics,” UCLA notes; D. Tong, “Lectures on the Quantum Hall Effect,” DAMPT, Cambridge University. I am sure there are more such gems to be found.
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[53] B. I., Halperin and A., Stern, Physical Review Letters 80, 5457 (1998). This was a comment on our article [37].
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