My Account Log in

3 options

Electronic transport in mesoscopic structures : the quantum Brownian motion picture / Hangmo Yi.

LIBRA QC001 1996 .Y51
Loading location information...

Available from offsite location This item is stored in our repository but can be checked out.

Log in to request item
LIBRA Diss. POPM1996.283
Loading location information...

Available from offsite location This item is stored in our repository but can be checked out.

Log in to request item
LIBRA microfilm P38:1996
Loading location information...

Mixed Availability Some items are available, others may be requested.

Log in to request item
Format:
Book
Manuscript
Microformat
Thesis/Dissertation
Author/Creator:
Yi, Hangmo.
Contributor:
Kane, C. L. (Charles L.), advisor.
University of Pennsylvania.
Language:
English
Subjects (All):
Penn dissertations--Physics.
Physics--Penn dissertations.
Local Subjects:
Penn dissertations--Physics.
Physics--Penn dissertations.
Physical Description:
xii, 173 leaves : illustrations ; 29 cm
Production:
1996.
Summary:
We study the quantum transport of electrons in mesoscopic structures using the picture of quantum Brownian motion in a periodic potential.
First, resonant tunneling between fractional quantum Hall edge states is considered in the Luttinger liquid picture. For the $\nu=1/3$ quantum Hall liquid, the resonance line shape is described by a universal function whose width scales to zero at T = 0. We calculate the scaling function using a Monte Carlo simulation method. Our results confirm the scaling theory and predict the explicit form of the scaling function over the entire width of the resonance.
Then, we investigate a quantum dot in the integer quantum Hall effect regime that is strongly coupled to a lead via a point contact. We find that even when the point contact is perfectly transmitting, important features of Coulomb blockade persist. In particular, the tunneling into the dot from a second weakly coupled lead is suppressed, showing features that can be ascribed to cotunneling. Weak backscattering at the point contact gives rise to oscillations in both the tunneling conductance G and the differential capacitance C as a function of gate voltage. We point out that the dimensionless ratio $\xi$ between the fractional oscillations in G and C is an intrinsic property of the dot. We compute $\xi$ within two models of electron-electron interactions. The role of additional channels is also discussed.
Finally, we study the general problem of quantum Brownian motion in a periodic potential. In D = 1 dimension, there are two T = 0 phases: a localized phase with zero-temperature mobility $\mu$ = 0 and an extended phase with $\mu$ unaffected by the periodic potential. For D $>$ 1, however, non-symmorphic lattices such as honeycomb lattice and its D-dimensional generalization have an intermediate phase with a universal mobility $\mu\sp*$ between 0 and the maximum perfect value. We study this intermediate fixed point in perturbatively accessible regimes. In addition, by mapping this problem to the Toulouse limit of the (D + 1)-channel Kondo model we can exactly compute $\mu\sp*$ using results known from conformal field theory. Experimental implications are discussed in connection to resonant tunneling in Coulomb blockade structures.
Notes:
Supervisor: Charles L. Kane.
Thesis (Ph.D. in Physics) -- University of Pennsylvania, 1996.
Includes bibliographical references.
University Microfilms order no.: 96-36236.
OCLC:
187450217

The Penn Libraries is committed to describing library materials using current, accurate, and responsible language. If you discover outdated or inaccurate language, please fill out this feedback form to report it and suggest alternative language.

Find

Home Release notes

My Account

Shelf Request an item Bookmarks Fines and fees Settings

Guides

Using the Find catalog Using Articles+ Using your account