ece 874: physical electronics
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ECE 874: Physical Electronics. Prof. Virginia Ayres Electrical & Computer Engineering Michigan State University [email protected]. Lecture 11, 04 Oct 12. Answers I can find:. Working tools:. Two unknowns y (x) and E in eV from one equation:. - PowerPoint PPT PresentationTRANSCRIPT
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ECE 874:Physical Electronics
Prof. Virginia AyresElectrical & Computer EngineeringMichigan State [email protected]
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Lecture 11, 04 Oct 12
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Answers I can find:
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Working tools:
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Two unknowns (x) and E in eV from one equation:
1. You can find (x) by inspection whenever the Schroedinger equation takes a form with a known solution like and exponential. The standard form equation will also give you one relationship for kx that contains E in eV.
2. Matching (x) at a boundary puts a different condition on kx and setting kx = kx enables you to also solve for E in eV.
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Or equivalent Aexpikx + Bexp-ikx form
Infinite potential well
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With B = 0: tunnelling out of a finite well
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Finite Potential Well:
-∞ to 0 a to +∞0 to a
(nm)
(eV)
Electron energy: E > U0
Electron energy: E < U0
Regions:
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Infinite Potential Well:
-∞ to 0 a to +∞0 to a
(nm)
U (eV) = +∞
Electron energy: E < U0
Regions:
U (eV) = +∞
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Free (between scattering events) particle (e- in I):
-∞ to +∞Region:
Electron energy: E > U0
U (eV) = 0
(nm)
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For all three situations, found:
- (x)
- E (free) or En (infinite and finite wells)
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Example problem: Find energy levels in a finite model for a SQW:
Consider a SQW of width a = 10 nm that is fabricated in GaAs that operates at 300K. The SQW is modelled as a finite well. How many energy levels for an e- exist for:A) U0 = 0.7 eV = half the size of the bandgapB) U0 = 1.4 eV = just under the size of the bandgapC) What is the practical meaning of the limit: = E/U0, 0 < < 1?
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Finite Potential Well
Advantage is: you scale to important parameters: the height U0 and width a.Note: Width a only affects the LHS: the number/spacing of tan curves.
Height U0 affects both sides but practical advantage on RHS plot..
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Example problem: Find (x) for a mixed U0 situation modelled as an infinite/finite well. Consider the case where E < U0-RHS.
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Expected wavefunctions in each of three regions are easy:
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Energy levels: set up the graphical solution:
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units
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Example problem: Find (x) for a mixed U0 situation modelled as an infinite/triangular well
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