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General Concerns |
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Name some optoelectronic devices. List their strengths and weaknesses in comparison to competing
products / technologies |
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Identify and discuss specific properties of some optoelectronic materials. |
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Why is the index of refraction an important property of optoelectronic semiconductors? How is it defined
and what kind of numbers can you give? |
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Compare the operation of a CMOS processor and an optoelectronic device in terms of power. What follows
for some material properties? |
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Why do we still use light bulbs or fluorescent light for general lighting? What are the prime conditions
that optoelectronics has to meet in order to impact the lighting market? |
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List and briefly discuss the advantages and disadvantages of semiconductor Lasers |
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Describe some recombination mechanisms, how they impact optoelectronic devices and what can be done to
optimize recombination. |
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What are OLED's? For what kinds of products are they of prime importance and why? |
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Important Principles and Technologies |
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Describe some measures necessary of you want to produce a high-efficiency LED. Use
hand drawings to illustrate (at least) three major points. |
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How can you best define a recombination volume? |
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Draw the band diagram of an Np junction in equilibrium with the bandgap of the N-type
semiconductor about twice the size of the p-type material. Discuss choice you make if necessary. |
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Discuss advantages an problems of hetero junctions for light emitting devices |
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Describe the working principle of MBE and what it means in terms of realization. |
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Describe the mechanisms of fundamental absorption (FA) and stimulated emission (SE) with the aid of a band diagram. What kind of relation between
the rates RSe and RFA, i.e. the number of events per second (and cm2)
must you have if amplification of light is to take place? |
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What is the meaning of "inversion" in the context of a semiconductor Laser? |
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What is "pumping" in the context of a Laser and why is a semiconductor very well suited for efficient
"pumping"? |
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How can you turn a light amplifier into a Laser? What does it mean technically for processing your semiconductor? |
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Here is a somewhat "longer" question: |
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The picture shows a schematic "to scale" drawing of a simple blue Laser diode and
the relevant material parameters in the "master" diagram. | |
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What kind of approximate band gap energy can you assign to the various layers? Draw a schematic
band diagram of this kind of situation. | |
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Which layer is the light-producing one? | |
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What is the function of the three relatively thin layers in the center region? |
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What could be the function of the two thicker pure GaN layers? |
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Why is the whole structure on an Al2O3 substrate (= sapphire) and what is
the electrical problem encountered? | |
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What might be the problem necessitating a "buffer" layer between the Al2O3
substrate and the stack of functional layers? | |
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Where are the mirrors necessary for a Laser? | |
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What is obviously used for n- or p-doping? Make a guess as to why the very thin central layer
contains Mg and Si as dopants | |
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© H. Föll (Semiconductor Technology - Script)
9.3.1 Summary to: 9. Optoelectronics 
With frame