1 / 4

Hydrogenic model of doping impurities

Hydrogenic model of doping impurities. The simple model for a hydrogen atom can be used to describe the behavior of an impurity in a semiconductor. Thus, the formula for the ionization energy of a hydrogen atom,. and the radius of the lowest orbit of the electron around the hydrogen nucleus.

emil
Download Presentation

Hydrogenic model of doping impurities

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Hydrogenic model of doping impurities The simple model for a hydrogen atom can be used to describe the behavior of an impurity in a semiconductor. Thus, the formula for the ionization energy of a hydrogen atom, and the radius of the lowest orbit of the electron around the hydrogen nucleus can be applied in modified form to calculate how an electron or hole will interact with its parent impurity atom. mo and o are replaced by m* (effective mass) and s respectively, since we are now concern with charge embedded in a semiconductor and not in vacuum (or free space). Source: http://web.eng.gla.ac.uk/groups/sim_centre/courses/hydrogenic/hydro_1.html

  2. Process 1: Intraband transition Process 2: Band-to-band transition Process 3: Excitonic transition Process 4: Valence band to donor transition Process 5: Conduction band to acceptor transition Process 6: Shallow donor to shallow acceptor transition 1 excitons shallow donors 5 Deep donors 4 3 6 2 Deep acceptors shallow acceptors Radiative transitions in semiconductors Others: Donor to conduction band, acceptor to valence band

  3. a = - 1/2 ( E ) A ( E E ) 0 g Intraband and interband transitions Process 1: Intraband transitions Hot electrons relax their energy mainly by emitting phonons, but sometimes under phonon’s or/and other electron’s assistance can also emit photons. This mechanism is truly rare as many particles are involved K Process 2: Band-to-band transitions Direct Indirect Peak of theemission spectrumhc/Eg Direct bandgap: Indirect bandgap: • = absorption coefficient, Ep is the phonon energy. Intensity proportional to  +ve and –ve signs are for absorption and emission

  4. 1 excitons shallow donors 5 Deep donors 4 3 6 2 Deep acceptors shallow acceptors Other radiative transitions Process 3: Excitonic transitions For free excitons: hv = Eg - Eexbind For bound excitons: hv = Eg - Eexbind – Eb Eb is the energy binding the exciton to the donor or acceptor Process 4 and 5: Free-bound transitions For Doh:hv = Eg - ED For Aoe: hv = Eg - EA Process 6: Donor-acceptor pair transitions where r is the distance between the donor and acceptor

More Related