A student project for AHSE1500: Foundations of Business and Entrepreneurship (taught in Spring 2006) featuring an Olin College themed tradable card game. It consists of cards of students, professors, locations, and events.
This record contains the Final Report for the project and scanned images of all the cards in the game.
We present a generalized study of light emission from reverse biased p–n junctions under avalanche breakdown conditions. A model is developed based on direct and indirect interband processes including self-absorption to describe measured electroluminescence spectra. This model was used to analyze experimental data for silicon (Si) and gallium arsenide p–njunctions and can be extended to several types of semiconductors regardless of their band gaps. This model can be used as a noninvasive technique for the determination of the junction depth. It has also been used to explain the observed changes of the Si p–n junction electroluminescence spectra after fast neutron irradiation. In particular, it is demonstrated that the neutron irradiation affects both the semiconductor and the overlying passivation oxide layer.
The Olin Raytheon/WHOI SCOPE team is assisting WHOI in the buoy design effort by writing software tools for managing the energy budget of a deployed buoy. Woods Hole Oceanographic Institute (WHOI) scientists are constructing buoys for the Ocean Observatories Initiative (OOI), an NSF funded program that will construct a network of buoys for monitoring physical, chemical, geological, and biological variables in the ocean and on the sea floor. The buoys in development for the OOI by WHOI will be expected to operate for 25 years with annual maintenance. Power for an array of reprogrammable sensors will be dependent on a combination of solar and wind power generation and an on-board fuel cell replenished during the annual maintenance.