Session B39: Focus Session: Materials and Applications for Solar Energy I
11:15 AM–2:03 PM, Monday, March 5, 2007
Colorado Convention Center Room: 502
Sponsoring Units:
FIAP DMP
Chair: Mike McGehee, Stanford University
Abstract ID: BAPS.2007.MAR.B39.6
Abstract: B39.00006 : Theoretical investigation of vacuum thermionic energy conversion devices for efficient conversion of solar to electrical energy
1:03 PM–1:15 PM
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Abstract 
Authors:
Joshua Smith
(North Carolina State University)
Robert Nemanich
(North Carolina State University)
Griff Bilbro
(North Carolina State University)
A vacuum thermionic energy conversion device (TEC) would offer the potential of efficiently converting solar energy directly to electrical work. These devices consist of a heated emitter electrode and a collector electrode separated by an evacuated interelectrode space. Models for such conceptual devices are developed, and efficiency is calculated by considering electron transport across the device as well as Stefan Boltzmann radiation. A device operating with an emitter and collector temperature of $775K$ and $375K$, respectively is considered. The conceptual TEC features diamond materials having low emission barrier heights as electrodes. Hydrogen terminated diamond is known to have a negative electron affinity (NEA) and nitrogen or phosphorus doping introduces donor levels at $~1.7eV$ and $~0.6eV$, respectively, below the conduction band minimum. For the devices considered, the barrier heights are $1.1eV$ and $0.5eV$ for the emitter and collector, respectively. The Richardson constant is $10A/cm^{2}K^{2}$, consistant with experimental results. Assuming an emissivity of 0.5, the device has a Carnot efficiency of 0.52, and a calculated absolute efficiency of 0.17 at a maximum power of $0.25W/cm^{2}$. The theory is extended to include the negative space charge effect, and the NEA properties of the materials are shown to mitigate the space charge effect and increase output power.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2007.MAR.B39.6