APS March Meeting 2015
Volume 60, Number 1
Monday–Friday, March 2–6, 2015;
San Antonio, Texas
Session G46: Invited Session: Ovshinsky Award Session - A Legacy of Energy Technologies
11:15 AM–2:15 PM,
Tuesday, March 3, 2015
Room: 217A
Sponsoring
Unit:
GERA
Chair: David Ginley, National Renewable Energy Laboratory
Abstract ID: BAPS.2015.MAR.G46.1
Abstract: G46.00001 : Deterministic Modelling of Carbon Nanotube Near-Infrared Solar Cells
11:15 AM–11:51 AM
Preview Abstract
Abstract
Author:
Darin Bellisario
(Massachusetts Institute of Technology, Dept. of Chemistry)
With solution-process-ability, scale-able fabrication and purification, and
cheap input materials, semiconducting single-walled carbon nanotube (SWNT)
networks represent promising materials for near-IR solar cell (SC)
applications. This promise has motivated a body of work not only developing
solar cells but also exploring alignment/deposition methods and SWNT
photovoltaic (PV) physics. Despite this interest, there is to date no
quantitative model of SWNT solar cell operation analogous to bulk
semiconductor p-n junction PVs, allowing a rigorous understanding of the
physical tradeoffs driving experimental observations and informing what
research will enable technological progress. In this work we have derived
the steady state operation of planar heterojunction SWNT PVs from the
fundamental light absorption, exciton transport, and free carrier transport
behaviors of single nanotubes. Our method can treat arbitrary distributions
of nanotube chiralities, lengths, orientations, defect types and
concentration, bundle fraction and size, density, dielectric environment,
electrode combinations, etc. We achieve this by treating individual SWNT
properties as random variables, and describing the network by the dependent
distributions of those properties, yielding coupled stochastic differential
equations for light absorption, exciton transport, and free carrier
transport. Applying the model to monochiral (6,5) films in aligned and
isotropic configurations, we find that there is a strongly optimal film
thickness at a given nanotube network density and orientation, reflecting an
inherent tradeoff between light absorption (i.e. exciton generation) and
diffusion to the electrodes. This optimal shifts lower with increasing
density, and is ultra-thin (\textless 10 nm) for horizontally-aligned films
but 50-200 nm for vertically aligned films. We show that due to weak
inter-SWNT exciton transport relative to exceptional intra-SWNT diffusion,
vertically-aligned films are unambiguously favored at densities above 3{\%}
of close-packed; at lower densities however an optimum emerges at an
intermediate angle to compensate for weaker light absorption of vertical
nanotubes. Films with in-plane aligned nanotubes are unambiguously the worst
design.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2015.MAR.G46.1