103 research outputs found
Effects of bulk and grain boundary recombination on the efficiency of columnar-grained crystalline silicon film solar cells
Columnar-grained polycrystalline silicon films deposited at
low temperatures are promising materials for use in thin-film
photovoltaics. We study the effects of recombination
at grain boundaries, bulk intragranular recombination,
grain size, and doping in such structures with two-dimensional
device physics simulations, explicitly
modeling the full statistics and electrostatics of traps at the
grain boundary. We characterize the transition from grain-boundary-limited to bulk-lifetime-limited performance as a
function of intergranular defect density and find that higher
bulk lifetimes amplify grain boundary recombination effects
in the intermediate regime of this transition. However,
longer bulk lifetimes ultimately yield higher efficiencies.
Additionally, heavier base doping is found to make
performance less sensitive to grain boundary defect
density
Growth of vertically aligned Si wire arrays over large areas (>1 cm^2) with Au and Cu catalysts
Arrays of vertically oriented Si wires with diameters of 1.5 µm and lengths of up to 75 µm were grown over areas >1 cm^2 by photolithographically patterning an oxide buffer layer, followed by vapor-liquid-solid growth with either Au or Cu as the growth catalyst. The pattern fidelity depended critically on the presence of the oxide layer, which prevented migration of the catalyst on the surface during annealing and in the early stages of wire growth. These arrays can be used as the absorber material in novel photovoltaic architectures and potentially in photonic crystals in which large areas are needed
Dynamically Stable Radiation Pressure Propulsion of Flexible Lightsails for Interstellar Exploration
Lightsail spacecraft, propelled to relativistic velocities via photon
pressure using high power density laser radiation, offer a potentially new
route to space exploration within and beyond the solar system, extending to
interstellar distances. Such missions will require meter-scale lightsails of
submicron thickness, posing substantial challenges for materials science and
engineering. We analyze the structural and photonic design of flexible
lightsails, developing a mesh-based multiphysics simulator based on linear
elastic theory, treating the lightsail as a flexible membrane rather than a
rigid body. We find that flexible lightsail membranes can be spin stabilized to
prevent shape collapse during acceleration, and that certain lightsail shapes
and designs offer beam-riding stability despite the deformations caused by
photon pressure and thermal expansion. Excitingly, nanophotonic lightsails
based on planar silicon nitride membranes patterned with suitably designed
optical metagratings exhibit both mechanically and dynamically stable
propulsion along the pump laser axis. These advances suggest that laser-driven
acceleration of membrane-like lightsails to the relativistic speeds needed to
access interstellar distances is conceptually feasible, and that fabrication of
such lightsails may be within the reach of modern microfabrication technology.Comment: 14 pages, 6 figures; plus 18-page SI with figures and linked video
10 µm minority-carrier diffusion lengths in Si wires synthesized by Cu-catalyzed vapor-liquid-solid growth
The effective electron minority-carrier diffusion length, L_(n,eff), for 2.0 µm diameter Si wires that were synthesized by Cu-catalyzed vapor-liquid-solid growth was measured by scanning photocurrent microscopy. In dark, ambient conditions, L_(n,eff) was limited by surface recombination to a value of ≤ 0.7 µm. However, a value of L_(n,eff) = 10.5±1 µm was measured under broad-area illumination in low-level injection. The relatively long minority-carrier diffusion length observed under illumination is consistent with an increased surface passivation resulting from filling of the surface states of the Si wires by photogenerated carriers. These relatively large L_(n,eff) values have important implications for the design of high-efficiency, radial-junction photovoltaic cells from arrays of Si wires synthesized by metal-catalyzed growth processes
Secondary ion mass spectrometry of vapor−liquid−solid grown, Au-catalyzed, Si wires
Knowledge of the catalyst concentration within vapor-liquid-solid (VLS) grown semiconductor wires is needed in order to assess potential limits to electrical and optical device performance imposed by the VLS growth mechanism. We report herein the use of secondary ion mass spectrometry to characterize the Au catalyst concentration within individual, VLS-grown, Si wires. For Si wires grown by chemical vapor deposition from SiCl_4 at 1000 °C, an upper limit on the bulk Au concentration was observed to be 1.7 x 10^16 atoms/cm^3, similar to the thermodynamic equilibrium concentration at the growth temperature. However, a higher concentration of Au was observed on the sidewalls of the wires
High-performance Si microwire photovoltaics
Crystalline Si wires, grown by the vapor–liquid–solid (VLS)
process, have emerged as promising candidate materials for lowcost, thin-film photovoltaics. Here, we demonstrate VLS-grown Si microwires that have suitable electrical properties for high-performance photovoltaic applications, including long minority-carrier diffusion lengths (L_n » 30 µm) and low surface recombination velocities (S « 70 cm·s^(-1)). Single-wire radial p–n junction solar cells were fabricated with amorphous silicon and silicon nitride
surface coatings, achieving up to 9.0% apparent photovoltaic efficiency, and exhibiting up to ~600 mV open-circuit voltage with over 80% fill factor. Projective single-wire measurements and optoelectronic simulations suggest that large-area Si wire-array solar cells have the potential to exceed 17% energy-conversion efficiency, offering a promising route toward cost-effective crystalline Si photovoltaics
Self-Stabilizing Silicon Nitride Lightsails
We report a design for a microscopic lightsail prototype that allows for passive stabilization in the radiation-pressure dominated regime. Stable dynamics of our silicon nitride structure are predicted for initial tilts of up to ±10°
Lightweight Carbon Fiber Mirrors for Solar Concentrator Applications
Lightweight parabolic mirrors for solar concentrators have been fabricated
using carbon fiber reinforced polymer (CFRP) and a nanometer scale optical
surface smoothing technique. The smoothing technique improved the surface
roughness of the CFRP surface from ~3 {\mu}m root mean square (RMS) for as-cast
to ~5 nm RMS after smoothing. The surfaces were then coated with metal, which
retained the sub-wavelength surface roughness, to produce a high-quality
specular reflector. The mirrors were tested in an 11x geometrical concentrator
configuration and achieved an optical efficiency of 78% under an AM0 solar
simulator. With further development, lightweight CFRP mirrors will enable
dramatic improvements in the specific power, power per unit mass, achievable
for concentrated photovoltaics in space.Comment: IEEE Photovoltaic Specialist Conference (PVSC), DC, USA, 201
Photoelectrochemical Hydrogen Evolution Using Si Microwire Arrays
Arrays of B-doped p-Si microwires, diffusion-doped with P to form a radial n+ emitter and subsequently coated with a 1.5-nm-thick discontinuous film of evaporated Pt, were used as photocathodes for H_2 evolution from water. These electrodes yielded thermodynamically based energy-conversion efficiencies >5% under 1 sun solar simulation, despite absorbing less than 50% of the above-band-gap incident photons. Analogous p-Si wire-array electrodes yielded efficiencies <0.2%, largely limited by the low photovoltage generated at the p-Si/H_2O junction
GaP/Si wire array solar cells
Si wire arrays have recently demonstrated their potential
as photovoltaic devices [1-3]. Using these arrays as a
base, we consider a next generation, multijunction wire
array architecture consisting of Si wire arrays with a
conformal GaN_xP_(1-x-y)As_y coating. Optical absorption and
device physics simulations provide insight into the design
of such devices. In particular, the simulations show that
much of the solar spectrum can be absorbed as the angle
of illumination is varied and that an appropriate choice of
coating thickness and composition will lead to current
matching conditions and hence provide a realistic path to
high efficiencies. We have previously demonstrated high
fidelity, high aspect ratio Si wire arrays grown by vapor-liquid-solid techniques, and we have now successfully
grown conformal GaP coatings on these wires as a
precursor to considering quaternary compound growth.
Structural, optical, and electrical characterization of these GaP/Si wire array heterostructures, including x-ray
diffraction, Hall measurements, and optical absorption of
polymer-embedded wire arrays using an integrating
sphere were performed. The GaP epilayers have high
structural and electrical quality and the ability to absorb a significant amount of the solar spectrum, making them
promising for future multijunction wire array solar cells
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