Renewable energy sources are among the most important
ingredients for the development of a human society with
sustainable environmental footprint. Among these, photovoltaics
(PV) plays a key role and is therefore a field of intense
research. The key parameters of a solar cell technology
includes not only the energy conversion efficiency but also
the operating lifetime and the overall cost of the energy produced.
The latter must also be compared with other energy
sources. The optimization of all these different aspects
involves research across the whole photovoltaics value chain,
starting from material science up to system optimization.
Development of new solar cell device concepts is as important
as search for new materials with more suitable optoelectronic
properties or improved approaches for PV module design and
integration in power distribution systems. This requires a
comprehensive view on PV technology across all scales, from
the atomic to the macroscopic and industrial scale.
An important aspect of PV research and of development
of new devices and systems, is theoretical modeling as an
indispensable tool for both basic understanding and device
optimization. This involves modeling also on all scales, from
the microscopic properties of materials and nanostructures
up to the behavior of PV modules.
During the last decade, multiscale approaches have seen
increasing interest for application in numerical simulation
of electronic devices. In particular, modeling and understanding
of advanced photovoltaic devices are expected to
benefit from multiscale modeling, which allows describing
consistently both macroscopic device behavior and local
microscopic processes governing light absorption, loss
mechanisms, carrier transport, and extraction. In fact, many
advanced PV concepts rely on effects or contain structural
features that are insufficiently described by standard numerical
simulation approaches or semianalytic models, both
regarding electronic and optical properties. The different
length scales of the electronic and optical degrees of freedoms
specifically lead to an intrinsic need for multiscale simulation,
which is accentuated in many advanced photovoltaics
concepts including nanostructured regions. Moreover, the
active layers in solar cells generally require to have a certain
thickness and a large overall device area, in order to absorb
a sufficient amount of light.
This special issue is an attempt to collect articles on
modeling of PV devices and systems on all scales. It includes
two experimental articles, one shedding some light on photoreflectance
measurements when probing above the pump
beam energy and the other discussing morphology in hybrid
lead halide perovskite solar cells. One article describes
numerical modeling of Cu2O on Si tandem cells based on a
semiempirical approach. A further contribution shows a
physics-based model of a quantum dot solar cell, including
a comparison with experimental data. The remaining two
papers deal with system relevant aspects, namely, power
point tracking and electrical inverters for connecting PV
modules or power plants with appliances.
«
Renewable energy sources are among the most important
ingredients for the development of a human society with
sustainable environmental footprint. Among these, photovoltaics
(PV) plays a key role and is therefore a field of intense
research. The key parameters of a solar cell technology
includes not only the energy conversion efficiency but also
the operating lifetime and the overall cost of the energy produced.
The latter must also be compared with other energy
sources. The optimization...
»
Login
BibTeX