Thin film solar cells based in Cu(In,Ga)Se2 (CIGS) are among the most efficient polycrystalline solar cells, surpassing CdTe and even polycrystalline silicon solar cells. For further developments, the CIGS technology has to start incorporating different solar cell architectures and strategies that allow for very low interface recombination. In this work, ultrathin 350 nm CIGS solar cells with a rear interface passivation strategy are studied and characterized. The rear passivation is achieved using an Al2O3 nanopatterned point structure. Using the cell results, photoluminescence measurements, and detailed optical simulations based on the experimental results, it is shown that by including the nanopatterned point contact structure, the interface defect concentration lowers, which ultimately leads to an increase of solar cell electrical performance mostly by increase of the open circuit voltage. Gains to the short circuit current are distributed between an increased rear optical reflection and also due to electrical effects. The approach of mixing several techniques allows us to make a discussion considering the different passivation gains, which has not been done in detail in previous works. A solar cell with a nanopatterned rear contact and a 350 nm thick CIGS absorber provides an average power conversion efficiency close to 10%.
Opto-electronics on/with paper is fostering a novel generation of flexible and recyclable devices for sunlight harvesting and intelligent optical sensing.
The spectra of localized surface plasmon resonances (LSPRs) in self-assembled silver nanoparticles (NPs), prepared by solid-state dewetting of thin films, are discussed in terms of their structural properties. We summarize the dependences of size and shape of NPs on the fabrication conditions with a proposed structural-phase diagram. It was found that the surface coverage distribution and the mean surface coverage (SC) size were the most appropriate statistical parameters to describe the correlation between the morphology and the optical properties of the nanostructures. The results are interpreted with theoretical predictions based on Mie theory. The broadband scattering efficiency of LSPRs in the nanostructures is discussed towards application as plasmon-enhanced back reflectors in thin-film solar cells.
The present development of non‐wafer‐based photovoltaics (PV) allows supporting thin film solar cells on a wide variety of low‐cost recyclable and flexible substrates such as paper, thereby extending PV to a broad range of consumer‐oriented disposable applications where autonomous energy harvesting is a bottleneck issue. However, their fibrous structure makes it challenging to fabricate good‐performing inorganic PV devices on such substrates. The advances presented here demonstrate the viability of fabricating thin film silicon PV cells on paper coated with a hydrophilic mesoporous layer. Such layer can not only withstand the cells production temperature (150 °C), but also provide adequate paper sealing and surface finishing for the cell's layers deposition. The substances released from the paper substrate are continuously monitored during the cell deposition by mass spectrometry, which allows adapting the procedures to mitigate any contamination from the substrate. In this way, a proof‐of‐concept solar cell with 3.4% cell efficiency (41% fill factor, 0.82 V open‐circuit voltage and 10.2 mA cm−2 short‐circuit current density) is attained, opening the door to the use of paper as a reliable substrate to fabricate inorganic PV cells for a plethora of indoor applications with tremendous impact in multi‐sectorial fields such as food, pharmacy and security.
In order to enhance infrared light absorption in sub-bandgap transitions in an intermediate band solar cell, the scattered near-field potential from uncoated and coated metallic nanoparticles with a spheroidal shape is calculated with the electrostatic model. The absorption enhancement produced at the surface plasmon frequency of the nanoparticles can be of several orders of magnitude in some cases.Conventional single-gap solar cells cannot exploit photon energies below semiconductor bandgap energies. A promising concept to overcome this limitation is the intermediate band solar cell (IBSC), which reaches a detailed balance efficiency limit of 63.2% compared to 40.7% for singlegap cells. The IBSC can generate photocurrent from subbandgap photons, without voltage degradation, due to the existence of an electronic band-the intermediate band (IB)-within the semiconductor bandgap.The IB can be formed by the confined levels of a quantum dot (QD) array. Prototype IBSCs were fabricated with ten QD layers. However, the IB impact on the cell performance is still marginal, mainly due to the weak absorption coefficient associated to the QDs. One way of increasing this absorption is to grow more QD layers, but this introduces strain-induced dislocations that deteriorate the device performance. Procedures for reducing the strain are in development, ~ but this is still a challenging problem. In this contribution, an alternative procedure is studied that exploits the high near-field that can appear in the vicinity of metal nanoparticles (MNPs) sustaining surface plasmons. The inclusion of these particles close to QDs can amplify their absorption, allowing the replacement of several QD layers by a single one with MNPs. These MNPs might also induce defects but it is possible that the reduction of layers has an overall positive effect.When an electric plane-wave impinges on a particle much smaller than its wavelength the electric field induced inside the particle can be assumed uniform. This is the principle of electrostatic approximation (EA), valid only if the following conditions are simultaneously fulfilled:277T eq /\ s is obtained from Laplace equation (V-E = 0) whose solution is exact for ellipsoids with semiaxes a, b, and c. Due to the unpolarized na...
A novel type of plasmonic light trapping structure is presented in this paper, composed of metal nanoparticles synthesized in colloidal solution and self-assembled in uniform long-range arrays using a wet-coating method. The high monodispersion in size and spherical shape of the gold colloids used in this work allows a precise match between their measured optical properties and electromagnetic simulations performed with Mie theory, and enables the full exploitation of their collective resonant plasmonic behavior for light-scattering applications. The colloidal arrays are integrated in plasmonic back reflector (PBR) structures aimed for light trapping in thin film solar cells. The PBRs exhibit high diffuse reflectance (up to 75%) in the red and near-infrared spectrum, which can pronouncedly enhance the near-bandgap photocurrent generated by the cells. Furthermore, the colloidal PBRs are fabricated by low-temperature (<120 °C) processes that allow their implementation, as a final step of the cell construction, in typical commercial thin film devices generally fabricated in a superstrate configuration.
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