Solar Energy

The UV absorption spectra and JV curves of DSSCs were applied.

result file of flow through measurement

The original data of Fig. 3, Fig. 4, and Fig. 5 for the manuscript entitled "Performance improvement of III-V compound solar cells using nanomesh electrode and nanostructured antireflection structures".

Original data that collected from factory to make the model. And original data that calculated by software Simapro.

The attached file contains the worldwide KGPV climate classification and the simulated PV performance indicators for a typical system using typical mc-Si PV modules.

Supplementary materials for "Nonparametric Bayesian-based recognition of solar irradiance conditions: Application to the generation of high temporal resolution synthetic solar irradiance data" article.

Research data of the kesterite solar cells

The data are from 2 monitoring campaign about an experimental prototype for a Low-Cost South of Chile. This experiment was part of the Bioclimatic Prosthesis project for wooden architecture. A system development for adaptive components to passive refurbishment and energy rehabilitation in different microclimatic contexts from Biobío region. Project Code [14.1554-IN.IIP]., Research was Funded by INNOVA Biobío from CORFO(Production Development Corporation). This paper is done as a part of a Post-Doctoral research in KU Leuven University Belgium funded by a Scholarship 2018-2020 from Becas-Chile CONICYT (Chilean National Research Science and Technology Council), for the research project titled Bioclimatic and Architectonic Prosthesis. From local adaptations to an incremental system for refurbishment and adaptive social housing. The monitoring periods and data collection are summarized for Coronel (coastal city) and for Chillán (Central valley city) in a representative week. Include detailed scenarios results for the city of Chillán.

Weather data in Taipei and New York City in .epw format and some .xml material files of complex fenestration systems.

This study reports on the deposition of TiO2 nanoparticles and the sensitization of the photoanode by a new digital printing technology, named Digital Materials Deposition “DMD” to fabricate semi-transparent DSSCs. In this study, the push-pull dye coded “D35” and I3−/I− were used respectively as sensitizer and redox mediator. The photovoltaic performances of the solar cells printed with the DMD technology were compared to those prepared by the conventional method consisting of screen-printed nanoparticles and dying process by overnight soaking of the electrode into a solution of the sensitizer. Scanning Electron Microscopy shows that the DMD printed film is more porous than the one deposited by screen printing. The cells prepared by DMD give higher solar energy conversion efficiency (Jsc= 12.65 mA/cm2, Voc= 775 mV, FF=75%, PEC=7.4%) than with conventional screen-printing technique (Jsc = 10.03 mA/cm2, Voc= 760 mV, FF =72 %, PEC=5.48%). IMVS/IMPS measurements demonstrate that the superior photocurrent density delivered by DMD printed solar cells is due to a higher charge collection efficiency. Overall, this study demonstrates that DMD technology simplifies the DSSC fabrication process with a reduction of the material consumption and it is quick and efficient representing an innovative and attractive method to manufacture DSSCs.