Ocean University of China

About: Ocean University of China is a education organization based out in Qingdao, China. It is known for research contribution in the topics: Population & Sea surface temperature. The organization has 27604 authors who have published 27886 publications receiving 440181 citations. The organization is also known as: Zhōngguó Hǎiyáng Dàxué & OUC.

Transparent Metal Selenide Alloy Counter Electrodes for High-Efficiency Bifacial Dye-Sensitized Solar Cells†

Abstract: The exploration of cost-effective and transparent counter electrodes (CEs) is a persistent objective in the development of bifacial dye-sensitized solar cells (DSSCs). Transparent counter electrodes based on binary-alloy metal selenides (M-Se; M=Co, Ni, Cu, Fe, Ru) are now obtained by a mild, solution-based method and employed in efficient bifacial DSSCs. Owing to superior charge-transfer ability for the I−/I3− redox couple, electrocatalytic activity toward I3− reduction, and optical transparency, the bifacial DSSCs with CEs consisting of a metal selenide alloy yield front and rear efficiencies of 8.30 % and 4.63 % for Co0.85Se, 7.85 % and 4.37 % for Ni0.85Se, 6.43 % and 4.24 % for Cu0.50Se, 7.64 % and 5.05 % for FeSe, and 9.22 % and 5.90 % for Ru0.33Se in comparison with 6.18 % and 3.56 % for a cell with an electrode based on pristine platinum, respectively. Moreover, fast activity onset, high multiple start/stop capability, and relatively good stability demonstrate that these new electrodes should find applications in solar panels.

Genetic and phenotypic characterization of Phaeodactylum tricornutum (Bacillariophyceae) accessions

Abstract: In the last few years, genome-based studies in diatoms have received a major boost following the genome sequencing of the centric species Thalassiosira pseudonana Hasle et Heimdal and the pleiomorphic raphid pennate diatom Phaeodactylum tricornutum Bohlin. In addition, molecular tools, such as genetic transformation, have been developed for both species. Despite these molecular advances, relatively little is known regarding the genetic diversity of the available strains of these diatoms. In this study, we have compiled a historical summary of the known P. tricornutum species resources and have provided a genetic and phenotypic overview of 10 different axenic strains. Examination of intraspecies genetic diversity based on internal transcribed spacer 2 (ITS2) sequence and amplified fragment length polymorphism (AFLP) analyses indicate four different genotypes. Seven strains are predominantly fusiform, whereas one strain is predominantly oval, and another is predominantly triradiate. Another is defined as a tropical strain because it appears better acclimated to growth at higher temperatures. Observations in the natural environment indicate that P. tricornutum is a coastal marine diatom that is able to adapt to unstable environments, such as estuaries and rock pools. Because it has rarely been noted in nature, we have developed specific primers to amplify ITS2 sequences and have successfully identified it in environmental samples. These resources should become useful tools for the diatom community when combined with the whole genome sequence and will open up a range of new possibilities for experimental investigations that can exploit the genotypic and phenotypic characteristics described.

Western boundary currents regulated by interaction between ocean eddies and the atmosphere

Abstract: Current climate models systematically underestimate the strength of oceanic fronts associated with strong western boundary currents, such as the Kuroshio and Gulf Stream Extensions, and have difficulty simulating their positions at the mid-latitude ocean’s western boundaries1. Even with an enhanced grid resolution to resolve ocean mesoscale eddies—energetic circulations with horizontal scales of about a hundred kilometres that strongly interact with the fronts and currents—the bias problem can still persist2; to improve climate models we need a better understanding of the dynamics governing these oceanic frontal regimes. Yet prevailing theories about the western boundary fronts are based on ocean internal dynamics without taking into consideration the intense air–sea feedbacks in these oceanic frontal regions. Here, by focusing on the Kuroshio Extension Jet east of Japan as the direct continuation of the Kuroshio, we show that feedback between ocean mesoscale eddies and the atmosphere (OME-A) is fundamental to the dynamics and control of these energetic currents. Suppressing OME-A feedback in eddy-resolving coupled climate model simulations results in a 20–40 per cent weakening in the Kuroshio Extension Jet. This is because OME-A feedback dominates eddy potential energy destruction, which dissipates more than 70 per cent of the eddy potential energy extracted from the Kuroshio Extension Jet. The absence of OME-A feedback inevitably leads to a reduction in eddy potential energy production in order to balance the energy budget, which results in a weakened mean current. The finding has important implications for improving climate models’ representation of major oceanic fronts, which are essential components in the simulation and prediction of extratropical storms and other extreme events3, 4, 5, 6, as well as in the projection of the effect on these events of climate change.