BUSCADOR RECOLECTA

6 pages. -- Table 1. Composition of different glass types used as substrates. -- Fig. 1. Comparison of Ψ and Δ spectra for standard sample step and poled region, together with corresponding fits. -- Fig. 2. Au NPs: poled and step region ε2 (a) and corresponding SEM micrographs (b, c). -- Fig. 3. The effect of plasma cleaning: comparison of sample cleaned with plasma upon GP and prior to coating (left) and a standard sample (right). -- Fig. 4 Difference of ε2 for Ag NPs containing layers over poled and step region for Cr containing sample. -- Fig. 5. SEM micrographs: transition between step (upper part) and poled region (lower part) of the sample with higher Ag concentration in the coating (a), protrusion of crystallites from the coating (b), out diffused crystallites (c) and their clustering (d). EDS of step region: at the site of the crystallite (e) and a site next to it (f). -- Fig. 6. The sample coated immediately after poling in vacuum: comparison of Ψ and Δ spectra for step and poled region (a) and b), respectively). -- Fig. 7. Transition between step and poled region of the sample coated immediately after poling in vacuum: from step region with out-diffused Na crystallites to the poled, crystallites free region confirming absence of IE., Peer reviewed

Modelizaciones ecohidrológicas en parques continentales de España, [ES] El dataset EcohydroParks se actualiza periódicamente, se puede consultar y descargar en el siguiente enlace: https://parquesactividad.csic.es/ [EN] The EcohydroParks dataset is updated periodically, it can be consulted and downloaded at the following link: https://parquesactividad.csic.es/, [EN] This dataset provide information about evapotranspiration, leaf area index, net primary productivity, precipitation, potential evapotranspiration, soil moisture, maximum and minimum temperature at 7 National Parks from peninsular Spain., [ES] Esta base de datos proporciona información de evapotranspiración, índice de área foliar, producción primaria neta, precipitación, evapotranspiración potencial, humedad del suelo, temperatura máxima y mínima para 7 parques nacionales de la España peninsular., Parques Naturales - Ministerio de agricutura y medio ambiente, a través del proyecto: Herramientas de monitorización de la vegetación mediante modelización ecohidrológica en parques continentales: Evolución reciente y proyecciones futuras (ECOHIDRO, 1560/2105), Peer reviewed

Additional file 1. Oligonucleotides used for amplification. Table containing all the oligonucleotides used for the different PCR assays described in the Methods., Spanish National Research Council (CSIC) Instituto de Salud Carlos III (ISCIII) Spanish Government Xunta de Galicia Ministerio de Economía, Industria y Competitividad, Gobierno de España RIS-RETIC ISCIII RETIC Catalan Government and the European Social Fund., Peer reviewed

Additional file 1. Supplementary material for: Integrating pathway knowledge with deep neural networks to reduce the dimensionality in single-cell RNA-seq data., Ministerio de Ciencia e Innovación H2020 Marie Skłodowska-Curie Actions Consejería de Economía, Innovación, Ciencia y Empleo, Junta de Andalucía., Peer reviewed

Autonomous oscillatory dynamics are ubiquitous at every level in Biology. At the cellular level, one of the most relevant and well characterized examples of periodic behavior is the cyclic assembly and disassembly of actomyosin networks. In Drosophila, these oscillations induce the robust contraction and expansion of individual cells required for correct dorsal closure, while in the follicular epithelium that surrounds the germline, periodic contractions of the basal actomyosin network are required for proper elongation of the egg chamber. While some studies suggest that actomyosin oscillations are driven by upstream signaling or mechanochemical features, we have recently proposed that they arise as a systems property from the competition between two well characterized features of the actomyosin machinery: 1) cooperative assembly of actin networks mediated by Actin crosslinker proteins and 2) tension-induced disassembly of actin networks mediated by myosin motors. Here, we perform experiments in amnioserosa and in the follicle cells of drosophila and simulations using a coarse-grained model of the actomyosin cortex to characterize the properties of the oscillations and how they depend on different features of the system. We also compare model and experiments to study the dynamics of actomyosin flows and the effect of mechanical coupling between cells in the tissue. In conclusion, our model is a powerful tool to study key features of actomyosin oscillations, from the effect of the individual components to network properties and finally supra-cellular organization of the oscillations at the tissue level., Peer reviewed

The dataset is made available under the Open Database License. Any rights in individual contents of the database are licensed under the Database Contents License. Please, read the full ODbL 1.0 license text for the exact terms that apply. Users of the dataset are free to: Share: copy, distribute and use the database, either commercially or non-commercially. Create: produce derivative works from the database. Adapt: modify, transform and build upon the database. Under the following conditions: Attribution: You must attribute any public use of the database, or works produced from the database. For any use or redistribution of the database, or works produced from it, you must make clear to others the license of the original database. Share-Alike: If you publicly use any adapted version of this database, or works produced from an adapted database, you must also offer that adapted database under the ODbL., This work was supported by grants RTI2018-101115-B-C21, PID2021-125858OB-100 and the Severo Ochoa Excellence Program CEX2021-001189-S funded by MCIN/AEI/ 10.13039/501100011033 and by “ERDF A way of making Europe”. MGL was recipient of a predoctoral grant FPU19/02066 funded by MCIN/AEI/680 10.13039/501100011033 and by “ESF Investing in your future”., Peer reviewed

3 pages. -- Figure S1 Particle size distribution of (a) Sn, (b) Sn/a-C, and (c) SnBi/a-C MPs. -- Figure S2 (a) A SEM image of core and shell layer of SnBi/a-C MPs. (b) EDX line scan mapping images of Sn, Bi and amorphous carbon along the yellow arrow., In this work, the microencapsulated phase change materials, Sn/amorphous-carbon (Sn/a-C), and SnBi/amorphous carbon (SnBi/a-C) microparticles (MPs) were successfully synthesized. The thermal stabilities of Sn/a-C and SnBi/a-C core–shell MPs were verified by cycling tests, and stable latent heats of 56 and 45.7 J/g were obtained for Sn/a-C and SnBi/a-C MPs, respectively. Compared to the high melting point of 231 °C and large thermal hysteresis (TH) of ∼106 °C for the Sn/a-C MPs, the SnBi/a-C MPs exhibited a lower melting point of 125 °C and a smaller TH of 20 °C. The nitrate senary salt with a lower melting point of ∼75 °C than that of the commercial HITEC salt (melting point of ∼142 °C) was also synthesized to enlarge the working temperature range of the working fluid in a solar thermal power plant and to demonstrate the latent heat-enhanced thermal energy storage using the SnBi/a-C MPs. The heat capacity can be enhanced by 200% by doping with 20 wt % Sn/a-C MPs into the HITEC salt, and it can be enhanced by 734% by doping with 20 wt % SnBi/a-C MPs into the senary salt. In addition, the viscosities of the HITEC salt and senary salt doped with the Sn/a-C and SnBi/a-C MPs were not appreciably raised by doping with the MPs. The various approaches accomplished in this work demonstrate (1) enhancing heat capacity of the working fluid by exploiting the latent heats of the embedded MPs; (2) lowering the TH of the MPs by using the alloy metal particles; and (3) extending the working temperature range by synthesizing the senary salt. These approaches could be applied for enhancing energy storage in solar thermal power plants and facilitating waste heat recovery., Peer reviewed

22 pages. -- PDF file includes: Structural characterization. -- Electrochemical Measurements. -- Faradaic efficiency (FE). -- Ionic strength compensation. -- Hypochlorite titration analysis. -- DFT Computational method. -- Figure S1 a-f) SEM images of the Mo-Co precursor. -- Figure S2 a-f) SEM images of MoN-Co2N. -- Figure S3. a-c) SEM images and d) EDS result of MoN-Co2N. -- Figure S4. a-f) TEM images of MoN-Co2N. -- Figure S5. a-c) TEM images and d-f) HAADF-STEM images of MoN-Co2N. -- Figure S6. TEM and HRTEM images of the MoN-Co2N. -- Figure S7. EELS chemical composition maps of MoN-Co2N obtained from the red squared area of the STEM micrograph. -- Figure S8. XRD patterns of MoN-Co2N, Mo-Co2N and CoxN compared with reference patterns of Co, Co4N, Co2N and MoN. -- Figure S9. a-c) SEM images and d) EDS result of Mo-Co2N. -- Figure S10. a-c) SEM images and d) EDS result of CoxN. -- Figure S11. Pore size distribution plot for MoN-Co2N and CoxN. -- Figure S12. Cyclic voltammograms for a) MoN-Co2N; b) Mo-Co2N; c) CoxN and d) Mo-Co precursors and e) IrO2 in the non-faradaic region of 1.12-1.22 V vs. RHE at various scan rates. -- Figure 13. a) N and b) Co partial and c) Total Density of states for Co2N and MoN-Co2N. -- Figure S14. The evolutions of local structural configurations for illustrating OER process of Co2N. (* represents the active site). -- Figure S15. Photograph of flasks containing seawater after adding KOH (left) and before adding KOH (right). -- Figure S16. Overall water/seawater splitting performance of MoN-Co2N ‖ MoN-Co2N and Pt/C ‖ IrO2 cells in 1 M KOH, 1 M KOH seawater, and untreated seawater. -- Figure S17. Overall water splitting performance of MoN-Co2N ‖ MoN-Co2N and Pt/C ‖ IrO2 cells in 1 M KOH seawater with and without ionic strength compensation. -- Figure S18. a) Digital photographs of the reaction and reference solutions for the iodometric titration, showing the absence of ClO− production in theº former case. b) Measured (dots) and theoretical (solid line) gaseous products by the two-electrode electrolyzer at a current of 50 mA cm-2 in 1 M KOH seawater. -- Figure S19. High-resolution XPS spectra of a) N 1s, b) Co 2p, c) Mo 3d for MoN-Co2N and MoN-Co2N after long-term reaction. -- Figure S20. a-b) TEM images, c-d) HAADF-STEM images, e-f) HRTEM of MoN-Co2N after long time reaction. -- Figure S21. EELS chemical composition maps of MoN-Co2N after long time reaction obtained from the red squared area of the STEM micrograph. Individual C K-edge at 284 eV (orange), N K-edge at 401 eV (blue), Co L2,3-edges at 779 eV (red) and Mo M4,5-edges at 227 eV (green) and composites of Co-N and Mo-N. -- Table S1. Comparison of OER activity of MoN-Co2N with recently reported nitride electrocatalysts in 1.0 M KOH electrolyte. -- Table S2. Cdl and ECSAs of various catalysts. -- Table S3. Comparison of HER performance of MoN-Co2N with recently reported nitride electrocatalysts in 1.0 M KOH electrolyte. -- Table S4 Comparison of the overall water splitting of MoN-Co2N with previously reported electrocatalysts., The development of cost-effective bifunctional catalysts for water electrolysis is both a crucial necessity and an exciting scientific challenge. Herein, a simple approach based on a metal–organic framework sacrificial template to preparing cobalt molybdenum nitride supported on nitrogen-doped carbon nanosheets is reported. The porous structure of produced composite enables fast reaction kinetics, enhanced stability, and high corrosion resistance in critical seawater conditions. The cobalt molybdenum nitride-based electrocatalyst is tested toward both oxygen evolution reaction and hydrogen evolution reaction half-reactions using the seawater electrolyte, providing excellent performances that are rationalized using density functional theory. Subsequently, the nitride composite is tested as a bifunctional catalyst for the overall splitting of KOH-treated seawater from the Mediterranean Sea. The assembled system requires overpotentials of just 1.70 V to achieve a current density of 100 mA cm–2 in 1 M KOH seawater and continuously works for over 62 h. This work demonstrates the potential of transition-metal nitrides for seawater splitting and represents a step forward toward the cost-effective implementation of this technology., Peer reviewed

11 pages. -- Figure S1. SEM image and EDS spectrum of the as-synthesized NiS NPs. -- Figure S2. NiS NPs: (a) XPS survey spectrum. (b-c) Corresponding Ni 2p3/2, and S 2p high resolution XPS spectra. -- Figure S3. Ni NPs: (a) XRD pattern. (b) Representative TEM micrograph and the corresponding size distribution. -- Figure S4. CV curves for the monometallic Ni NPs based electrode in 1 M KOH with the presence of 1 M methanol or ethanol in alkaline media at a scan rate of 50 mV s 1. -- Table S1. Fitting parameters for the Nyquist curve at 1.5 V in 1.0 M KOH with and without 1.0 M m ethanol or ethanol. -- Figure S5. Electrochemical performance dependence on alcohol concentration for Ni-based electrode in 1 M KOH electrolyte. -- Figure S6. Electrochemical activity of Ni-based electrode in 1 M KOH. -- Figure S 7 . (a) CV curves in the potential range of 0.9 1. 6 V at different scan rates . (b) Linear fitting between the peak current and scan rates from 10 to 50 mV s 1 . (c) Linear fitting between the peak current and square root of scan rates from 60 to 100 mV s 1. -- Table S2. Comparison of the alcohols oxidation performance between this work and previously reported electrocatalysts with a similar system. -- Figure S8. (a) CA test towards MOR and EOR on NiS NPs electrode over 10,000 s testing period in 1 M KOH at 1.6 V. (b) IC curve of the solution at the end of CA testing. -- Figure S9. (a) Survey XPS spectrum of the NiS-based electrode after 10,000 s testing period in 1 M KOH and 1 M ethanol at 1.6 V. (b) High-resolution Ni 2p XPS spectrum. (c) High-resolution S 2pXPS spectrum. -- Figure S10. (a) Optimized structural model of NiOOH SO 4 (b) DOS of Ni OOH and Ni OOH SO 4 regarding the Ni 3d orbitals., The electrocatalytic oxidation of alcohols is a potentially cost-effective strategy for the synthesis of valuable chemicals at the anode while simultaneously generating hydrogen at the cathode. For this approach to become commercially viable, high-activity, low-cost, and stable catalysts need to be developed. Herein, we demonstrate an electrocatalyst based on earth-abundant nickel and sulfur elements. Experimental investigations reveal the produced NiS displays excellent electrocatalytic performance associated with a higher electrochemical surface area (ECSA) and the presence of sulfate ions on the formed NiOOH surface in basic media. The current densities reached for the oxidation of ethanol and methanol at 1.6 V vs reversible hydrogen electrode (RHE) are up to 175.5 and 145.1 mA cm–2, respectively. At these high current densities, the Faradaic efficiency of methanol to formate conversion is 98% and that of ethanol to acetate is 81%. Density functional theory calculations demonstrate the presence of the generated sulfate groups to modify the electronic properties of the NiOOH surface, improving electroconductivity and electron transfer. Besides, calculations are used to determine the reaction energy barriers, revealing the dehydrogenation of ethoxy groups to be more favorable than that of methoxy on the catalyst surface, which explains the highest current densities obtained for ethanol oxidation., Peer reviewed

Datos geoespaciales del índice de vegetación de diferencia normalizado (NDVI) de alta resolución espacial (1.1 km) para la España peninsular y Baleares con una resolución temporal quincenal (1981-2015)., [ES] El dataset NDVISpainDatabase se actualiza periódicamente, se puede consultar y descargar en el siguiente enlace: https://spainndvi.csic.es/ [EN] The NDVISpainDatabase dataset is updated periodically, it can be consulted and downloaded at the following link: https://spainndvi.csic.es/, [EN] NDVISpainDatabase is a high-resolution (1.1 km) Normalized Difference Vegetation Index dataset for the peninsular Spain and the Balearic Islands. This dataset covers from 1981 to 2015 with a biweekly time resolution., [ES] NDVISpainDatabase es una base de datos del índice de vegetación de diferencia normalizado de alta resolución espacial (1.1 km) para la España peninsular y Baleares. La base de datos cubre el periodo 1981-2015 con una resolución temporal quincenal., Spanish Commission of Science and Technology and FEDER ECOHIDRO (1550/2015, funded by the Natural Parks-Ministry of Agriculture and Environment) by the research projects PCIN-2015-220, PCIN-2017-020, CGL2014-52135-C03-01, CGL2017-83866-C3-3-R and CGL2017-82216-R, Water Works 2014 co-funded call of the European Commission by the project IMDROFLOOD, Assessment of Cross(X) - sectoral climate Impacts and pathways for Sustainable transformation JPI Climate co-funded call of the European Commission by the project CROSSDRO, FORMAS (SE), DLR (DE), BMWFW (AT), IFD (DK), MINECO (ES), ANR (FR) with co-funding by the European Union (Grant 690462) by the project INDECIS (which is part of ERA4CS, an ERA-NET initiated by JPI Climate), Peer reviewed