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1. Seventy-five genetic loci influencing the human red blood cell

Author

van der Harst, P. et al.This is a multiauthor paper, U. Elling, IMBA, is shared first author and J. M. Penninger, IMBA, shared co-last author, U. Elling, IMBA, is shared first author, and J. M. Penninger, IMBA, shared co-last author

Published
2012

3. Country-specific net-zero strategies of the pulp and paper industry.

Author

Dai M, Sun M, Chen B, Shi L, Jin M, Man Y, Liang Z, de Almeida CMVB, Li J, Zhang P, Chiu ASF, Xu M, Yu H, Meng J, and Wang Y

Subjects
Greenhouse Effect, Industry, Recycling, Methane analysis, Greenhouse Gases
Abstract

The pulp and paper industry is an important contributor to global greenhouse gas emissions 1,2 . Country-specific strategies are essential for the industry to achieve net-zero emissions by 2050, given its vast heterogeneities across countries 3,4 . Here we develop a comprehensive bottom-up assessment of net greenhouse gas emissions of the domestic paper-related sectors for 30 major countries from 1961 to 2019-about 3.2% of global anthropogenic greenhouse gas emissions from the same period 5 -and explore mitigation strategies through 2,160 scenarios covering key factors. Our results show substantial differences across countries in terms of historical emissions evolution trends and structure. All countries can achieve net-zero emissions for their pulp and paper industry by 2050, with a single measure for most developed countries and several measures for most developing countries. Except for energy-efficiency improvement and energy-system decarbonization, tropical developing countries with abundant forest resources should give priority to sustainable forest management, whereas other developing countries should pay more attention to enhancing methane capture rate and reducing recycling. These insights are crucial for developing net-zero strategies tailored to each country and achieving net-zero emissions by 2050 for the pulp and paper industry., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published
2024
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4. Tautomeric mixture coordination enables efficient lead-free perovskite LEDs.

Author

Han D, Wang J, Agosta L, Zang Z, Zhao B, Kong L, Lu H, Mosquera-Lois I, Carnevali V, Dong J, Zhou J, Ji H, Pfeifer L, Zakeeruddin SM, Yang Y, Wu B, Rothlisberger U, Yang X, Grätzel M, and Wang N

Abstract

Lead halide perovskite light-emitting diodes (PeLEDs) have demonstrated remarkable optoelectronic performance 1-3 . However, there are potential toxicity issues with lead 4,5 and removing lead from the best-performing PeLEDs-without compromising their high external quantum efficiencies-remains a challenge. Here we report a tautomeric-mixture-coordination-induced electron localization strategy to stabilize the lead-free tin perovskite TEA 2 SnI 4 (TEAI is 2-thiopheneethylammonium iodide) by incorporating cyanuric acid. We demonstrate that a crucial function of the coordination is to amplify the electronic effects, even for those Sn atoms that aren't strongly bonded with cyanuric acid owing to the formation of hydrogen-bonded tautomeric dimer and trimer superstructures on the perovskite surface. This electron localization weakens adverse effects from Anderson localization and improves ordering in the crystal structure of TEA 2 SnI 4 . These factors result in a two-orders-of-magnitude reduction in the non-radiative recombination capture coefficient and an approximately twofold enhancement in the exciton binding energy. Our lead-free PeLED has an external quantum efficiency of up to 20.29%, representing a performance comparable to that of state-of-the-art lead-containing PeLEDs 6-12 . We anticipate that these findings will provide insights into the stabilization of Sn(II) perovskites and further the development of lead-free perovskite applications., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published
2023
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5. Additive manufacturing of silica aerogels.

Author

Zhao S, Siqueira G, Drdova S, Norris D, Ubert C, Bonnin A, Galmarini S, Ganobjak M, Pan Z, Brunner S, Nyström G, Wang J, Koebel MM, and Malfait WJ

Abstract

Owing to their ultralow thermal conductivity and open pore structure 1-3 , silica aerogels are widely used in thermal insulation 4,5 , catalysis 6 , physics 7,8 , environmental remediation 6,9 , optical devices 10 and hypervelocity particle capture 11 . Thermal insulation is by far the largest market for silica aerogels, which are ideal materials when space is limited. One drawback of silica aerogels is their brittleness. Fibre reinforcement and binders can be used to overcome this for large-volume applications in building and industrial insulation 5,12 , but their poor machinability, combined with the difficulty of precisely casting small objects, limits the miniaturization potential of silica aerogels. Additive manufacturing provides an alternative route to miniaturization, but was "considered not feasible for silica aerogel" 13 . Here we present a direct ink writing protocol to create miniaturized silica aerogel objects from a slurry of silica aerogel powder in a dilute silica nanoparticle suspension (sol). The inks exhibit shear-thinning behaviour, owing to the high volume fraction of gel particles. As a result, they flow easily through the nozzle during printing, but their viscosity increases rapidly after printing, ensuring that the printed objects retain their shape. After printing, the silica sol is gelled in an ammonia atmosphere to enable subsequent processing into aerogels. The printed aerogel objects are pure silica and retain the high specific surface area (751 square metres per gram) and ultralow thermal conductivity (15.9 milliwatts per metre per kelvin) typical of silica aerogels. Furthermore, we demonstrate the ease with which functional nanoparticles can be incorporated. The printed silica aerogel objects can be used for thermal management, as miniaturized gas pumps and to degrade volatile organic compounds, illustrating the potential of our protocol.

Published
2020
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