Solar steam nanobubbles

Polman A.

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Solar steam nanobubbles

机译：太阳能蒸汽纳米气泡

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Silica-gold core-shell nanoparticles that are immersed in water act as efficient nanoscale generators of steam when illuminated with sunlight. In their paper in this issue of ACS Nano, Halas, Nordlander, and co-workers demonstrate this intriguing phenomenon that results from the nucleation of steam at the surface of individual nanoparticles that are heated by the sun. The same effect is also used to demonstrate distillation of ethanol. The solar steam nanobubble generation phenomenon results from the complex interplay of many different phenomena that occur at the nanoscale, and can find a broad range of applications.

机译：当被阳光照射时，浸入水中的硅金核壳纳米粒子可作为有效的纳米级蒸汽发生器。 Halas，Nordlander及其同事在本期ACS Nano中的论文中证明了这种引人入胜的现象，该现象是由太阳加热的各个纳米颗粒表面的蒸汽成核引起的。同样的效果也可用于证明乙醇的蒸馏。太阳蒸汽纳米气泡的产生现象是由于在纳米尺度上发生的许多不同现象之间复杂的相互作用所致，可以找到广泛的应用。

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《ACS nano》 |2013年第1期|共4页
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Polman A.;
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正文语种 eng
中图分类分子物理学、原子物理学;
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1. Solar steam nanobubbles [J] . Polman A. ACS nano . 2013,第1期

机译：太阳能蒸汽纳米气泡
2. A high efficiency solar steam generation system with using residual heat to enhance steam escape [J] . Bai Binglin, Yang Xiaohong, Tian Rui, Desalination: The International Journal on the Science and Technology of Desalting and Water Purification . 2020,第1期

机译：高效太阳能蒸汽发电系统，采用残留热量增强蒸汽逸出
3. Steam from the Sun New spongelike structure converts solar energy into steam [J] . Sally Wood Materials AUSTRALIA . 2014,第3期

机译：来自太阳的蒸汽新的海绵状结构将太阳能转化为蒸汽
4. Steam Generation Control in Solar Invictus 53S - A Parabolic Dish Solar Collector for Direct Steam Generation [C] . Wajahat Ali, Zubair Usman, Umer Jamil International Conference on Concentrating Solar Power and Chemical Energy Systems . 2017

机译：太阳能Invictus 53s的蒸汽发生控制 - 一种用于直接蒸汽发电的抛物线碟太阳能收集器
5. Ammonia Based Solar Thermochemical Energy Storage System for Direct Production of High Temperature Supercritical Steam [D] . Chen, Chen. 2017

机译：基于氨的太阳能热化学储能系统，用于直接生产高温超临界蒸汽
6. Porous Carbon Nanofoam Derived From Pitch as Solar Receiver for Efficient Solar Steam Generation [O] . Lihua Chen, Shujing Zhao, Qi‐Meige Hasi, 2020

机译：沥青衍生的多孔碳纳米泡沫作为太阳能接收器可高效产生太阳能蒸汽
7. This article presents a new numerical model describing the behaviour of a thermally thick wood sample exposed to high solar heat flux (above 1 MW/m2). A preliminary study based on dimensionless numbers is used to classify the problem and support model building assumptions. Then, a model based on mass, momentum and energy balance equations is proposed. These equations are coupled with liquid-vapour drying model and pseudo species biomass degradation model. By comparing to a former experimental study, preliminary results have shown that these equations are not enough to accurately predict biomass behaviour under high solar heat flux. Indeed, a char layer acting as radiative shield forms on the sample exposed surface. In addition to this classical set of equations, it is mandatory to take into account radiation penetration into the medium. Furthermore, as biomass contains water, medium deformation consecutively to char steam gasification must also be implemented. Finally, with the addition of these two strategies, the model is able to properly capture the degradation of biomass when exposed to high radiative heat flux over a range of sample initial moisture content. Additional insights of biomass behaviour under high solar heat flux were also derived. Drying, pyrolysis and gasification fronts are present at the same time inside of the sample. The coexistence of these three thermochemical fronts leads to char gasification by the steam produced from drying of the sample, which it is the main phenomenon behind medium ablation. [O] . Pozzobon, Victor, Salvador, Sylvain, Bézian, Jean Jacques 2018

机译：本文提供了一个新的数值模型，该模型描述了暴露于高太阳热通量（高于1 / MW / m2）的热厚木材样品的行为。基于无量纲数的初步研究用于对问题进行分类并支持模型构建假设。然后，提出了一种基于质量，动量和能量平衡方程的模型。这些方程式与液体蒸汽干燥模型和假物种生物质降解模型耦合。通过与以前的实验研究进行比较，初步结果表明，这些方程不足以准确预测高太阳热通量下的生物量行为。的确，在样品暴露的表面上形成了充当辐射屏蔽层的炭层。除了这套经典的方程式之外，还必须考虑到辐射向介质的渗透。此外，由于生物质中含有水，因此还必须在炭蒸气汽化后进行连续的介质变形。最后，通过添加这两种策略，该模型能够在一定范围的样品初始水分含量下暴露于高辐射热通量的情况下，正确捕获生物质的降解。还得出了在高太阳热通量下生物量行为的其他见解。样品内部同时存在干燥，热解和气化前沿。这三个热化学前沿的共存会导致样品干燥产生的蒸汽产生焦炭气化，这是介质烧蚀的主要现象。

Solar steam nanobubbles

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