College of Materials Science and Engineering, Qingdao University of Science and Technology, Qingdao 266042, PR China.
School of Materials Science and Engineering, Harbin Institute of Technology (Weihai), Weihai 264209, PR China.
J Colloid Interface Sci. 2023 Jan 15;630(Pt A):297-305. doi: 10.1016/j.jcis.2022.09.133. Epub 2022 Sep 29.
Solar steam generation (SSG) is a very promising desalination technology. However, new photothermal materials are still to be explored to further reduce the cost, and the device structure is still to be innovated to improve the structural integrality and evaporation performance. In this work, an all-in-one highly-efficient and self-floating jellyfish-like SSG (SFJ-SSG) is developed based on partially carbonized Enteromorpha (EA) aerogel (PCEAA). The carbonized top surface exhibits high solar absorption ability and excellent photothermal effect, while the uncarbonized EA retains the hydrophilicity and high-water transport capability due to the nature of tubular algal plant. Moreover, the heat produced by photothermal effect of the carbonized EA is confined at the top surface due to the thermal insulation of the uncarbonized layer, which is very beneficial for interfacial water evaporation. After optimizing the carbonization time and the height of the SFJ-SSG, a high evaporation rate of 1.87 kg mh is obtained under 1.0 sun irradiation, which outcompetes most SSG based on carbonized biomass. The development of SFJ-SSG based on EA not only minimizes the cost of SSG, but also solves the EA pollution, ensuring the broad prospect in practical applications.
太阳能蒸汽发电(SSG)是一种很有前途的海水淡化技术。然而,仍需要探索新的光热材料来进一步降低成本,并且需要创新装置结构以提高结构完整性和蒸发性能。在这项工作中,基于部分碳化的浒苔(EA)气凝胶(PCEAA)开发了一种一体化的高效自浮水母状 SSG(SFJ-SSG)。碳化的顶部表面表现出高的太阳能吸收能力和优异的光热效应,而未碳化的 EA 由于管状藻类植物的性质而保持亲水性和高的水传输能力。此外,由于未碳化层的隔热作用,碳化 EA 的光热效应产生的热量被限制在顶部表面,这非常有利于界面水蒸发。通过优化碳化时间和 SFJ-SSG 的高度,在 1.0 个太阳辐照下获得了 1.87 kg m h 的高蒸发率,超过了大多数基于碳化生物质的 SSG。基于 EA 的 SFJ-SSG 的开发不仅使 SSG 的成本最小化,而且解决了 EA 污染问题,确保了在实际应用中的广阔前景。
