Evaporating seawater and separating salt from water is one of the most promising solutions for global water scarcity. State‐of‐the‐art water desalination devices combining solar harvesting and heat localization for evaporation using nanomaterials still suffer from several issues in energy efficiency, long‐term performance, salt fouling, light blocking, and clean water collection in real‐world applications. To address these issues, this work devises plasma‐enabled multifunctional all‐carbon nanoarchitectures with on‐surface waterways formed by nitrogen‐doped hydrophilic graphene nanopetals (N‐fGPs) seamlessly integrated onto the external surface of hydrophobic self‐assembled graphene foam (sGF). The N‐fGPs simultaneously transport water and salt ions, absorb sunlight, serve as evaporation surfaces, then capture the salts, followed by self‐cleaning. The sGF ensures effective thermal insulation and enhanced heat localization, contributing to high solar‐vapor efficiency of 88.6 ± 2.1%. Seamless connection between N‐fGPs and sGF and self‐cleaning of N‐fGP structures by redissolution of the captured salts in the waterways lead to long‐term stability over 240 h of continuous operation in real seawater without performance degradation, and a high daily evaporation yield of 15.76 kg m−2. By eliminating sunlight blocking and guiding condensed vapor, a high clean water collection ratio of 83.5% is achieved. The multiple functionalities make the current nanoarchitectures promising as multipurpose advanced energy materials.
Solar-thermal conversion is a key technology in harvesting solar energy for a diverse range of applications including water vapor generation. However, simultaneously ultrafast and highly efficient solar-thermal conversion and scalable fabrication of materials and devices to achieve such performance in practical applications still remain the key unmet challenges. Here we report a hierarchical nanoarchitecture that integrates vertically oriented graphene nanosheets and highly porous graphene aerogel to achieve ultrafast solar-thermal response (a temperature increase of 169.7 C within 1 s), resulting from superior photonic absorption and excellent thermal insulation. Through engineering surface water pathways and minimizing interfacial thermal resistances, ultrafast solar-thermal response (reaching 100 C within 34 s) and simultaneously high energy efficiency (89.4%) for saturated vapor generation at 10 sun is achieved. Importantly, we demonstrate high-throughput, scalable fabrication of the unique nanoarchitecture. Ultrafast medical sterilization is demonstrated as a potential practical application of this green, nanotechnology-enhanced system for large-scale solar energy harvesting.
Oil
spills remain a worldwide challenge and need emergency “spill-SOS”
actions when they occur. Conventional methods suffer from complex
processes and high cost. Here, we demonstrate a solar-heating siphon-capillary
oil skimmer (S-SOS) that harvests solar energy, gravitational potential
energy, and solid surface energy to enable efficient oil spill recovery
in a self-pumping manner. The S-SOS is assembled by an inverted U-shape
porous architecture combining solar-heating, siphon, and capillary
effects, and works without any external power or manual interventions.
Importantly, solid surface energy is used by capillary adsorption
to enable the self-starting behavior, gravitational potential energy
is utilized by siphon transport to drive the oil flow, and solar energy
is harvested by solar-thermal conversion to facilitate the transport
speed. In the proof-of-concept work, an all-carbon hierarchical architecture
(VG/GF) is fabricated by growing vertically oriented graphene nanosheets
(VGs) on a monolith of graphite felt (GF) via a plasma-enhanced method
to serve as the U-shape architecture. Consequently, an oil-recovery
rate of 35.2 L m–2 h–1 is obtained
at ambient condition. When exposed to normal solar irradiation, the
oil-recovery rate dramatically increases to 123.3 L m–2 h–1. Meanwhile, the solar-thermal energy efficiency
is calculated to be 75.3%. Moreover, the S-SOS system presents excellent
stability without obvious performance-degradation over 60 h. The outstanding
performance is ascribed to the enhanced siphon action, capillary action,
photonic absorption, and interfacial heating in the plasma-made graphene
nanostructures. Multiple merits make the current S-SOS design and
the VG/GF nanostructures promising for efficient oil recovery and
transport of energy stored in chemical bonds.
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