3 research outputs found
Nature-Inspired Surface Engineering for Efficient Atmospheric Water Harvesting
Atmospheric water harvesting is a sustainable solution
to global
water shortage, which requires high efficiency, high durability, low
cost, and environmentally friendly water collectors. In this paper,
we report a novel water collector design based on a nature-inspired
hybrid superhydrophilic/superhydrophobic aluminum surface. The surface
is fabricated by combining laser and chemical treatments. We achieve
a 163° contrast in contact angles between the superhydrophilic
pattern and the superhydrophobic background. Such a unique superhydrophilic/superhydrophobic
combination presents a self-pumped mechanism, providing the hybrid
collector with highly efficient water harvesting performance. Based
on simulations and experimental measurements, the water harvesting
rate of the repeating units of the pattern was optimized, and the
corresponding hybrid collector achieves a water harvesting rate of
0.85 kg m–2 h–1. Additionally,
our hybrid collector also exhibits good stability, flexibility, as
well as thermal conductivity and hence shows great potential for practical
application
Practical GHz single-cavity all-fiber dual-comb laser for high-speed spectroscopy
Dual-comb spectroscopy (DCS) with few-GHz tooth spacing that provides the optimal trade-off between spectral resolution and refresh rate is a powerful tool for measuring and analyzing rapidly evolving transient events. Despite such an exciting opportunity, existing technologies compromise either the spectral resolution or refresh rate, leaving few-GHz DCS with robust design largely unmet for frontier applications. In this work, we demonstrate a novel GHz DCS by exploring the multimode interference-mediated spectral filtering effect in an all-fiber ultrashort cavity configuration. The GHz single-cavity all-fiber dual-comb source is seeded by a dual-wavelength mode-locked fiber laser operating at fundamental repetition rates of about 1.0 GHz differing by 148 kHz, which has an excellent stability in the free-running state that the Allan deviation is only 101.7 mHz for an average time of 1 second. Thanks to the large repetition rate difference between the asynchronous dichromatic pulse trains, the GHz DCS enables a refresh time as short as 6.75 us, making it promising for studying nonrepeatable transient phenomena in real time. To this end, the practicality of the present GHz DCS is validated by successfully capturing the 'shock waves' of balloon and firecracker explosions outdoors. This GHz single-cavity all-fiber dual-comb system promises a noteworthy improvement in acquisition speed and reliability without sacrificing measurement accuracy, anticipated as a practical tool for high-speed applications
Luffa-Sponge-Like Glass–TiO<sub>2</sub> Composite Fibers as Efficient Photocatalysts for Environmental Remediation
Structural
design of photocatalysts is of great technological importance for
practical applications. A rational design of architecture can not
only promote the synthetic performance of photocatalysts but also
bring convenience in their application procedure. Nanofibers have
been established as one of the most ideal architectures of photocatalysts.
However, simultaneous optimization of the photocatalytic efficiency,
mechanical strength, and thermal/chemical tolerance of nanofibrous
photocatalysts remains a big challenge. Here, we demonstrate a novel
design of TiO<sub>2</sub>–SiO<sub>2</sub> composite fiber as
an efficient photocatalyst with excellent synthetic performance. Core–shell
mesoporous SiO<sub>2</sub> fiber with high flexibility was employed
as the backbone for supporting ultrasmall TiO<sub>2</sub> nanowhiskers
of the anatase phase, constructing core@double-shell fiber with luffa-sponge-like
appearance. Benefitting from their continuously long fibrous morphology,
highly porous structure, and completely inorganic nature, the TiO<sub>2</sub>–SiO<sub>2</sub> composite fibers simultaneously possess
high photocatalytic reactivity, good flexibility, and excellent thermal
and chemical stability. This novel architecture of TiO<sub>2</sub>–SiO<sub>2</sub> glass composite fiber may find extensive
use in the environment remediation applications