Polyphenol-mediated hierarchical porous hydrogel evaporators for accelerated water transport and reduced evaporation enthalpy.

Quantities of faecal material produced by the Japanese oyster varied seasonally, reaching maxima in October. This seasonal rate was caused by activities of the gills of oysters. Daily quantities (V) of suspended matter removed by the gills of a single oyster could be calculated by means of the equation V(mg/day)=suspended matter (mg/l) × filtration rate (l/h)×24. As a part of this calculated quantity was digested and absorbed, quantities of faecal material produced were a little smaller than that of suspended matter calculated using the above equation. Oysters retained approximately 40 to 50 per cent of the suspended matter contained in the inhalent current and this rate did not vary throughout the year, therefore, daily quantities of suspended matter removed could also be estimated from the rates of water transport. Rates of filtration and water transport per gram wet weight of meat were a linear function of the water temperature (t°C) and could be expressed by equations Filtration rate (l/h/g of meat) =-0.308+0.066t Rate of water transport (l/h/g of meat)=-0.002+0.109t

Ion transport in rabbit ileal mucosa. 3. Effects of catecholamines.

Self-Healing Hydrophilic Porous Photothermal Membranes for Durable and Highly Efficient Solar-Driven Interfacial Water Evaporation

Exogenous gibberellic acid was applied to regulate fruit growth of grapes to acquire high quality seedless berries. The vascular bundles provide the pathway of water and nutrient transport into the fruit and play an important role in berry growth and sugar accumulation. Therefore, changes in berry size and quality are closely related to the structure and function of the vascular tissue. In this study, 10-year-old “Shine Muscat” grape vines were treated with GA3 in grapevine production. Based on previous research and experimental environmental conditions, four treatments were applied: elongating cluster（5 mg L−1 GA3 on Apr. 28）+ seedless（25 mg L−1 GA3 on May. 24）+ expanding（50 mg L−1 GA3 on Jun. 7） (T1), seedless（25 mg L−1 GA3 on May. 24）+ expanding（50 mg L−1 GA3 on Jun. 7） (T2), expanding（50 mg L−1 GA3 on Jun. 7） (T3) and water (CK). Compared to CK, all fruits treated with GA3 had greater berry size. In addition, GA3 treated grapes had greater vascular bundle areas, including the areas of both phloem and xylem, as well as a greater number of vessels compared to control fruit. During the first rapid growth stage, water transport into the grape was rapid and did not differ among treatments. During veraison, the water transport rate among the four treatments differed, and the rank of speed was T2>T3>CK>T1. Therefore, we found that GA3 treatment can significantly promote the differentiation of vascular tissues and improve water transport capacity and phloem sugar unloading; T2 promoted the development of vascular bundles, enhanced water transport speed and phloem sugar unloading of fruit after veraison, and increased berry size.

ASTM permeability cup method and capacitance technique were used to study water (vapor) transport processes in inhibitor-free, and praseodymium (Pr)-containing aerospace primer films. The water transport rate from the cup method was found much higher in inhibitor-free epoxy film than Pr-containing aerospace primer films when fully cured. The change in film capacitance, determined by electrochemical impedance spectroscopy (EIS), was quantitatively correlated with the total amount of in-plane water transported in primer films. The water diffusion coefficients derived from the permeability cup and capacitance data were in an order of magnitude of 10-8 ~ 10-7 -cm2/s, while the diffusion coefficient of inhibitor ion (Pr+3), calculated from the side-by-side diffusion cell measurements, was in an order of magnitude of 10-10 cm2/s, significantly lower than water transport within primer films. The effects of inhibitor ion (Pr+3) concentration, solution pH on inhibitor transport process were also studied. It was found that both Pr and Ca-containing pigments were dissolved (leached) more significantly in strong acidic (pH ~2) than in weak acidic (pH ~ 5.5) environments.

Cost management and scalable fabrication without sacrificing the purification performance are two critical issues that should be addressed before the practical commercial application of solar-driven evaporators. To address this challenge, we report a porous photothermal hydrogel coating prepared by mixing the raw materials of sawdust (SD), carbon nanotubes (CNTs), and poly(vinyl alcohol) (PVA), which was applied to undergo a blading-drying-rehydration process to prepare the evaporator. In the coating, the crystallized PVA gives the coating a solid skeleton and the sawdust endows the coating with a loose structure to sufficiently enhance the water transportation capacity. As a result, the evaporator coated with the hydrogel coating displays a high water transport rate and efficient evaporation performance along with excellent mechanical properties and stability. Water migrates vertically upward 5 cm within 4 minutes. The compressive stress of the rehydrated hydrogel coating reaches as high as 14.28 MPa under 80% strain. The water evaporation rate of the hydrogel coating-based evaporator reaches 1.833 kg m-2 h-1 corresponding to an energy efficiency of 83.29% under 1 sun irradiation. What is more, the hydrogel coating retains its excellent evaporation performance and stability after immersion in acid or alkali solution, ultrasound treatment, and long-time immersion in water. Under outdoor conditions, the water evaporation rate of the hydrogel coating-based evaporator is about 5.69 times higher than that of pure water. This study proposes a rapid, cost-effective, and scalable strategy for preparing a high-performance photothermal hydrogel coating that will find sustainable and practical application in solar-driven water purification.

Intensity of transpiration, intensity of water absorption, water saturation deficit (w.s.d.) in different parts of samples and rate of water transport was investigated in samples from leaf tissue of fodder cabbage and banana-tree.In all experiments (at initial w.s.d. 0% and 20%, in samples from upper, middle and lower leaves of fodder cabbage and from leaves of banana-tree) a distinct gradient of w.s.d. in the direction of transport of water was determined, therefore the limiting factor in the water balance was rate of water transport and not rate of water absorption.The lowest amount of water was always transported within transpiring part of sample. When the initial w.s.d. was 0% not only the water transported by tissue from the environment, but also the water of the leaf tissue itself took part in water lost by transpiration and therefore water stress originated in the whole sample. At an initial w.s.d. of 20%, the rate of water absorption was higher than the rate of water transport and therefore the increase of w.s.d. in the transpiring part of the sample was accompanied by a simultaneous decrease of w.s.d. in the transporting part.An increase in the value of w.s.d. in leaf tissue proportionally increased the resistance of water transport in the liquid phase (on the average from 1·7 . 103 to 6·7 . 103 atm min cm2 g−1) and also in the gaseous phase (on the average from 2·7 . 10−2 to 14·0 . 10−2 min cm−1).It was proved that insufficient rate of water transport can be responsible for the origin of water stress. At the same time the rate of water transport was influenced by the value of the w.s.d. since every change of w.s.d. in leaf tissue not only the gradient of water potential changed but also the resistance to water transport.

Interfacial evaporation using porous hydrogels has demonstrated highly effective solar evaporation performance under natural sunlight to ensure an affordable clean water supply. However, it remains challenging to realize scalable and ready-to-use hydrogel materials with durable mechanical properties. Here, self-assembled templating (SAT) is developed as a simple yet effective method to fabricate large-scale elastic hydrogel evaporators with excellent desalination performance. The highly interconnected porous structure of the hydrogels with low tortuosity and tunable pore size enables high level of tunability on the water transport rate. With superior elasticity, the porous hydrogels are easy to process with a rapid shape recovery after being rolled, folded, and twisted over hundred times, and exhibit highly effective and stable evaporation with an evaporation rate of ≈2.8 kg m-2 h-1 and ≈90 % solar-to-vapor efficiency. It is anticipated that this SAT strategy, without the typical need for freeze-drying, will accelerate the industrialization of hydrogel solar evaporators for practical applications.

Interfacial evaporation using porous hydrogels has demonstrated highly effective solar evaporation performance under natural sunlight to ensure an affordable clean water supply. However, it remains challenging to realize scalable and ready‐to‐use hydrogel materials with durable mechanical properties. Here, self‐assembled templating (SAT) is developed as a simple yet effective method to fabricate large‐scale elastic hydrogel evaporators with excellent desalination performance. The highly interconnected porous structure of the hydrogels with low tortuosity and tunable pore size enables high level of tunability on the water transport rate. With superior elasticity, the porous hydrogels are easy to process with a rapid shape recovery after being rolled, folded, and twisted over hundred times, and exhibit highly effective and stable evaporation with an evaporation rate of ≈2.8 kg m−2 h−1 and ≈90 % solar‐to‐vapor efficiency. It is anticipated that this SAT strategy, without the typical need for freeze‐drying, will accelerate the industrialization of hydrogel solar evaporators for practical applications.

Target analysis studies of red cell water and urea transport

Water and ion transport in nylon as studied by NMR

Solar-driven desalination (SDD) is a promising technology for addressing water scarcity. However, how to overcome the trade-off between water transportation and heat supply of the evaporator to achieve a high evaporation rate and good salt tolerance simultaneously remains a challenge. Here, a novel all-in-one multi-functional SDD evaporator undergoing gradient heating is used. This evaporator incorporates a hydrophilic PDA (polydopamine)@CNT(carbon nanotube)/PVA (polyvinyl alcohol) aerogel with vertically aligned structures as the water evaporation layer, enabling rapid water transportation. Surrounding the evaporation layer, there is a photothermal hydrophobic CCP (cotton/CNT/polydimethylsiloxane) film that serves as the heating layer, enhancing the heat supply to the evaporation layer. This innovative design strikes a favorable balance between water transportation and heat supply, facilitating high evaporation rates and good salt tolerance simultaneously, while also maximizing electricity generation. Due to the wettability difference between the evaporation layer (PVA aerogel) and heating layer (CCP film), a record stable temperature gradient of nearly 70 °C was formed between the CCP film and the PVA aerogel under 1 sun irradiation, so that heat on the high-temperature CCP film was continuously transferred to the low-temperature aerogel through its thermal conductive network, leading to a high evaporation rate of 6.96 kg m-2 h-1 under 1 sun irradiation in 5.0 wt% sodium chloride (NaCl) brine (higher than the world average seawater salinity (3.5 wt%)). Meanwhile, high flux directional flow of brine generated 130 mV stable voltage and 120 μA circuit current. Furthermore, the evaporator illustrates good stability for consecutive 7 days of testing and shows industry-leading comprehensive performance of SDD in actual use. More importantly, it was tested in real Bohai seawater under weak natural light, and fresh water generated can meet the recommended daily intake of water for 2.6 households and the simultaneously generated voltage reaches above 60 mV. In addition, the evaporator exhibits good adsorption capacity for heavy metals and dye molecules. This simple and universal solar evaporation structure is suitable for the assembly of gradient thermal structures for most solar thermal materials reported in the literature, which provides a new route for maximizing the use of solar energy for freshwater and electricity generation.

Specifically, the extraction yield, the content of total polyphenols by Folin-Ciocalteu colorimetric assay, and the antioxidant activity by FRAP (Ferric Reducing Antioxidant Power) were measured. In particular the following specific phenolic compounds were detected and determined by HPLC analysis: gallic, chlorogenic, ferulic, p-coumaric, and ellagic acids, (+)-catechin, (–)-epicatechin, and rutin. The values of extraction yield and total polyphenol content decreased according to the extraction solvent in the following order: absolute methanol > 70% methanol > water. The antioxidant activity showed the opposite trend among the three types of extraction. The values obtained from the analysis were higher in chestnut rather than in hazelnut shell. The specific amount of phenolic compounds varied depending on the solvent used for the extraction. Gallic acid was found in all samples extracted, though with lower values in hazelnut shells treated in water. High values of (–)-epicatechin, chlorogenic acid and ellagic acid were found in hazelnut samples extracted with hydro-alcoholic solution and water. A fair amount of catechin was detected in all samples, whilst rutin, p-coumaric acid and ferulic acid were present in small amounts, although the best results were obtained in absolute methanol. The results of this study demonstrated that with a simple extraction process considerable amount of phenolic compounds with high antioxidant activity were obtained from chestnut and hazelnut shells.

Recent studies have shown that water absorption changes the mechanical and transport properties of Nafion by orders of magnitude. The unusually large changes in properties are indicative of microstructural changes induced by water absorption. The experimental findings of changes in proton conduction, water transport, elastic modulus, and stress relaxation are highlighted and explained by microphase segregation of hydrophilic domains resulting from water absorption. Water absorption is proposed to cause clustering of hydrophilic sulfonic acid groups and water within a hydrophobic polytetrafluoroethylene matrix. The hydrophilic domains form a network that facilitates transport and create physical cross-links that stiffen Nafion. At high temperature and low water activity, the entropy of de-mixing breaks the clusters apart, causing a large drop in elastic modulus of the polymer and a large decrease in the rates of water and proton transport.

The sudden changes in the rates of transpiration and water uptake which occurred when the osmotic potential of the nutrient solution surrounding the roots of young wheat plants was rapidly changed were studied. The transpiration was measured by the aid of the microwave hygrometer and the water uptake by a recording poto‐meter specially built for this investigation.When the osmotic potential of the nutrient solution was rapidly increased by adding mannitol, there was a temporary transpiration increase. The maximum increase was greater but the total time of the temporary increase shorter when a higher mannitol concentration was used. The quantity of water transpired by the shoots due to the temporary transpiration increase seemed to be fairly constant irrespectively of the mannitol concentration. The water transport to the shoots was immediately reduced when the osmotic potential was rapidly increased. The immediate reduction was greater when a higher mannitol concentration was used. After the immediate reduction the rate of water transport increased without delay.When the osmotic potential of the nutrient solution was rapidly decreased by withdrawing mannitol there was a temporary transpiration decrease, and the water transport to the shoots was immediately increased. After this increase the rate of water transport started to decrease at once. When, however, the mannitol concentration had been 0.30Mor higher, the transpiration rate increased progressively, and the change of the rate of water transport was small.The results indicate that the primary effect of the rapidly changed osmotic potential is localized to the root surface. The rapidly reduced water transport to the shoots after adding mannitol brings about the temporary transpiration increase. The course of events after withdrawing mannitol is just the reverse to that when adding mannitol.