scholarly journals Water uptake mechanism and germination of Erythrina velutina seeds treated with atmospheric plasma

2016 ◽  
Vol 6 (1) ◽  
Author(s):  
Clodomiro Alves Junior ◽  
Jussier de Oliveira Vitoriano ◽  
Dinnara Layza Souza da Silva ◽  
Mikelly de Lima Farias ◽  
Nadjamara Bandeira de Lima Dantas
Keyword(s):  
Water Uptake ◽  
Atmospheric Plasma ◽  
Uptake Mechanism

Hydrodynamic volume of trehalose and its water uptake mechanism

2019 ◽  
Vol 249 ◽  
pp. 106145 ◽  
Author(s):  
Nader Sakhaee ◽  
Sahar Sakhaee ◽  
Ahmad Takallou ◽  
Akbar Mobaraki ◽  
Mina Maddah ◽  
...  
Keyword(s):  
Water Uptake ◽  
Uptake Mechanism ◽  
Hydrodynamic Volume

scholarly journals Molecular scale description of interfacial mass transfer in phase separated aqueous secondary organic aerosol

2021 ◽  
Author(s):  
Mária Lbadaoui-Darvas ◽  
Satoshi Takahama ◽  
Athanasios Nenes
Keyword(s):  
Surface Tension ◽  
Free Energy ◽  
Water Uptake ◽  
Concentration Gradient ◽  
Driving Forces ◽  
Uptake Mechanism ◽  
Energy Profiles ◽  
Ideal Mixing ◽  
Molecular Scale ◽  
Free Energy Profiles

Abstract. Liquid-liquid phase separated (LLPS) aerosol particles are known to exhibit increased cloud condensation nuclei (CCN) activity compared to well mixed ones due to a complex effect of low surface tension and non-ideal mixing. The relation between the two contributions as well as the molecular scale mechanism of water uptake in the presence of an internal interface within the particle is to date not fully understood. Here we present steered molecular dynamics simulation studies of water uptake by a vapor/hydroxi-cis-pinonic acid/water double interfacial system at 200 K and 300 K. Simulated free energy profiles are used to map the water uptake mechanism and are decomposed into energetic and entropic contributions to highlight its main thermodynamic driving forces. Atmospheric implications are discussed in terms of gas/particle partitioning, intraparticle water redistribution timescales, and equilibrium saturation ratios of water vapor. Our simulations reveal a strongly temperature-dependent water uptake mechanism, whose most prominent features are determined by local extrema in conformational and orientational entropies near the organic/water interface which result in a reduced core uptake coefficient (ko/w = 0.05) and a concentration gradient of water in the organic shell at the higher temperature, while their effect is negligible at 200 K due to the explicit temperature dependence of entropic terms in the free energy profiles. The concentration gradient, which is a molecular level manifestation of non-ideal mixing – suspected to be a major factor to increase LLPS CCN activity – is responsible for maintaining LLPS and low surface tension even at very high relative humidities, thus reducing critical supersaturations. Thermodynamic driving forces are rationalised to be generalizable across different compositions. The conditions under which single uptake coefficients can be used to to describe growth kinetics as a function of temperature in LLPS particles are described.

scholarly journals Molecular-scale description of interfacial mass transfer in phase-separated aqueous secondary organic aerosol

2021 ◽  
Vol 21 (23) ◽  
pp. 17687-17714
Author(s):  
Mária Lbadaoui-Darvas ◽  
Satoshi Takahama ◽  
Athanasios Nenes
Keyword(s):  
Surface Tension ◽  
Free Energy ◽  
Liquid Phase ◽  
Water Uptake ◽  
Driving Forces ◽  
Uptake Mechanism ◽  
Energy Profiles ◽  
Ideal Mixing ◽  
Molecular Scale ◽  
Free Energy Profiles

Abstract. Liquid–liquid phase-separated (LLPS) aerosol particles are known to exhibit increased cloud condensation nuclei (CCN) activity compared to well-mixed ones due to a complex effect of low surface tension and non-ideal mixing. The relation between the two contributions as well as the molecular-scale mechanism of water uptake in the presence of an internal interface within the particle is to date not fully understood. Here we attempt to gain understanding in these aspects through steered molecular dynamics simulation studies of water uptake by a vapor–hydroxy-cis-pinonic acid–water double interfacial system at 200 and 300 K. Simulated free-energy profiles are used to map the water uptake mechanism and are separated into energetic and entropic contributions to highlight its main thermodynamic driving forces. Atmospheric implications are discussed in terms of gas–particle partitioning, intraparticle water redistribution timescales and water vapor equilibrium saturation ratios. Our simulations reveal a strongly temperature-dependent water uptake mechanism, whose most prominent features are determined by local extrema in conformational and orientational entropies near the organic–water interface. This results in a low core uptake coefficient (ko/w=0.03) and a concentration gradient of water in the organic shell at the higher temperature, while entropic effects are negligible at 200 K due to the association-entropic-term reduction in the free-energy profiles. The concentration gradient, which results from non-ideal mixing – and is a major factor in increasing LLPS CCN activity – is responsible for maintaining liquid–liquid phase separation and low surface tension even at very high relative humidities, thus reducing critical supersaturations. Thermodynamic driving forces are rationalized to be generalizable across different compositions. The conditions under which single uptake coefficients can be used to describe growth kinetics as a function of temperature in LLPS particles are described.

Water Relations in an Insect, Thermobia Domestica

1971 ◽  
Vol 55 (2) ◽  
pp. 435-448
Author(s):  
A. Y. K. OKASHA
Keyword(s):  
Water Content ◽  
Water Uptake ◽  
Volume Regulation ◽  
Dry Matter ◽  
High Water ◽  
High Water Content ◽  
Uptake Mechanism ◽  
Thermobia Domestica ◽  
Moulting Cycle ◽  
Very High

1. Water uptake is not inhibited by centrifugation, exposure to 45 °C, burning of the integument or by submergence in water for 1 h. 2. Repeated desiccation followed by rehydration does not inhibit water uptake. This, however, results in insects with an extremely high water content. 3. Starvation also results in insects with a very high water content, the latter depending on the length of starvation, and also results in the depletion of dry matter. 4. Desiccation followed by rehydration does not result in any loss in dry matter additional to that caused by starvation. 5. The ability to rehydrate of insects desiccated at various stages of the moulting cycle is described. It is concluded that at the later stages of the moulting cycle water uptake ceases. 6. The results are discussed in the light of current theories of the uptake mechanism. It is suggested that the uptake mechanism is primarily concerned with volume regulation. 7. It is also suggested that anal blockage, which is known to arrest uptake, results in a nervous inhibition bringing about such an effect, rather than the rectum being the site of uptake.

Water Uptake Mechanism in Crispy Bread Crust

2008 ◽  
Vol 56 (15) ◽  
pp. 6439-6446 ◽  
Author(s):  
Neleke H. van Nieuwenhuijzen ◽  
Marcel B. J. Meinders ◽  
R. Hans Tromp ◽  
Rob J. Hamer ◽  
Ton van Vliet
Keyword(s):  
Water Uptake ◽  
Uptake Mechanism ◽  
Bread Crust

Water uptake by substituted amylose tablets: experimentation and numerical simulation

2009 ◽  
Vol 00 (00) ◽  
pp. 090904073309027-8
Author(s):  
H.W. Wang ◽  
S. Kyriacos ◽  
L. Cartilier
Keyword(s):  
Numerical Simulation ◽  
Water Uptake

Uptake, Internalization and Degradation of the Novel Plasminogen Activator Reteplase (BM 06.022) in the Rat

1995 ◽  
Vol 74 (06) ◽  
pp. 1501-1510 ◽  
Author(s):  
J Kuiper ◽  
H van de Bilt ◽  
U Martin ◽  
Th J C van Berkel
Keyword(s):  
Plasminogen Activator ◽  
Liver Cells ◽  
The Novel ◽  
Uptake Mechanism ◽  
Liver Uptake ◽  
Lysosomal Compartment ◽  
Β Phase ◽  
Α Phase ◽  
Parenchymal Liver

SummaryThe catabolism of the novel plasminogen activator reteplase (BM 06.022) was described. For this purpose BM 06.022 was radiolabelled with l25I or with the accumulating label l25I-tyramine cellobiose (l25I-TC).BM 06.022 was injected at a pharmacological dose of 380 μg/kg b.w. and it was cleared from the plasma in a biphasic manner with a half-life of about 1 min in the α-phase and t1/2of 20-28 min in the β-phase. 28% and 72% of the injected dose was cleared in the α-phase and β-phase, respectively. Initially liver, kidneys, skin, bones, lungs, spleen, and muscles contributed mainly to the plasma clearance. Only liver and the kidneys, however, were responsible for the uptake and subsequent degradation of BM 06.022 and contributed for 75% to the catabolism of BM 06.022. BM 06.022 was degraded in the lysosomal compartment of both organs. Parenchymal liver cells were responsible for 70% of the liver uptake of BM 06.022. BM 06.022 associated rapidly to isolated rat parenchymal liver cells and was subsequently degraded in the lysosomal compartment of these cells. BM 06.022 bound with low-affinity to the parenchymal liver cells (550 nM) and the binding of BM 06.022 could be displaced by t-PA (IC50 5.6 nM), indicating that the low-density lipoprotein receptor-related protein (LRP) could be involved in the binding of BM 06.022. GST-RAP, which is an inhibitor of LRP, could in vivo significantly inhibit the uptake of BM 06.022 in the liver.It is concluded that BM 06.022 is metabolized primarily in the liver and the kidneys. These organs take up and degrade BM 06.022 in the lysosomes. The uptake mechanism of BM 06.022 in the kidneys is unknown, while LRP is responsible for a low-affinity binding and uptake of BM 06.022 in parenchymal liver cells.

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