Equation of state of colloidal membranes

Microfluidic device allows for an in situ control of the polymer osmotic pressure that envelops a colloidal membrane. Tuning this pressure changes the membrane area and yields the equation of state of colloidal membranes.

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Diagnosis of in Situ Air Sparging Performance Using Groundwater Pressure Changes During Startup and Shutdown

10.21236/ada406092 ◽

2001 ◽

Author(s):

Richard L. Johnson ◽

Paul C. Johnson ◽

Tim L. Johnson ◽

Neil Thomas ◽

Andrea Leason

Keyword(s):

Air Sparging ◽

Pressure Changes

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Pressure variation in a fluid at rest (hydrostatics)

10.1093/oso/9780198719878.003.0004 ◽

2018 ◽

Author(s):

Marcel Escudier

Keyword(s):

Equation Of State ◽

Static Pressure ◽

Applied Pressure ◽

Pressure Variation ◽

Constant Density ◽

Fluid Temperature ◽

Earth’S Atmosphere ◽

Hydrostatic Equation ◽

Depth Increase ◽

Pressure Changes

The three fundamental principles for the variation of static pressure p throughout a body of fluid at rest are (a) the pressure at a point is the same in all directions (Pascal’s law), (b) the pressure is the same at all points on the same horizontal level, and (c) the pressure increases with depth z according to the hydrostatic equation. dp/dz= ρ‎g For a fluid with constant density ρ‎, the increase in pressure over a depth increase h is ρ‎gh, a result which can be used to analyse the response of simple barometers and manometers to applied pressure changes and differences. In situations where very large changes in pressure occur an equation of state may be required to relate pressure and density together with an assumption about the fluid temperature. The hydrostatic equation is still valid but more difficult to integrate, as illustrated by consideration of the earth’s atmosphere.

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Universal Equation of State Describes Osmotic Pressure throughout Gelation Process

Physical Review Letters ◽

10.1103/physrevlett.125.267801 ◽

2020 ◽

Vol 125 (26) ◽

Author(s):

Takashi Yasuda ◽

Naoyuki Sakumichi ◽

Ung-il Chung ◽

Takamasa Sakai

Keyword(s):

Equation Of State ◽

Osmotic Pressure ◽

Universal Equation ◽

Gelation Process

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Measuring the structure and equation of state of polyethylene terephthalate at megabar pressures

Scientific Reports ◽

10.1038/s41598-021-91769-0 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

J. Lütgert ◽

J. Vorberger ◽

N. J. Hartley ◽

K. Voigt ◽

M. Rödel ◽

...

Keyword(s):

Equation Of State ◽

Polyethylene Terephthalate ◽

Density Functional ◽

Equations Of State ◽

Md Simulations ◽

X Ray Diffraction ◽

Functional Theory ◽

Shock Hugoniot ◽

Highly Correlated

AbstractWe present structure and equation of state (EOS) measurements of biaxially orientated polyethylene terephthalate (PET, $$({\hbox {C}}_{10} {\hbox {H}}_8 {\hbox {O}}_4)_n$$ ( C 10 H 8 O 4 ) n , also called mylar) shock-compressed to ($$155 \pm 20$$ 155 ± 20 ) GPa and ($$6000 \pm 1000$$ 6000 ± 1000 ) K using in situ X-ray diffraction, Doppler velocimetry, and optical pyrometry. Comparing to density functional theory molecular dynamics (DFT-MD) simulations, we find a highly correlated liquid at conditions differing from predictions by some equations of state tables, which underlines the influence of complex chemical interactions in this regime. EOS calculations from ab initio DFT-MD simulations and shock Hugoniot measurements of density, pressure and temperature confirm the discrepancy to these tables and present an experimentally benchmarked correction to the description of PET as an exemplary material to represent the mixture of light elements at planetary interior conditions.

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A Thread/Fabric-Based Band as A Flexible and Wearable Microfluidic Device for Sweat Sensing and Monitoring

Lab on a Chip ◽

10.1039/d0lc01075h ◽

2021 ◽

Author(s):

Zhiqi Zhao ◽

Qiujin Li ◽

Linna Chen ◽

Yu Zhao ◽

Jixian Gong ◽

...

Keyword(s):

Microfluidic Device ◽

Point Of Care ◽

Monitoring Systems ◽

Biological Analytes

Flexible biosensors for monitoring systems have emerged as a promising portable diagnostics platform due to their potential for in situ point-of-care (POC) analytic devices. Assessment of biological analytes in sweat...

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Colloid osmotic pressure changes of dog's blood exposed to different mixtures of CO2 and air

Journal of Applied Physiology ◽

10.1152/jappl.1978.44.2.254 ◽

1978 ◽

Vol 44 (2) ◽

pp. 254-257 ◽

Cited By ~ 1

Author(s):

Y. Kakiuchi ◽

A. B. DuBois ◽

D. Gorenberg

Keyword(s):

Red Blood Cells ◽

Osmotic Pressure ◽

Cell Volume ◽

Blood Cells ◽

Freezing Point ◽

Colloid Osmotic Pressure ◽

Red Cell ◽

Freezing Point Depression ◽

Pressure Changes ◽

Different Levels

Hansen's membrane manometer method for measuring plasma colloid osmotic pressure was used to obtain the osmolality changes of dogs breathing different levels of CO2. Osmotic pressure was converted to osmolality by calibration of the manometer with saline and plasma, using freezing point depression osmometry. The addition of 10 vol% of CO2 to tonometered blood caused about a 2.0 mosmol/kg H2O increase of osmolality, or 1.2% increase of red blood cell volume. The swelling of the red blood cells was probably due to osmosis caused by Cl- exchanged for the HCO3- which was produced rapidly by carbonic anhydrase present in the red blood cells. The change in colloid osmotic pressure accompanying a change in co2 tension was measured on blood obtained from dogs breathing different CO2 mixtures. It was approximately 0.14 mosmol/kg H2O per Torr Pco2. The corresponding change in red cell volume could not be calculated from this because water can exchange between the plasma and tissues.

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Colloid osmotic pressure changes in human whole blood and separated plasma in vitro with changes in CO2 content and pH

Comparative Biochemistry and Physiology Part A Physiology ◽

10.1016/0300-9629(86)90452-4 ◽

1986 ◽

Vol 85 (3) ◽

pp. 587-591 ◽

Cited By ~ 3

Author(s):

Christopher S. Ogilvy ◽

C.Bruch Wenger ◽

P.Glenn Tremml ◽

Arthur B. Dubois

Keyword(s):

Osmotic Pressure ◽

Whole Blood ◽

Colloid Osmotic Pressure ◽

Human Whole Blood ◽

Pressure Changes

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Adenosine Triphosphate Measurement in Deep Sea Using a Microfluidic Device

Micromachines ◽

10.3390/mi9080370 ◽

2018 ◽

Vol 9 (8) ◽

pp. 370 ◽

Cited By ~ 6

Author(s):

Tatsuhiro Fukuba ◽

Takuroh Noguchi ◽

Kei Okamura ◽

Teruo Fujii

Keyword(s):

Adenosine Triphosphate ◽

Microfluidic Device ◽

Deep Sea ◽

Temperature Sensor ◽

Biochemical Parameter ◽

Underwater Vehicle ◽

Luciferase Assay ◽

Bioluminescence Intensity

Total ATP (adenosine triphosphate) concentration is a useful biochemical parameter for detecting microbial biomass or biogeochemical activity anomalies in the natural environment. In this study, we describe the development and evaluation of a new version of in situ ATP analyzer improved for the continuous and quantitative determination of ATP in submarine environments. We integrated a transparent microfluidic device containing a microchannel for cell lysis and a channel for the bioluminescence L–L (luciferin–luciferase) assay with a miniature pumping unit and a photometry module for the measurement of the bioluminescence intensity. A heater and a temperature sensor were also included in the system to maintain an optimal temperature for the L–L reaction. In this study, the analyzer was evaluated in deep sea environments, reaching a depth of 200 m using a remotely operated underwater vehicle. We show that the ATP analyzer successfully operated in the deep-sea environment and accurately quantified total ATP within the concentration lower than 5 × 10−11 M.

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