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Surface Tension of Fluid01:22

Surface Tension of Fluid

Surface tension is a fundamental property of fluids, occurring at the boundary between a liquid and a gas or between two immiscible liquids. This phenomenon arises from the cohesive forces between molecules at the fluid's surface, creating an effect similar to a stretched elastic membrane. Inside each fluid, molecules are equally attracted in all directions by neighboring molecules, but surface molecules experience a net inward force, resulting in surface tension.
Surface tension varies with...
Eulerian and Lagrangian Flow Descriptions01:22

Eulerian and Lagrangian Flow Descriptions

Fluid flow analysis is critical in many scientific and engineering disciplines, and two principal approaches are used to describe this flow: the Eulerian and Lagrangian methods. These methods offer different perspectives on monitoring and analyzing the motion of fluids, each with distinct advantages depending on the scenario.
The Eulerian method focuses on fixed points in space where fluid properties, such as velocity, pressure, and temperature, are observed as the fluid moves between these...
Control Volume and System Representations01:16

Control Volume and System Representations

Two key frameworks are employed to analyze mass, energy, and momentum transfer: the control volume approach and the system approach. These frameworks offer different perspectives, depending on whether the focus is on a specific region in space (control volume approach) or a defined mass of fluid (system approach).
The control volume approach considers a stationary region in space through which fluid flows. This region is bounded by a control surface.  For instance, in the case of water flowing...
Modeling and Similitude01:12

Modeling and Similitude

Scaled modeling is a fundamental technique in engineering, enabling the study of large and complex systems by creating smaller, manageable replicas that recreate critical characteristics of the original. In hydrology and civil infrastructure, for example, scaled models of dams help analyze water flow, turbulence, and pressure. This method allows for accurate predictions of real-world behavior within a controlled environment, significantly reducing the cost and time involved in full-scale...
Laminar Flow: Problem Solving01:24

Laminar Flow: Problem Solving

Laminar flow occurs when a fluid moves smoothly in parallel layers with minimal mixing and turbulence. In fluid mechanics, ensuring laminar flow within a pipe is essential for precise control of flow characteristics, especially in engineering applications. The key factor in determining whether flow remains laminar is the Reynolds number, a dimensionless quantity that depends on the fluid's velocity, density, viscosity, and the pipe's diameter. A Reynolds number of 2100 or lower indicates...
Turbulent Flow: Problem Solving01:09

Turbulent Flow: Problem Solving

Carbonation is a process used to dissolve carbon dioxide gas in a liquid, commonly used in the production of carbonated beverages. Achieving efficient carbonation requires careful control of temperature, pressure, and flow conditions. By adjusting these parameters, carbonation efficiency can be maximized, producing a higher concentration of CO2 in the liquid.
Temperature is a key factor in CO2 solubility. In this case, the CO2 gas and the liquid are cooled to 20°C. Lower temperatures enhance...

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Related Experiment Video

Updated: Jul 7, 2026

A Microfluidic Chip for ICPMS Sample Introduction
11:16

A Microfluidic Chip for ICPMS Sample Introduction

Published on: March 5, 2015

11.3K

Microfluidics for geosciences: metrological developments and future challenges.

Sophie Roman1, Flore Rembert1,2, Anthony R Kovscek3

  • 1Univ. Orléans, CNRS, BRGM, ISTO, UMR 7327, F-45071 Orléans, France. sophie.roman@univ-orleans.fr.

Lab on a Chip
|August 4, 2025
PubMed
Summary
This summary is machine-generated.

This review highlights advancements in microfluidics metrology for geosciences over the last decade. These techniques enable detailed study of subsurface processes like groundwater flow and energy extraction.

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Last Updated: Jul 7, 2026

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Area of Science:

  • Geosciences
  • Microfluidics
  • Metrology

Background:

  • Microfluidics in geosciences models complex geological processes.
  • Applications include groundwater management, soil remediation, and geothermal energy.
  • Controlled microfluidic environments allow observation and characterization of subsurface phenomena.

Purpose of the Study:

  • To review metrological developments in microfluidics for geosciences over the past decade.
  • To present the state-of-the-art in measurement techniques for microfluidic experiments.
  • To discuss challenges and future directions, including AI integration.

Main Methods:

  • Advanced metrology techniques coupled with microfluidic experiments.
  • Direct visualization and measurement of transport, reactions, and interfacial processes.
  • Combining experimental and computational microfluidics.

Main Results:

  • Detailed measurement of velocity fields, fluid/solute saturations, and chemical reactions.
  • Enhanced understanding of coupled, multiphase, and reactive processes in porous media.
  • Discussion on upscaling findings from microfluidic to reservoir scales.

Conclusions:

  • Metrology advancements have significantly improved microfluidic studies in geosciences.
  • Future work should focus on further metrological innovation and AI integration.
  • Microfluidics-based metrology is crucial for understanding and managing geological resources.