Darcy (unit)

Last updated September 06, 2022

The darcy (or darcy unit) and millidarcy (md or mD) are units of permeability, named after Henry Darcy. They are not SI units, but they are widely used in petroleum engineering and geology. The unit has also been used in biophysics and biomechanics, where the flow of fluids such as blood through capillary beds and cerebrospinal fluid through the brain interstitial space is being examined.^[1] A darcy has dimensional units of length ².

Definition

Permeability measures the ability of fluids to flow through rock (or other porous media). The darcy is defined using Darcy's law, which can be written as:

Q={\frac {Ak\,\Delta P}{\mu \,\Delta x}}

where:

$Q\,$	is the volumetric fluid flow rate through the medium
$A\,$	is the area of the medium
$k\,$	is the permeability of the medium
$\mu \,$	is the dynamic viscosity of the fluid
$\Delta P\,$	is the applied pressure difference
$\Delta x\,$	is the thickness of the medium

The darcy is referenced to a mixture of unit systems. A medium with a permeability of 1 darcy permits a flow of 1 cm³/s of a fluid with viscosity 1 cP (1 mPa·s) under a pressure gradient of 1 atm/cm acting across an area of 1 cm².

Typical values of permeability range as high as 100,000 darcys for gravel, to less than 0.01 microdarcy for granite. Sand has a permeability of approximately 1 darcy.^[2]

Tissue permeability, whose measurement in vivo is still in its infancy, is somewhere in the range of 0.01 to 100 darcy.^[1]

Origin

The darcy is named after Henry Darcy.^[1] Rock permeability is usually expressed in millidarcys (md) because rocks hosting hydrocarbon or water accumulations typically exhibit permeability ranging from 5 to 500 md.

The odd combination of units comes from Darcy's original studies of water flow through columns of sand. Water has a viscosity of 1.0019 cP at about room temperature.

The unit abbreviation "d" is not capitalized (contrary to industry use).^{[ clarification needed ]} The American Association of Petroleum Geologists^[3] uses the following unit abbreviations and grammar in their publications:

darcy (plural darcys, not darcies): d
millidarcy (plural millidarcys, not millidarcies): md

Conversions

Converted to SI units, 1 darcy is equivalent to 9.869233×10⁻¹³ m² or 0.9869233 µm².^[4] This conversion is usually approximated as 1 µm². This is the reciprocal of 1.013250—the conversion factor from atmospheres to bars.^[1]

Specifically in the hydrology domain, permeability of soil or rock may also be defined as the flux of water under hydrostatic pressure (~ 0.1 bar/m) at a temperature of 20 °C. In this specific setup, 1 darcy is equivalent to 0.831 m/day. ^[5]

Related Research Articles

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In fluid dynamics, the Darcy–Weisbach equation is an empirical equation that relates the head loss, or pressure loss, due to friction along a given length of pipe to the average velocity of the fluid flow for an incompressible fluid. The equation is named after Henry Darcy and Julius Weisbach. Currently, there is no formula more accurate or universally applicable than the Darcy-Weisbach supplemented by the Moody diagram or Colebrook equation.

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Darcy's law is an equation that describes the flow of a fluid through a porous medium. The law was formulated by Henry Darcy based on results of experiments on the flow of water through beds of sand, forming the basis of hydrogeology, a branch of earth sciences. It is analogous to Ohm's law in electrostatics, linearly relating the volume flow rate of the fluid to the hydraulic head difference via the hydraulic conductivity.

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Hydraulic conductivity, symbolically represented as $K$ , is a property of porous materials, soils and rocks, that describes the ease with which a fluid can move through the pore space, or fractures network. It depends on the intrinsic permeability of the material, the degree of saturation, and on the density and viscosity of the fluid. Saturated hydraulic conductivity, $K sat$ , describes water movement through saturated media. By definition, hydraulic conductivity is the ratio of volume flux to hydraulic gradient yielding a quantitative measure of a saturated soil's ability to transmit water when subjected to a hydraulic gradient.

In physics and engineering, permeation is the penetration of a permeate through a solid. It is directly related to the concentration gradient of the permeate, a material's intrinsic permeability, and the materials' mass diffusivity. Permeation is modeled by equations such as Fick's laws of diffusion, and can be measured using tools such as a minipermeameter.

In fluid mechanics, multiphase flow is the simultaneous flow of materials with two or more thermodynamic phases. Virtually all processing technologies from cavitating pumps and turbines to paper-making and the construction of plastics involve some form of multiphase flow. It is also prevalent in many natural phenomena.

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In petroleum engineering, a Klinkenberg correction is a procedure for calibration of permeability data obtained from a minipermeameter device. A more accurate correction factor can be obtained using Knudsen correction. When using nitrogen gas for core plug measurements, the Klinkenberg correction is usually necessary due to the so-called Klinkenberg gas slippage effect. This takes place when the pore space approaches the mean free path of the gas

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Morris Muskat was an American petroleum engineer. Muskat refined Darcy's equation for single phase flow, and this change made it suitable for the petroleum industry. Based on experimental results worked out by his colleagues, Muskat and Milan W. Meres also generalized Darcy's law to cover multiphase flow of water, oil and gas in the porous medium of a petroleum reservoir. The generalized flow equation provides the analytical foundation for reservoir engineering that exists to this day.

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References

1 2 3 4 Sowinski, Damian (January 2021). "Poroelasticity as a Model of Soft Tissue Structure: Hydraulic Permeability Reconstruction for Magnetic Resonance Elastography in Silico". Frontiers in Physics. 8: 637. arXiv: 2012.03993 . Bibcode:2021FrP.....8..637S. doi: 10.3389/fphy.2020.617582 .
↑ Peter C. Lichtner, Carl I. Steefel, Eric H. Oelkers, Reactive Transport in Porous Media , Mineralogical Society of America, 1996, ISBN 0-939950-42-1, p. 5.
↑ "The American Association of Petroleum Geologist Style Guides" (PDF). Archived from the original (PDF) on 2011-08-09.
↑ The SI Metric System of Units and SPE Metric Standard (PDF) (2nd ed.). Society of Petroleum Engineers. June 1984 [First published 1982].
↑ K. N. Duggal, J. P. Soni: Elements of Water Resources Engineering. Publisher New Age International, 1996, p. 270

Richard Selley's "Elements of Petroleum Geology (2nd edition)," page 250.

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[drs-1] 1 2 3 4 Sowinski, Damian (January 2021). "Poroelasticity as a Model of Soft Tissue Structure: Hydraulic Permeability Reconstruction for Magnetic Resonance Elastography in Silico". Frontiers in Physics. 8: 637. arXiv: 2012.03993 . Bibcode:2021FrP.....8..637S. doi: 10.3389/fphy.2020.617582 .

[2] Peter C. Lichtner, Carl I. Steefel, Eric H. Oelkers, Reactive Transport in Porous Media , Mineralogical Society of America, 1996, ISBN 0-939950-42-1, p. 5.

[3] "The American Association of Petroleum Geologist Style Guides" (PDF). Archived from the original (PDF) on 2011-08-09.

[spe-4] The SI Metric System of Units and SPE Metric Standard (PDF) (2nd ed.). Society of Petroleum Engineers. June 1984 [First published 1982].

[5] K. N. Duggal, J. P. Soni: Elements of Water Resources Engineering. Publisher New Age International, 1996, p. 270

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