Difference between revisions of "Absorption coefficient"
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+ | <font color="orange">معامل الامتصاص</font> (''Ar''). <font color="blue">Coefficient d'abosrption</font> (''Fr''). <font color="red">Absorptionskoeffizient</font> (''Ge''). <font color="black">Coefficiente di assorbiment</font> (''It''). <font color="purple">吸収係数</font> (''Ja''). <font color="brown">Коэффициент поглощения</font> (''Ru''). <font color="green">Coeficiente de absorción</font> (''Sp''). | ||
+ | |||
== Definition == | == Definition == | ||
− | The X-ray mass absorption coefficient, <math>\Big[{\mu\over\rho}\Big](E)</math> or <math>\Big[{\mu\over\rho}\Big]_{ | + | The X-ray mass absorption coefficient, <math>\Big[{\mu\over\rho}\Big](E)</math> or <math>\Big[{\mu\over\rho}\Big]_{PE}(E)</math> follows the Beer-Lambert law for a parallel beam of photons of energy <math>E</math> in which the transmitted photon intensity <math>I(t)</math> is related to the incoming photon intensity <math>I_0</math> such that |
− | <math>I(t) = I_0 | + | <math>I(t) = I_0 \exp({-\Big[{\mu\over\rho}\Big]\rho t})</math> |
− | where<math>t</math> is the thickness of a uniform sample and the density <math>\rho</math> is usually given in (g/cm<sup>3</sup>). The mass absorption coefficient is labeled as such because the absorption exponent is linear in the mass per unit area <math>\rho t</math>, otherwise known as the integrated column density through a sample. Use of <math>\mu</math> for this term is not recommended because it is highly ambiguous and dimensionally inconsistent. The subscript '' | + | where <math>t</math> is the thickness of a uniform sample and the density <math>\rho</math> is usually given in (g/cm<sup>3</sup>). The mass absorption coefficient is labeled as such because the absorption exponent is linear in the mass per unit area <math>\rho t</math>, otherwise known as the integrated column density through a sample. Use of <math>\mu</math> for this term is not recommended because it is highly ambiguous and dimensionally inconsistent. The subscript ''PE'' emphasizes that this is the photo-electric mass absorption coefficient rather than the [[mass attenuation coefficient]], which of course does not obey the Beer-Lambert law. Note also that it is rare for SI units to be used in texts on absorption spectroscopy. |
− | The X-ray linear absorption coefficient, <math>\mu(E)</math> or <math>\mu_{ | + | The X-ray linear absorption coefficient, <math>\mu(E)</math> or <math>\mu_{PE}(E)</math> follows <math>I(t) = I_0 \exp({-\mu t})</math>, with units of length<sup>−1</sup> (conventionally cm<sup>−1</sup>). <math>\mu</math> is the product of density <math>\rho</math> (g/cm<sup>3</sup>) and the mass absorption coefficient <math>\Big[{\mu\over\rho}\Big]</math> (cm<sup>2</sup>/g). |
− | It is sometimes convenient to describe the decrease in the beam intensity in terms of the absorption length: the thickness of the material in question at which the beam intensity has fallen to <math>(1/e)</math> of the incident beam intensity | + | It is sometimes convenient to describe the decrease in the beam intensity in terms of the absorption length: the thickness of the material in question at which the beam intensity has fallen to <math>(1/e)</math> of the incident beam intensity; that is, when <math>\mu t=1</math>, or when 63% of the flux is absorbed. In soft X-ray spectroscopy one absorption length can be some tens of nm while typical values in hard X-ray spectroscopy are microns or millimetres. |
<math>\mu</math> depends on energy, <math>E</math>, of the incoming photon and the elemental composition of the sample. The XAFS technique measures the variations in <math>\mu(E)</math>. | <math>\mu</math> depends on energy, <math>E</math>, of the incoming photon and the elemental composition of the sample. The XAFS technique measures the variations in <math>\mu(E)</math>. | ||
== Historical Note == | == Historical Note == | ||
− | Early references are P. Bouguer | + | Early references are P. Bouguer (1729). ''Essai d’Optique sur la Graduation de la Lumière'' (Paris, Jombert); J. H. Lambert (1760). ''Photometria sive Mensura et Gradibus Luminus, Colorum et Umbrae'' (Augsburg); A. Beer (1852). ''Annalen der Physik''. '''86''' (1852) pp. 78-87. ''Bestimmung der Absorption des rothen Lichts in farbigen Flüssigkeiten''. |
− | Note that all these preceded the discovery of X-rays, and were based on visible optics. From ''A History of Light and Colour Measurement'' [S. F. | + | Note that all these preceded the discovery of X-rays, and were based on visible optics. From ''A History of Light and Colour Measurement'' [Johnston, S. F. (2001), CRC Press] p18: 'The logarithm of the quantity of light received is inversely [meaning multiplied by <math>-1</math>] proportional to the thickness (Bouguer’s Law) and to the chemical composition (Beer’s Law) of an absorbing material, and the quantity of light to the cosine of the angle of incidence of the illuminated sample (Lambert’s Law)'. |
== See also == | == See also == | ||
− | *[[ | + | *[[Linear attenuation coefficient]] |
− | *[[ | + | *[[Mass attenuation coefficient]] |
[[Category: X-ray absorption spectroscopy]] | [[Category: X-ray absorption spectroscopy]] |
Latest revision as of 17:35, 8 November 2017
معامل الامتصاص (Ar). Coefficient d'abosrption (Fr). Absorptionskoeffizient (Ge). Coefficiente di assorbiment (It). 吸収係数 (Ja). Коэффициент поглощения (Ru). Coeficiente de absorción (Sp).
Definition
The X-ray mass absorption coefficient, [math]\Big[{\mu\over\rho}\Big](E)[/math] or [math]\Big[{\mu\over\rho}\Big]_{PE}(E)[/math] follows the Beer-Lambert law for a parallel beam of photons of energy [math]E[/math] in which the transmitted photon intensity [math]I(t)[/math] is related to the incoming photon intensity [math]I_0[/math] such that
[math]I(t) = I_0 \exp({-\Big[{\mu\over\rho}\Big]\rho t})[/math]
where [math]t[/math] is the thickness of a uniform sample and the density [math]\rho[/math] is usually given in (g/cm3). The mass absorption coefficient is labeled as such because the absorption exponent is linear in the mass per unit area [math]\rho t[/math], otherwise known as the integrated column density through a sample. Use of [math]\mu[/math] for this term is not recommended because it is highly ambiguous and dimensionally inconsistent. The subscript PE emphasizes that this is the photo-electric mass absorption coefficient rather than the mass attenuation coefficient, which of course does not obey the Beer-Lambert law. Note also that it is rare for SI units to be used in texts on absorption spectroscopy.
The X-ray linear absorption coefficient, [math]\mu(E)[/math] or [math]\mu_{PE}(E)[/math] follows [math]I(t) = I_0 \exp({-\mu t})[/math], with units of length−1 (conventionally cm−1). [math]\mu[/math] is the product of density [math]\rho[/math] (g/cm3) and the mass absorption coefficient [math]\Big[{\mu\over\rho}\Big][/math] (cm2/g).
It is sometimes convenient to describe the decrease in the beam intensity in terms of the absorption length: the thickness of the material in question at which the beam intensity has fallen to [math](1/e)[/math] of the incident beam intensity; that is, when [math]\mu t=1[/math], or when 63% of the flux is absorbed. In soft X-ray spectroscopy one absorption length can be some tens of nm while typical values in hard X-ray spectroscopy are microns or millimetres.
[math]\mu[/math] depends on energy, [math]E[/math], of the incoming photon and the elemental composition of the sample. The XAFS technique measures the variations in [math]\mu(E)[/math].
Historical Note
Early references are P. Bouguer (1729). Essai d’Optique sur la Graduation de la Lumière (Paris, Jombert); J. H. Lambert (1760). Photometria sive Mensura et Gradibus Luminus, Colorum et Umbrae (Augsburg); A. Beer (1852). Annalen der Physik. 86 (1852) pp. 78-87. Bestimmung der Absorption des rothen Lichts in farbigen Flüssigkeiten.
Note that all these preceded the discovery of X-rays, and were based on visible optics. From A History of Light and Colour Measurement [Johnston, S. F. (2001), CRC Press] p18: 'The logarithm of the quantity of light received is inversely [meaning multiplied by [math]-1[/math]] proportional to the thickness (Bouguer’s Law) and to the chemical composition (Beer’s Law) of an absorbing material, and the quantity of light to the cosine of the angle of incidence of the illuminated sample (Lambert’s Law)'.