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| {{More footnotes|date=January 2009}}
| | == looking at this scene. == |
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| [[Image:Love wave.jpg|thumb|right|300px|How love waves work]]
| | , Sleeping in the mouth have a smile that seems to dream of a very happy thing, but in this hall in addition to Luo Feng outside ...... there is a universe in the presence of two very scary super,[http://www.alleganycountyfair.org/_vti_cnf/rakuten_oakley_33.htm オークリー サングラス 調整], looking at this scene.<br><br>slowly opened his eyes suddenly Feng Luo,[http://www.alleganycountyfair.org/_vti_cnf/rakuten_oakley_18.htm オークリー スポーツサングラス].<br><br>sleep sleep dreaming,[http://www.alleganycountyfair.org/_vti_cnf/rakuten_oakley_21.htm 登山 サングラス オークリー], apparently soul has been completely restored,[http://www.alleganycountyfair.org/_vti_cnf/rakuten_oakley_47.htm オークリーレーダーサングラス], Luo Feng in the finish that dream,[http://www.alleganycountyfair.org/_vti_cnf/rakuten_oakley_73.htm オークリー サングラス 店舗], but also opened his eyes.<br><br>'child ......' a warm heart sounds,[http://www.alleganycountyfair.org/_vti_cnf/rakuten_oakley_61.htm オークリー 自転車 サングラス], as if the black metal plate that sound the same,[http://www.alleganycountyfair.org/_vti_cnf/rakuten_oakley_13.htm オークリー サングラス 野球], so that even Luofeng Li stood up, turned around and looked.<br><br>front has two figure.<br><br>a familiar Lord of the Universe 'Pu Ti',[http://www.alleganycountyfair.org/_vti_cnf/rakuten_oakley_73.htm オークリー サングラス 人気], then Pu Ti convergence coercion but very understated entrenched on one side, and in the forefront of the entire central hall is standing a towering giant of up to more than 900 meters figure, he was wearing blue A seemingly ordinary armor, forehead with a transparent double angle, looking down overlooking the Feng Luo.<br><br>endless atmosphere enveloped the whole |
| In [[elastodynamics]], '''Love waves''', named after [[Augustus Edward Hough Love|A. E. H. Love]], are horizontally [[Polarization (waves)|polarized]] [[surface wave]]. In fact the Love wave is a result of the interferation of many [[shear wave]]s (SH waves) guided by an elastic layer, which is "welded" to an elastic half space on one side while bordering a vacuum on the other side. In [[seismology]], '''Love waves''' (also known as '''Q waves''' ('''Q'''uer: German for lateral)) are [[surface waves|surface]] [[seismic wave]]s that cause horizontal shifting of the Earth during an [[earthquake]]. [[Augustus Edward Hough Love|A. E. H. Love]] predicted the existence of Love waves mathematically in 1911; the name comes from him (Chapter 11 from Love's book "Some problems of geodynamics", first published in 1911). They form a distinct class, different from other types of [[seismic wave]]s, such as [[P-wave]]s and [[S-wave]]s (both [[Body wave (seismology)|body wave]]s), or [[Rayleigh waves]] (another type of surface wave). Love waves travel with a slower velocity than P- or S- waves, but faster than Rayleigh waves. These waves are observed only when there is a low velocity layer overlying a high velocity layer/ sub layers.
| | 相关的主题文章: |
| | | <ul> |
| ==Description==
| | |
| The particle motion of a Love wave forms a horizontal line perpendicular to the direction of [[wave propagation|propagation]] (i.e. are [[transverse waves]]). Moving deeper into the material, motion can decrease to a "node" and then alternately increase and decrease as one examines deeper layers of particles. The [[amplitude]], or maximum particle motion, often decreases rapidly with depth.
| | <li>[http://www.autowj.com/bbs/home.php?mod=space&uid=174159 http://www.autowj.com/bbs/home.php?mod=space&uid=174159]</li> |
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| Since Love waves travel on the Earth's surface, the strength (or [[amplitude]]) of the waves decrease exponentially with the depth of an earthquake. However, given their confinement to the surface, their amplitude decays only as <math>\frac{1}{\sqrt{r}}</math>, where <math>r</math> represents the distance the wave has travelled from the earthquake. Surface waves therefore decay more slowly with distance than do body waves, which travel in three dimensions. Large earthquakes may generate Love waves that travel around the Earth several times before dissipating.
| | <li>[http://www.yifangvisa.com/plus/feedback.php?aid=616 http://www.yifangvisa.com/plus/feedback.php?aid=616]</li> |
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| Since they decay so slowly, Love waves are the most destructive outside the immediate area of the focus or [[epicentre]] of an earthquake. They are what most people feel directly during an earthquake.
| | <li>[http://www.bjhforum.co.uk/woolly/guestbook.cgi http://www.bjhforum.co.uk/woolly/guestbook.cgi]</li> |
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| In the past, it was often thought that animals like cats and dogs could predict an earthquake before it happened. However, they are simply more sensitive to [[ground vibrations]] than humans and able to detect the subtler body waves that precede Love waves, like the P-waves and the S-waves.<ref>{{cite web|url=http://www.geo.mtu.edu/UPSeis/waves.html|title=What Is Seismology?|year=2007|publisher=Michigan Technological University|accessdate=2009-07-28}}</ref>
| | </ul> |
| | |
| == Basic theory ==
| |
| The conservation of [[linear momentum]] of a [[linear elasticity|linear elastic]] material can be written as <ref>The body force is assumed to be zero and direct tensor notation has been used. For other ways of writing these governing equations see [[linear elasticity]].</ref>
| |
| :<math>\boldsymbol{\nabla}\cdot(\mathsf{C}:\boldsymbol{\nabla}\mathbf{u}) = \rho~\ddot{\mathbf{u}} </math>
| |
| where <math>\mathbf{u}</math> is the [[Displacement (vector)|displacement vector]] and <math>\mathsf{C}</math> is the [[stiffness tensor]]. Love waves are a special solution (<math>\mathbf{u}</math>) that satisfy this system of equations. We typically use a Cartesian coordinate system (<math>x,y,z</math>) to describe Love waves.
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| Consider an isotropic linear elastic medium in which the elastic properties are functions of only the <math>z</math> coordinate, i.e., the [[Lamé parameters]] and the mass [[density]] can be expressed as <math>\lambda(z), \mu(z), \rho(z)</math>. Displacements <math>(u,v,w)</math> produced by Love waves as a function of time (<math>t</math>) have the form
| |
| :<math>
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| u(x,y,z,t) = 0 ~,~~ v(x,y,z,t) = \hat{v}(x,z,t) ~,~~ w(x,y,z,t) = 0 \,. | |
| </math>
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| These are therefore [[antiplane shear]] waves perpendicular to the <math>(x,z)</math> plane. The function <math>\hat{v}(x,z,t)</math> can be expressed as the superposition of [[harmonic wave]]s with varying [[wave number]]s (<math>k</math>) and [[frequency|frequencies]] (<math>\omega</math>). Let us consider a single harmonic wave, i.e.,
| |
| :<math>
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| \hat{v}(x,z,t) = V(k, z, \omega)\,\exp[i(k x - \omega t)]
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| </math>
| |
| where <math>i = \sqrt{-1}</math>. The [[stress (physics)|stresses]] caused by these displacements are
| |
| :<math>
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| \sigma_{xx} = 0 ~,~~ \sigma_{yy} = 0 ~,~~ \sigma_{zz} = 0 ~, ~~ \tau_{zx} = 0
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| ~,~~ \tau_{yz} = \mu(z)\,\frac{dV}{dz}\,\exp[i(k x - \omega t)]
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| ~,~~ \tau_{xy} = i k \mu(z) V(k, z, \omega) \,\exp[i(k x - \omega t)] \,.
| |
| </math>
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| If we substitute the assume displacements into the equations for the conservation of momentum, we get a simplified equation
| |
| :<math>
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| \frac{d}{dz}\left[\mu(z)\,\frac{dV}{dz}\right] = [k^2\,\mu(z) - \omega^2\,\rho(z)]\,V(k,z,\omega) \,.
| |
| </math>
| |
| The boundary conditions for a Love wave are that the [[surface traction]]s at the free surface <math>(z = 0)</math> must be zero. Another requirement is that the stress component <math>\tau_{yz}</math> in a layer medium must be continuous at the interfaces of the layers. To convert the second order [[differential equation]] in <math>V</math> into two first order equations, we express this stress component in the form
| |
| :<math>
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| \tau_{yz} = T(k, z, \omega)\,\exp[i(k x - \omega t)] | |
| </math>
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| to get the first order conservation of momentum equations
| |
| :<math> | |
| \frac{d}{dz}\begin{bmatrix} V \\ T \end{bmatrix} =
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| \begin{bmatrix} 0 & 1/\mu(z) \\ k^2\,\mu(z) - \omega^2\,\rho(z) & 0 \end{bmatrix}
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| \begin{bmatrix} V \\ T \end{bmatrix} \,.
| |
| </math>
| |
| The above equations describe an [[eigenvalue]] problem whose solution [[eigenfunctions]] can be found by a number of [[numerical methods]]. Another common, and powerful, approach is the [[propagator|propagator matrix]] method (also called the [[matricant]] approach).
| |
| | |
| ==See also==
| |
| * [[Longitudinal wave]]
| |
| * [[P-wave]]
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| * [[S-wave]]
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| * [[Rayleigh wave]]
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| * [[Antiplane shear]]
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| | |
| ==References==
| |
| | |
| * A. E. H. Love, "Some problems of geodynamics", first published in 1911 by the Cambridge University Press and published again in 1967 by Dover, New York, USA. (Chapter 11: Theory of the propagation of seismic waves)
| |
| | |
| <references/> | |
| | |
| [[Category:Geophysics]]
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| [[Category:Waves]]
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| [[Category:Seismology and earthquake terminology]]
| |
looking at this scene.
, Sleeping in the mouth have a smile that seems to dream of a very happy thing, but in this hall in addition to Luo Feng outside ...... there is a universe in the presence of two very scary super,オークリー サングラス 調整, looking at this scene.
slowly opened his eyes suddenly Feng Luo,オークリー スポーツサングラス.
sleep sleep dreaming,登山 サングラス オークリー, apparently soul has been completely restored,オークリーレーダーサングラス, Luo Feng in the finish that dream,オークリー サングラス 店舗, but also opened his eyes.
'child ......' a warm heart sounds,オークリー 自転車 サングラス, as if the black metal plate that sound the same,オークリー サングラス 野球, so that even Luofeng Li stood up, turned around and looked.
front has two figure.
a familiar Lord of the Universe 'Pu Ti',オークリー サングラス 人気, then Pu Ti convergence coercion but very understated entrenched on one side, and in the forefront of the entire central hall is standing a towering giant of up to more than 900 meters figure, he was wearing blue A seemingly ordinary armor, forehead with a transparent double angle, looking down overlooking the Feng Luo.
endless atmosphere enveloped the whole
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