Is a Wick rotation a change of coordinates?Showing $I=int d^3kint dk^0frac1k^4$ to be logarithmically divergentHow to Perform Wick Rotation in the Lagrangian of a Gauge Theory (like QCD)?Is it okay to Wick rotate to give the negative of the Euclidean metric? Also, could we make the space-like coordinates imaginary instead?Curved space-time VS change of coordinates in Minkowski spaceHow does the Lorentz boost change if we introduce transformation to the minkowski metricPerforming Wick Rotation to get Euclidean action of a scalar field $Psi$Determinant of the metric tensorIntegral and Wick rotation (Srednicki ch75)How does the Equivalence Principle imply that derivatives of the metric vanish in a freely falling frame?Interpretation of Normal Coordinates

Why there is no wireless switch?

How could a planet have one hemisphere way warmer than the other without the planet being tidally locked?

Translate English to Pig Latin | PIG_LATIN.PY

What's this constructed number's starter?

Darwin alternative to `lsb_release -a`?

Are there mathematical concepts that exist in the fourth dimension, but not in the third dimension?

Where on Earth is it easiest to survive in the wilderness?

Undefined Hamiltonian for this particular Lagrangian

Do 643,000 Americans go bankrupt every year due to medical bills?

A magician's sleight of hand

How many people can lift Thor's hammer?

Would you recommend a keyboard for beginners with or without lights in keys for learning?

First Number to Contain Each Letter

Tying double knot of garbarge bag

My Friend James

Fantasy Military Arms and Armor: the Dwarven Grand Armory

To which airspace does the border of two adjacent airspaces belong to?

Who are these people in this satirical cartoon of the Congress of Verona?

What's the eccentricity of an orbit (trajectory) falling straight down towards the center?

Is a paralyzed creature limp or rigid?

Is it risky to move from broad geographical diversification into investing mostly in less developed markets?

Why are some hotels asking you to book through Booking.com instead of matching the price at the front desk?

Never make public members virtual/abstract - really?

Ceiling fan electrical box missing female screw holes



Is a Wick rotation a change of coordinates?


Showing $I=int d^3kint dk^0frac1k^4$ to be logarithmically divergentHow to Perform Wick Rotation in the Lagrangian of a Gauge Theory (like QCD)?Is it okay to Wick rotate to give the negative of the Euclidean metric? Also, could we make the space-like coordinates imaginary instead?Curved space-time VS change of coordinates in Minkowski spaceHow does the Lorentz boost change if we introduce transformation to the minkowski metricPerforming Wick Rotation to get Euclidean action of a scalar field $Psi$Determinant of the metric tensorIntegral and Wick rotation (Srednicki ch75)How does the Equivalence Principle imply that derivatives of the metric vanish in a freely falling frame?Interpretation of Normal Coordinates






.everyoneloves__top-leaderboard:empty,.everyoneloves__mid-leaderboard:empty,.everyoneloves__bot-mid-leaderboard:empty margin-bottom:0;








4












$begingroup$


My understanding is that a Wick rotation is a change of coordinates from $(t,x) rightarrow (tau , x)$ where $tau = i t$. In the $(t,x)$ coordinate system, the Minkowski metric has components $ eta_mu nu = mathrmdiag(1,-1,-1,-1)$. Using the formula for the transformation of the components under a coordinate change:



$$ eta_alpha beta = fracpartial x^mupartial x'^alphafracpartial x^nupartial x'^betaeta_mu nu $$



we find in the $(tau,x)$ coordinate system, the metric has components $eta_alpha beta = mathrmdiag(-1,-1,-1,-1)$.



In QFT for the gifted amateur by Lancaster and Blundell equation 25.4, it is stated that under a Wick rotation, the magnitude of a vector is given by



$$ x^2 = - x_E^2 $$



where $x$ is the Minkowski vector and $x_E$ is the corresponding Euclidean vector. Now I am confused by this statement, because the objects $x$ and $x_E$ are coordinate representations of a vector, say $X$, which is a geometric object independent of the coordinate system we choose, so we should expect



$$ |X|^2 = eta_mu nu x^mu x^nu = eta_alpha beta x^alpha_E x^beta_E$$



in other words, the magnitude of the vector $X$ should not depend on which coordinate system we use. So under a simple Wick rotation, how could the magnitude of a vector change?



I was thinking, maybe a Wick rotation is an active rotation into the complex plane but the book states that the metric tranforms too so we can use the Euclidean metric. If we transform both the vector and the metric then that suggests a change of coordinates, but if only the vector changes then it suggests some sort of active transformation.



My Question



Is a Wick rotation simply a change of coordinates or is it an active rotation of the vector into the complex plane?










share|cite|improve this question











$endgroup$













  • $begingroup$
    This is a horrible misunderstanding that "casual" textbooks propagate... a Wick rotation isn't a change of coordinates. Wick rotations have drastic consequences, while as you correctly point out, a change of coordinates barely does anything!
    $endgroup$
    – knzhou
    8 hours ago










  • $begingroup$
    Saying that a Wick rotation is a change of coordinates is the second most common and second worst misexplanation of it, the first being that "it's a substitution $t to it$". The vast majority of books cover this totally basic thing all wrong. It should be thought of in terms of rotating contours of integration.
    $endgroup$
    – knzhou
    8 hours ago






  • 1




    $begingroup$
    My answer here should be relevant
    $endgroup$
    – MannyC
    8 hours ago

















4












$begingroup$


My understanding is that a Wick rotation is a change of coordinates from $(t,x) rightarrow (tau , x)$ where $tau = i t$. In the $(t,x)$ coordinate system, the Minkowski metric has components $ eta_mu nu = mathrmdiag(1,-1,-1,-1)$. Using the formula for the transformation of the components under a coordinate change:



$$ eta_alpha beta = fracpartial x^mupartial x'^alphafracpartial x^nupartial x'^betaeta_mu nu $$



we find in the $(tau,x)$ coordinate system, the metric has components $eta_alpha beta = mathrmdiag(-1,-1,-1,-1)$.



In QFT for the gifted amateur by Lancaster and Blundell equation 25.4, it is stated that under a Wick rotation, the magnitude of a vector is given by



$$ x^2 = - x_E^2 $$



where $x$ is the Minkowski vector and $x_E$ is the corresponding Euclidean vector. Now I am confused by this statement, because the objects $x$ and $x_E$ are coordinate representations of a vector, say $X$, which is a geometric object independent of the coordinate system we choose, so we should expect



$$ |X|^2 = eta_mu nu x^mu x^nu = eta_alpha beta x^alpha_E x^beta_E$$



in other words, the magnitude of the vector $X$ should not depend on which coordinate system we use. So under a simple Wick rotation, how could the magnitude of a vector change?



I was thinking, maybe a Wick rotation is an active rotation into the complex plane but the book states that the metric tranforms too so we can use the Euclidean metric. If we transform both the vector and the metric then that suggests a change of coordinates, but if only the vector changes then it suggests some sort of active transformation.



My Question



Is a Wick rotation simply a change of coordinates or is it an active rotation of the vector into the complex plane?










share|cite|improve this question











$endgroup$













  • $begingroup$
    This is a horrible misunderstanding that "casual" textbooks propagate... a Wick rotation isn't a change of coordinates. Wick rotations have drastic consequences, while as you correctly point out, a change of coordinates barely does anything!
    $endgroup$
    – knzhou
    8 hours ago










  • $begingroup$
    Saying that a Wick rotation is a change of coordinates is the second most common and second worst misexplanation of it, the first being that "it's a substitution $t to it$". The vast majority of books cover this totally basic thing all wrong. It should be thought of in terms of rotating contours of integration.
    $endgroup$
    – knzhou
    8 hours ago






  • 1




    $begingroup$
    My answer here should be relevant
    $endgroup$
    – MannyC
    8 hours ago













4












4








4


3



$begingroup$


My understanding is that a Wick rotation is a change of coordinates from $(t,x) rightarrow (tau , x)$ where $tau = i t$. In the $(t,x)$ coordinate system, the Minkowski metric has components $ eta_mu nu = mathrmdiag(1,-1,-1,-1)$. Using the formula for the transformation of the components under a coordinate change:



$$ eta_alpha beta = fracpartial x^mupartial x'^alphafracpartial x^nupartial x'^betaeta_mu nu $$



we find in the $(tau,x)$ coordinate system, the metric has components $eta_alpha beta = mathrmdiag(-1,-1,-1,-1)$.



In QFT for the gifted amateur by Lancaster and Blundell equation 25.4, it is stated that under a Wick rotation, the magnitude of a vector is given by



$$ x^2 = - x_E^2 $$



where $x$ is the Minkowski vector and $x_E$ is the corresponding Euclidean vector. Now I am confused by this statement, because the objects $x$ and $x_E$ are coordinate representations of a vector, say $X$, which is a geometric object independent of the coordinate system we choose, so we should expect



$$ |X|^2 = eta_mu nu x^mu x^nu = eta_alpha beta x^alpha_E x^beta_E$$



in other words, the magnitude of the vector $X$ should not depend on which coordinate system we use. So under a simple Wick rotation, how could the magnitude of a vector change?



I was thinking, maybe a Wick rotation is an active rotation into the complex plane but the book states that the metric tranforms too so we can use the Euclidean metric. If we transform both the vector and the metric then that suggests a change of coordinates, but if only the vector changes then it suggests some sort of active transformation.



My Question



Is a Wick rotation simply a change of coordinates or is it an active rotation of the vector into the complex plane?










share|cite|improve this question











$endgroup$




My understanding is that a Wick rotation is a change of coordinates from $(t,x) rightarrow (tau , x)$ where $tau = i t$. In the $(t,x)$ coordinate system, the Minkowski metric has components $ eta_mu nu = mathrmdiag(1,-1,-1,-1)$. Using the formula for the transformation of the components under a coordinate change:



$$ eta_alpha beta = fracpartial x^mupartial x'^alphafracpartial x^nupartial x'^betaeta_mu nu $$



we find in the $(tau,x)$ coordinate system, the metric has components $eta_alpha beta = mathrmdiag(-1,-1,-1,-1)$.



In QFT for the gifted amateur by Lancaster and Blundell equation 25.4, it is stated that under a Wick rotation, the magnitude of a vector is given by



$$ x^2 = - x_E^2 $$



where $x$ is the Minkowski vector and $x_E$ is the corresponding Euclidean vector. Now I am confused by this statement, because the objects $x$ and $x_E$ are coordinate representations of a vector, say $X$, which is a geometric object independent of the coordinate system we choose, so we should expect



$$ |X|^2 = eta_mu nu x^mu x^nu = eta_alpha beta x^alpha_E x^beta_E$$



in other words, the magnitude of the vector $X$ should not depend on which coordinate system we use. So under a simple Wick rotation, how could the magnitude of a vector change?



I was thinking, maybe a Wick rotation is an active rotation into the complex plane but the book states that the metric tranforms too so we can use the Euclidean metric. If we transform both the vector and the metric then that suggests a change of coordinates, but if only the vector changes then it suggests some sort of active transformation.



My Question



Is a Wick rotation simply a change of coordinates or is it an active rotation of the vector into the complex plane?







special-relativity metric-tensor coordinate-systems complex-numbers wick-rotation






share|cite|improve this question















share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited 7 hours ago









Qmechanic

113k13 gold badges223 silver badges1341 bronze badges




113k13 gold badges223 silver badges1341 bronze badges










asked 8 hours ago









Matt0410Matt0410

9595 silver badges21 bronze badges




9595 silver badges21 bronze badges














  • $begingroup$
    This is a horrible misunderstanding that "casual" textbooks propagate... a Wick rotation isn't a change of coordinates. Wick rotations have drastic consequences, while as you correctly point out, a change of coordinates barely does anything!
    $endgroup$
    – knzhou
    8 hours ago










  • $begingroup$
    Saying that a Wick rotation is a change of coordinates is the second most common and second worst misexplanation of it, the first being that "it's a substitution $t to it$". The vast majority of books cover this totally basic thing all wrong. It should be thought of in terms of rotating contours of integration.
    $endgroup$
    – knzhou
    8 hours ago






  • 1




    $begingroup$
    My answer here should be relevant
    $endgroup$
    – MannyC
    8 hours ago
















  • $begingroup$
    This is a horrible misunderstanding that "casual" textbooks propagate... a Wick rotation isn't a change of coordinates. Wick rotations have drastic consequences, while as you correctly point out, a change of coordinates barely does anything!
    $endgroup$
    – knzhou
    8 hours ago










  • $begingroup$
    Saying that a Wick rotation is a change of coordinates is the second most common and second worst misexplanation of it, the first being that "it's a substitution $t to it$". The vast majority of books cover this totally basic thing all wrong. It should be thought of in terms of rotating contours of integration.
    $endgroup$
    – knzhou
    8 hours ago






  • 1




    $begingroup$
    My answer here should be relevant
    $endgroup$
    – MannyC
    8 hours ago















$begingroup$
This is a horrible misunderstanding that "casual" textbooks propagate... a Wick rotation isn't a change of coordinates. Wick rotations have drastic consequences, while as you correctly point out, a change of coordinates barely does anything!
$endgroup$
– knzhou
8 hours ago




$begingroup$
This is a horrible misunderstanding that "casual" textbooks propagate... a Wick rotation isn't a change of coordinates. Wick rotations have drastic consequences, while as you correctly point out, a change of coordinates barely does anything!
$endgroup$
– knzhou
8 hours ago












$begingroup$
Saying that a Wick rotation is a change of coordinates is the second most common and second worst misexplanation of it, the first being that "it's a substitution $t to it$". The vast majority of books cover this totally basic thing all wrong. It should be thought of in terms of rotating contours of integration.
$endgroup$
– knzhou
8 hours ago




$begingroup$
Saying that a Wick rotation is a change of coordinates is the second most common and second worst misexplanation of it, the first being that "it's a substitution $t to it$". The vast majority of books cover this totally basic thing all wrong. It should be thought of in terms of rotating contours of integration.
$endgroup$
– knzhou
8 hours ago




1




1




$begingroup$
My answer here should be relevant
$endgroup$
– MannyC
8 hours ago




$begingroup$
My answer here should be relevant
$endgroup$
– MannyC
8 hours ago










1 Answer
1






active

oldest

votes


















6














$begingroup$

[The following is a half-remembered comment that my doctoral advisor told me some years ago, so I may have garbled it. I welcome corrections in the comments; feel free to tell me I'm full of it as well.]



One way to think about a Wick rotation is that the "Euclidean" and "Lorentzian" manifolds (both of which are four-dimensional real manifolds, with a particular metric) can be viewed as hypersurfaces lying in an underlying four-dimensional complex manifold. For example, in the complex manifold $mathbbC^4$ with the obvious metric, you can find hypersurfaces with four (real) dimensions that are diffeomorphic to Euclidean four-space, and hypersurfaces with four (real) dimensions that are diffeomorphic to Minkowski space. The reason that Wick rotations are successful in flat spacetime is because the functions we're looking at are generally holomorphic, and so they can be analytically continued from one "cross-section" to another.



In this picture, a vector lying in a Euclidean cross-section of $mathbbC^4$ must be actively "rotated" into the Lorentzian cross-section. Simply changing the coordinates on your cross-section will not magically "pull in" a vector that doesn't already lie in that cross-section.



This picture, by the way, does not necessarily carry over to the analysis in curved spacetimes. We might think that if the Lorentzian metric is of the form
$$
ds^2 = - f(r,t) dt^2 + g^ij dx_i dx_j
$$

in some set of coordinates, then we can define a Euclidean analog
$$
ds_E^2 = f(r,t) dt^2 + g^ij dx_i dx_j
$$

and do the analysis there. However, there is no guarantee that there exists a complex manifold having these two cross-sections, and so we cannot rely on the Euclidean results to tell us anything about the Lorentzian physics.






share|cite|improve this answer











$endgroup$

















    Your Answer








    StackExchange.ready(function()
    var channelOptions =
    tags: "".split(" "),
    id: "151"
    ;
    initTagRenderer("".split(" "), "".split(" "), channelOptions);

    StackExchange.using("externalEditor", function()
    // Have to fire editor after snippets, if snippets enabled
    if (StackExchange.settings.snippets.snippetsEnabled)
    StackExchange.using("snippets", function()
    createEditor();
    );

    else
    createEditor();

    );

    function createEditor()
    StackExchange.prepareEditor(
    heartbeatType: 'answer',
    autoActivateHeartbeat: false,
    convertImagesToLinks: false,
    noModals: true,
    showLowRepImageUploadWarning: true,
    reputationToPostImages: null,
    bindNavPrevention: true,
    postfix: "",
    imageUploader:
    brandingHtml: "Powered by u003ca class="icon-imgur-white" href="https://imgur.com/"u003eu003c/au003e",
    contentPolicyHtml: "User contributions licensed under u003ca href="https://creativecommons.org/licenses/by-sa/3.0/"u003ecc by-sa 3.0 with attribution requiredu003c/au003e u003ca href="https://stackoverflow.com/legal/content-policy"u003e(content policy)u003c/au003e",
    allowUrls: true
    ,
    noCode: true, onDemand: true,
    discardSelector: ".discard-answer"
    ,immediatelyShowMarkdownHelp:true
    );



    );













    draft saved

    draft discarded


















    StackExchange.ready(
    function ()
    StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fphysics.stackexchange.com%2fquestions%2f500239%2fis-a-wick-rotation-a-change-of-coordinates%23new-answer', 'question_page');

    );

    Post as a guest















    Required, but never shown

























    1 Answer
    1






    active

    oldest

    votes








    1 Answer
    1






    active

    oldest

    votes









    active

    oldest

    votes






    active

    oldest

    votes









    6














    $begingroup$

    [The following is a half-remembered comment that my doctoral advisor told me some years ago, so I may have garbled it. I welcome corrections in the comments; feel free to tell me I'm full of it as well.]



    One way to think about a Wick rotation is that the "Euclidean" and "Lorentzian" manifolds (both of which are four-dimensional real manifolds, with a particular metric) can be viewed as hypersurfaces lying in an underlying four-dimensional complex manifold. For example, in the complex manifold $mathbbC^4$ with the obvious metric, you can find hypersurfaces with four (real) dimensions that are diffeomorphic to Euclidean four-space, and hypersurfaces with four (real) dimensions that are diffeomorphic to Minkowski space. The reason that Wick rotations are successful in flat spacetime is because the functions we're looking at are generally holomorphic, and so they can be analytically continued from one "cross-section" to another.



    In this picture, a vector lying in a Euclidean cross-section of $mathbbC^4$ must be actively "rotated" into the Lorentzian cross-section. Simply changing the coordinates on your cross-section will not magically "pull in" a vector that doesn't already lie in that cross-section.



    This picture, by the way, does not necessarily carry over to the analysis in curved spacetimes. We might think that if the Lorentzian metric is of the form
    $$
    ds^2 = - f(r,t) dt^2 + g^ij dx_i dx_j
    $$

    in some set of coordinates, then we can define a Euclidean analog
    $$
    ds_E^2 = f(r,t) dt^2 + g^ij dx_i dx_j
    $$

    and do the analysis there. However, there is no guarantee that there exists a complex manifold having these two cross-sections, and so we cannot rely on the Euclidean results to tell us anything about the Lorentzian physics.






    share|cite|improve this answer











    $endgroup$



















      6














      $begingroup$

      [The following is a half-remembered comment that my doctoral advisor told me some years ago, so I may have garbled it. I welcome corrections in the comments; feel free to tell me I'm full of it as well.]



      One way to think about a Wick rotation is that the "Euclidean" and "Lorentzian" manifolds (both of which are four-dimensional real manifolds, with a particular metric) can be viewed as hypersurfaces lying in an underlying four-dimensional complex manifold. For example, in the complex manifold $mathbbC^4$ with the obvious metric, you can find hypersurfaces with four (real) dimensions that are diffeomorphic to Euclidean four-space, and hypersurfaces with four (real) dimensions that are diffeomorphic to Minkowski space. The reason that Wick rotations are successful in flat spacetime is because the functions we're looking at are generally holomorphic, and so they can be analytically continued from one "cross-section" to another.



      In this picture, a vector lying in a Euclidean cross-section of $mathbbC^4$ must be actively "rotated" into the Lorentzian cross-section. Simply changing the coordinates on your cross-section will not magically "pull in" a vector that doesn't already lie in that cross-section.



      This picture, by the way, does not necessarily carry over to the analysis in curved spacetimes. We might think that if the Lorentzian metric is of the form
      $$
      ds^2 = - f(r,t) dt^2 + g^ij dx_i dx_j
      $$

      in some set of coordinates, then we can define a Euclidean analog
      $$
      ds_E^2 = f(r,t) dt^2 + g^ij dx_i dx_j
      $$

      and do the analysis there. However, there is no guarantee that there exists a complex manifold having these two cross-sections, and so we cannot rely on the Euclidean results to tell us anything about the Lorentzian physics.






      share|cite|improve this answer











      $endgroup$

















        6














        6










        6







        $begingroup$

        [The following is a half-remembered comment that my doctoral advisor told me some years ago, so I may have garbled it. I welcome corrections in the comments; feel free to tell me I'm full of it as well.]



        One way to think about a Wick rotation is that the "Euclidean" and "Lorentzian" manifolds (both of which are four-dimensional real manifolds, with a particular metric) can be viewed as hypersurfaces lying in an underlying four-dimensional complex manifold. For example, in the complex manifold $mathbbC^4$ with the obvious metric, you can find hypersurfaces with four (real) dimensions that are diffeomorphic to Euclidean four-space, and hypersurfaces with four (real) dimensions that are diffeomorphic to Minkowski space. The reason that Wick rotations are successful in flat spacetime is because the functions we're looking at are generally holomorphic, and so they can be analytically continued from one "cross-section" to another.



        In this picture, a vector lying in a Euclidean cross-section of $mathbbC^4$ must be actively "rotated" into the Lorentzian cross-section. Simply changing the coordinates on your cross-section will not magically "pull in" a vector that doesn't already lie in that cross-section.



        This picture, by the way, does not necessarily carry over to the analysis in curved spacetimes. We might think that if the Lorentzian metric is of the form
        $$
        ds^2 = - f(r,t) dt^2 + g^ij dx_i dx_j
        $$

        in some set of coordinates, then we can define a Euclidean analog
        $$
        ds_E^2 = f(r,t) dt^2 + g^ij dx_i dx_j
        $$

        and do the analysis there. However, there is no guarantee that there exists a complex manifold having these two cross-sections, and so we cannot rely on the Euclidean results to tell us anything about the Lorentzian physics.






        share|cite|improve this answer











        $endgroup$



        [The following is a half-remembered comment that my doctoral advisor told me some years ago, so I may have garbled it. I welcome corrections in the comments; feel free to tell me I'm full of it as well.]



        One way to think about a Wick rotation is that the "Euclidean" and "Lorentzian" manifolds (both of which are four-dimensional real manifolds, with a particular metric) can be viewed as hypersurfaces lying in an underlying four-dimensional complex manifold. For example, in the complex manifold $mathbbC^4$ with the obvious metric, you can find hypersurfaces with four (real) dimensions that are diffeomorphic to Euclidean four-space, and hypersurfaces with four (real) dimensions that are diffeomorphic to Minkowski space. The reason that Wick rotations are successful in flat spacetime is because the functions we're looking at are generally holomorphic, and so they can be analytically continued from one "cross-section" to another.



        In this picture, a vector lying in a Euclidean cross-section of $mathbbC^4$ must be actively "rotated" into the Lorentzian cross-section. Simply changing the coordinates on your cross-section will not magically "pull in" a vector that doesn't already lie in that cross-section.



        This picture, by the way, does not necessarily carry over to the analysis in curved spacetimes. We might think that if the Lorentzian metric is of the form
        $$
        ds^2 = - f(r,t) dt^2 + g^ij dx_i dx_j
        $$

        in some set of coordinates, then we can define a Euclidean analog
        $$
        ds_E^2 = f(r,t) dt^2 + g^ij dx_i dx_j
        $$

        and do the analysis there. However, there is no guarantee that there exists a complex manifold having these two cross-sections, and so we cannot rely on the Euclidean results to tell us anything about the Lorentzian physics.







        share|cite|improve this answer














        share|cite|improve this answer



        share|cite|improve this answer








        edited 2 hours ago

























        answered 7 hours ago









        Michael SeifertMichael Seifert

        18k2 gold badges33 silver badges60 bronze badges




        18k2 gold badges33 silver badges60 bronze badges






























            draft saved

            draft discarded
















































            Thanks for contributing an answer to Physics Stack Exchange!


            • Please be sure to answer the question. Provide details and share your research!

            But avoid


            • Asking for help, clarification, or responding to other answers.

            • Making statements based on opinion; back them up with references or personal experience.

            Use MathJax to format equations. MathJax reference.


            To learn more, see our tips on writing great answers.




            draft saved


            draft discarded














            StackExchange.ready(
            function ()
            StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fphysics.stackexchange.com%2fquestions%2f500239%2fis-a-wick-rotation-a-change-of-coordinates%23new-answer', 'question_page');

            );

            Post as a guest















            Required, but never shown





















































            Required, but never shown














            Required, but never shown












            Required, but never shown







            Required, but never shown

































            Required, but never shown














            Required, but never shown












            Required, but never shown







            Required, but never shown







            Popular posts from this blog

            19. јануар Садржај Догађаји Рођења Смрти Празници и дани сећања Види још Референце Мени за навигацијуу

            Israel Cuprins Etimologie | Istorie | Geografie | Politică | Demografie | Educație | Economie | Cultură | Note explicative | Note bibliografice | Bibliografie | Legături externe | Meniu de navigaresite web oficialfacebooktweeterGoogle+Instagramcanal YouTubeInstagramtextmodificaremodificarewww.technion.ac.ilnew.huji.ac.ilwww.weizmann.ac.ilwww1.biu.ac.ilenglish.tau.ac.ilwww.haifa.ac.ilin.bgu.ac.ilwww.openu.ac.ilwww.ariel.ac.ilCIA FactbookHarta Israelului"Negotiating Jerusalem," Palestine–Israel JournalThe Schizoid Nature of Modern Hebrew: A Slavic Language in Search of a Semitic Past„Arabic in Israel: an official language and a cultural bridge”„Latest Population Statistics for Israel”„Israel Population”„Tables”„Report for Selected Countries and Subjects”Human Development Report 2016: Human Development for Everyone„Distribution of family income - Gini index”The World FactbookJerusalem Law„Israel”„Israel”„Zionist Leaders: David Ben-Gurion 1886–1973”„The status of Jerusalem”„Analysis: Kadima's big plans”„Israel's Hard-Learned Lessons”„The Legacy of Undefined Borders, Tel Aviv Notes No. 40, 5 iunie 2002”„Israel Journal: A Land Without Borders”„Population”„Israel closes decade with population of 7.5 million”Time Series-DataBank„Selected Statistics on Jerusalem Day 2007 (Hebrew)”Golan belongs to Syria, Druze protestGlobal Survey 2006: Middle East Progress Amid Global Gains in FreedomWHO: Life expectancy in Israel among highest in the worldInternational Monetary Fund, World Economic Outlook Database, April 2011: Nominal GDP list of countries. Data for the year 2010.„Israel's accession to the OECD”Popular Opinion„On the Move”Hosea 12:5„Walking the Bible Timeline”„Palestine: History”„Return to Zion”An invention called 'the Jewish people' – Haaretz – Israel NewsoriginalJewish and Non-Jewish Population of Palestine-Israel (1517–2004)ImmigrationJewishvirtuallibrary.orgChapter One: The Heralders of Zionism„The birth of modern Israel: A scrap of paper that changed history”„League of Nations: The Mandate for Palestine, 24 iulie 1922”The Population of Palestine Prior to 1948originalBackground Paper No. 47 (ST/DPI/SER.A/47)History: Foreign DominationTwo Hundred and Seventh Plenary Meeting„Israel (Labor Zionism)”Population, by Religion and Population GroupThe Suez CrisisAdolf EichmannJustice Ministry Reply to Amnesty International Report„The Interregnum”Israel Ministry of Foreign Affairs – The Palestinian National Covenant- July 1968Research on terrorism: trends, achievements & failuresThe Routledge Atlas of the Arab–Israeli conflict: The Complete History of the Struggle and the Efforts to Resolve It"George Habash, Palestinian Terrorism Tactician, Dies at 82."„1973: Arab states attack Israeli forces”Agranat Commission„Has Israel Annexed East Jerusalem?”original„After 4 Years, Intifada Still Smolders”From the End of the Cold War to 2001originalThe Oslo Accords, 1993Israel-PLO Recognition – Exchange of Letters between PM Rabin and Chairman Arafat – Sept 9- 1993Foundation for Middle East PeaceSources of Population Growth: Total Israeli Population and Settler Population, 1991–2003original„Israel marks Rabin assassination”The Wye River Memorandumoriginal„West Bank barrier route disputed, Israeli missile kills 2”"Permanent Ceasefire to Be Based on Creation Of Buffer Zone Free of Armed Personnel Other than UN, Lebanese Forces"„Hezbollah kills 8 soldiers, kidnaps two in offensive on northern border”„Olmert confirms peace talks with Syria”„Battleground Gaza: Israeli ground forces invade the strip”„IDF begins Gaza troop withdrawal, hours after ending 3-week offensive”„THE LAND: Geography and Climate”„Area of districts, sub-districts, natural regions and lakes”„Israel - Geography”„Makhteshim Country”Israel and the Palestinian Territories„Makhtesh Ramon”„The Living Dead Sea”„Temperatures reach record high in Pakistan”„Climate Extremes In Israel”Israel in figures„Deuteronom”„JNF: 240 million trees planted since 1901”„Vegetation of Israel and Neighboring Countries”Environmental Law in Israel„Executive branch”„Israel's election process explained”„The Electoral System in Israel”„Constitution for Israel”„All 120 incoming Knesset members”„Statul ISRAEL”„The Judiciary: The Court System”„Israel's high court unique in region”„Israel and the International Criminal Court: A Legal Battlefield”„Localities and population, by population group, district, sub-district and natural region”„Israel: Districts, Major Cities, Urban Localities & Metropolitan Areas”„Israel-Egypt Relations: Background & Overview of Peace Treaty”„Solana to Haaretz: New Rules of War Needed for Age of Terror”„Israel's Announcement Regarding Settlements”„United Nations Security Council Resolution 497”„Security Council resolution 478 (1980) on the status of Jerusalem”„Arabs will ask U.N. to seek razing of Israeli wall”„Olmert: Willing to trade land for peace”„Mapping Peace between Syria and Israel”„Egypt: Israel must accept the land-for-peace formula”„Israel: Age structure from 2005 to 2015”„Global, regional, and national disability-adjusted life years (DALYs) for 306 diseases and injuries and healthy life expectancy (HALE) for 188 countries, 1990–2013: quantifying the epidemiological transition”10.1016/S0140-6736(15)61340-X„World Health Statistics 2014”„Life expectancy for Israeli men world's 4th highest”„Family Structure and Well-Being Across Israel's Diverse Population”„Fertility among Jewish and Muslim Women in Israel, by Level of Religiosity, 1979-2009”„Israel leaders in birth rate, but poverty major challenge”„Ethnic Groups”„Israel's population: Over 8.5 million”„Israel - Ethnic groups”„Jews, by country of origin and age”„Minority Communities in Israel: Background & Overview”„Israel”„Language in Israel”„Selected Data from the 2011 Social Survey on Mastery of the Hebrew Language and Usage of Languages”„Religions”„5 facts about Israeli Druze, a unique religious and ethnic group”„Israël”Israel Country Study Guide„Haredi city in Negev – blessing or curse?”„New town Harish harbors hopes of being more than another Pleasantville”„List of localities, in alphabetical order”„Muncitorii români, doriți în Israel”„Prietenia româno-israeliană la nevoie se cunoaște”„The Higher Education System in Israel”„Middle East”„Academic Ranking of World Universities 2016”„Israel”„Israel”„Jewish Nobel Prize Winners”„All Nobel Prizes in Literature”„All Nobel Peace Prizes”„All Prizes in Economic Sciences”„All Nobel Prizes in Chemistry”„List of Fields Medallists”„Sakharov Prize”„Țara care și-a sfidat "destinul" și se bate umăr la umăr cu Silicon Valley”„Apple's R&D center in Israel grew to about 800 employees”„Tim Cook: Apple's Herzliya R&D center second-largest in world”„Lecții de economie de la Israel”„Land use”Israel Investment and Business GuideA Country Study: IsraelCentral Bureau of StatisticsFlorin Diaconu, „Kadima: Flexibilitate și pragmatism, dar nici un compromis în chestiuni vitale", în Revista Institutului Diplomatic Român, anul I, numărul I, semestrul I, 2006, pp. 71-72Florin Diaconu, „Likud: Dreapta israeliană constant opusă retrocedării teritoriilor cureite prin luptă în 1967", în Revista Institutului Diplomatic Român, anul I, numărul I, semestrul I, 2006, pp. 73-74MassadaIsraelul a crescut in 50 de ani cât alte state intr-un mileniuIsrael Government PortalIsraelIsraelIsraelmmmmmXX451232cb118646298(data)4027808-634110000 0004 0372 0767n7900328503691455-bb46-37e3-91d2-cb064a35ffcc1003570400564274ge1294033523775214929302638955X146498911146498911

            Кастелфранко ди Сопра Становништво Референце Спољашње везе Мени за навигацију43°37′18″ СГШ; 11°33′32″ ИГД / 43.62156° СГШ; 11.55885° ИГД / 43.62156; 11.5588543°37′18″ СГШ; 11°33′32″ ИГД / 43.62156° СГШ; 11.55885° ИГД / 43.62156; 11.558853179688„The GeoNames geographical database”„Istituto Nazionale di Statistica”проширитиууWorldCat156923403n850174324558639-1cb14643287r(подаци)