When are nonintersecting finite degree field extensions linearly disjoint?











up vote
55
down vote

favorite
22












Let $F$ be a field, and let $K,L$ be finite degree field extensions of $F$ inside a common algebraic closure. Consider the following two properties:



(i) $K$ and $L$ are linearly disjoint over $F$: the natural map $K otimes_F L hookrightarrow KL$ is an injection.



(ii) $K cap L = F$.



It is well known that (i) $implies$ (ii): see e.g. $S$ 13.1 of my field theory notes. This implication ought to be (and usually is) followed up with the comment that (ii) does not imply (i) without some additional hypothesis: for instance take $F = mathbb{Q}$, $K = mathbb{Q}(sqrt[3]{2})$, $L = mathbb{Q}(e^{frac{2 pi i}{3}}sqrt[3]{2})$, or more generally, any two distinct, but conjugate, extensions of prime degree. Thus some normality hypothesis is necessary. What is the weakest such hypothesis?



The following is a standard result: see e.g. $S$ 13.3, loc. cit.




Theorem: If $K/F$ and $L/F$ are both Galois, then (ii) $implies$ (i).




I remember this point coming up in a course I took as a graduate student, and the instructor claimed in passing that it was enough for only one of $K$, $L$ to be Galois. None of the standard field theory texts I own contains a proof of this. But by online searching I found an algebra text of P.M. Cohn which proves something stronger.




Theorem: If at least one of $K,L$ is normal and at least one is separable [it is permissible for the same field to be both normal and separable], then (ii) $implies$ (i).




I wasn't able to freely view the proof, so if someone can pass it along to me I'd be appreciative. Still, I think I know of no counterexamples to the following stronger




Claim: If at least one of $K,L$ is normal, then (ii) $implies$ (i).




Is this in fact true? (I believe I have seen it claimed in certain research papers, e.g. one by Piatetski-Shapiro. But because terminology and running separability hypotheses are not so standardized, I don't take this as conclusive evidence.)










share|cite|improve this question




















  • 6




    Here are the relevant pages from Cohn's Algebra, Volume 3: page 188/1, page 188/2, page 189/1, page 189/2. Cohn doesn't appear to address your question about counterexamples directly in the body of the section, but perhaps there is something hidden in the exercises which I am unable to recognize because I'm lacking the expertise.
    – Martin
    May 5 '13 at 11:23






  • 1




    @Martin: Thanks! That's very helpful.
    – Pete L. Clark
    May 5 '13 at 11:27















up vote
55
down vote

favorite
22












Let $F$ be a field, and let $K,L$ be finite degree field extensions of $F$ inside a common algebraic closure. Consider the following two properties:



(i) $K$ and $L$ are linearly disjoint over $F$: the natural map $K otimes_F L hookrightarrow KL$ is an injection.



(ii) $K cap L = F$.



It is well known that (i) $implies$ (ii): see e.g. $S$ 13.1 of my field theory notes. This implication ought to be (and usually is) followed up with the comment that (ii) does not imply (i) without some additional hypothesis: for instance take $F = mathbb{Q}$, $K = mathbb{Q}(sqrt[3]{2})$, $L = mathbb{Q}(e^{frac{2 pi i}{3}}sqrt[3]{2})$, or more generally, any two distinct, but conjugate, extensions of prime degree. Thus some normality hypothesis is necessary. What is the weakest such hypothesis?



The following is a standard result: see e.g. $S$ 13.3, loc. cit.




Theorem: If $K/F$ and $L/F$ are both Galois, then (ii) $implies$ (i).




I remember this point coming up in a course I took as a graduate student, and the instructor claimed in passing that it was enough for only one of $K$, $L$ to be Galois. None of the standard field theory texts I own contains a proof of this. But by online searching I found an algebra text of P.M. Cohn which proves something stronger.




Theorem: If at least one of $K,L$ is normal and at least one is separable [it is permissible for the same field to be both normal and separable], then (ii) $implies$ (i).




I wasn't able to freely view the proof, so if someone can pass it along to me I'd be appreciative. Still, I think I know of no counterexamples to the following stronger




Claim: If at least one of $K,L$ is normal, then (ii) $implies$ (i).




Is this in fact true? (I believe I have seen it claimed in certain research papers, e.g. one by Piatetski-Shapiro. But because terminology and running separability hypotheses are not so standardized, I don't take this as conclusive evidence.)










share|cite|improve this question




















  • 6




    Here are the relevant pages from Cohn's Algebra, Volume 3: page 188/1, page 188/2, page 189/1, page 189/2. Cohn doesn't appear to address your question about counterexamples directly in the body of the section, but perhaps there is something hidden in the exercises which I am unable to recognize because I'm lacking the expertise.
    – Martin
    May 5 '13 at 11:23






  • 1




    @Martin: Thanks! That's very helpful.
    – Pete L. Clark
    May 5 '13 at 11:27













up vote
55
down vote

favorite
22









up vote
55
down vote

favorite
22






22





Let $F$ be a field, and let $K,L$ be finite degree field extensions of $F$ inside a common algebraic closure. Consider the following two properties:



(i) $K$ and $L$ are linearly disjoint over $F$: the natural map $K otimes_F L hookrightarrow KL$ is an injection.



(ii) $K cap L = F$.



It is well known that (i) $implies$ (ii): see e.g. $S$ 13.1 of my field theory notes. This implication ought to be (and usually is) followed up with the comment that (ii) does not imply (i) without some additional hypothesis: for instance take $F = mathbb{Q}$, $K = mathbb{Q}(sqrt[3]{2})$, $L = mathbb{Q}(e^{frac{2 pi i}{3}}sqrt[3]{2})$, or more generally, any two distinct, but conjugate, extensions of prime degree. Thus some normality hypothesis is necessary. What is the weakest such hypothesis?



The following is a standard result: see e.g. $S$ 13.3, loc. cit.




Theorem: If $K/F$ and $L/F$ are both Galois, then (ii) $implies$ (i).




I remember this point coming up in a course I took as a graduate student, and the instructor claimed in passing that it was enough for only one of $K$, $L$ to be Galois. None of the standard field theory texts I own contains a proof of this. But by online searching I found an algebra text of P.M. Cohn which proves something stronger.




Theorem: If at least one of $K,L$ is normal and at least one is separable [it is permissible for the same field to be both normal and separable], then (ii) $implies$ (i).




I wasn't able to freely view the proof, so if someone can pass it along to me I'd be appreciative. Still, I think I know of no counterexamples to the following stronger




Claim: If at least one of $K,L$ is normal, then (ii) $implies$ (i).




Is this in fact true? (I believe I have seen it claimed in certain research papers, e.g. one by Piatetski-Shapiro. But because terminology and running separability hypotheses are not so standardized, I don't take this as conclusive evidence.)










share|cite|improve this question















Let $F$ be a field, and let $K,L$ be finite degree field extensions of $F$ inside a common algebraic closure. Consider the following two properties:



(i) $K$ and $L$ are linearly disjoint over $F$: the natural map $K otimes_F L hookrightarrow KL$ is an injection.



(ii) $K cap L = F$.



It is well known that (i) $implies$ (ii): see e.g. $S$ 13.1 of my field theory notes. This implication ought to be (and usually is) followed up with the comment that (ii) does not imply (i) without some additional hypothesis: for instance take $F = mathbb{Q}$, $K = mathbb{Q}(sqrt[3]{2})$, $L = mathbb{Q}(e^{frac{2 pi i}{3}}sqrt[3]{2})$, or more generally, any two distinct, but conjugate, extensions of prime degree. Thus some normality hypothesis is necessary. What is the weakest such hypothesis?



The following is a standard result: see e.g. $S$ 13.3, loc. cit.




Theorem: If $K/F$ and $L/F$ are both Galois, then (ii) $implies$ (i).




I remember this point coming up in a course I took as a graduate student, and the instructor claimed in passing that it was enough for only one of $K$, $L$ to be Galois. None of the standard field theory texts I own contains a proof of this. But by online searching I found an algebra text of P.M. Cohn which proves something stronger.




Theorem: If at least one of $K,L$ is normal and at least one is separable [it is permissible for the same field to be both normal and separable], then (ii) $implies$ (i).




I wasn't able to freely view the proof, so if someone can pass it along to me I'd be appreciative. Still, I think I know of no counterexamples to the following stronger




Claim: If at least one of $K,L$ is normal, then (ii) $implies$ (i).




Is this in fact true? (I believe I have seen it claimed in certain research papers, e.g. one by Piatetski-Shapiro. But because terminology and running separability hypotheses are not so standardized, I don't take this as conclusive evidence.)







field-theory






share|cite|improve this question















share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited May 5 '13 at 10:47

























asked May 5 '13 at 2:44









Pete L. Clark

79.9k9161311




79.9k9161311








  • 6




    Here are the relevant pages from Cohn's Algebra, Volume 3: page 188/1, page 188/2, page 189/1, page 189/2. Cohn doesn't appear to address your question about counterexamples directly in the body of the section, but perhaps there is something hidden in the exercises which I am unable to recognize because I'm lacking the expertise.
    – Martin
    May 5 '13 at 11:23






  • 1




    @Martin: Thanks! That's very helpful.
    – Pete L. Clark
    May 5 '13 at 11:27














  • 6




    Here are the relevant pages from Cohn's Algebra, Volume 3: page 188/1, page 188/2, page 189/1, page 189/2. Cohn doesn't appear to address your question about counterexamples directly in the body of the section, but perhaps there is something hidden in the exercises which I am unable to recognize because I'm lacking the expertise.
    – Martin
    May 5 '13 at 11:23






  • 1




    @Martin: Thanks! That's very helpful.
    – Pete L. Clark
    May 5 '13 at 11:27








6




6




Here are the relevant pages from Cohn's Algebra, Volume 3: page 188/1, page 188/2, page 189/1, page 189/2. Cohn doesn't appear to address your question about counterexamples directly in the body of the section, but perhaps there is something hidden in the exercises which I am unable to recognize because I'm lacking the expertise.
– Martin
May 5 '13 at 11:23




Here are the relevant pages from Cohn's Algebra, Volume 3: page 188/1, page 188/2, page 189/1, page 189/2. Cohn doesn't appear to address your question about counterexamples directly in the body of the section, but perhaps there is something hidden in the exercises which I am unable to recognize because I'm lacking the expertise.
– Martin
May 5 '13 at 11:23




1




1




@Martin: Thanks! That's very helpful.
– Pete L. Clark
May 5 '13 at 11:27




@Martin: Thanks! That's very helpful.
– Pete L. Clark
May 5 '13 at 11:27










1 Answer
1






active

oldest

votes

















up vote
0
down vote













There are counterexamples to the Claim. Recall that an extension of a field $F$ of characteristic $p>0$ is separable if and only if it is linearly disjoint from $F^{1/p^infty}$ over $F$. Note that $F^{1/p^infty}/F$ is a normal extension. There is an insparable algebraic extension $K/F$ which does not intersect $F^{1/p^infty} smallsetminus F$ (see Does an inseparable extension have a purely inseparable element?). This gives a counterexample.






share|cite|improve this answer





















    Your Answer





    StackExchange.ifUsing("editor", function () {
    return StackExchange.using("mathjaxEditing", function () {
    StackExchange.MarkdownEditor.creationCallbacks.add(function (editor, postfix) {
    StackExchange.mathjaxEditing.prepareWmdForMathJax(editor, postfix, [["$", "$"], ["\\(","\\)"]]);
    });
    });
    }, "mathjax-editing");

    StackExchange.ready(function() {
    var channelOptions = {
    tags: "".split(" "),
    id: "69"
    };
    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',
    convertImagesToLinks: true,
    noModals: true,
    showLowRepImageUploadWarning: true,
    reputationToPostImages: 10,
    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%2fmath.stackexchange.com%2fquestions%2f381775%2fwhen-are-nonintersecting-finite-degree-field-extensions-linearly-disjoint%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








    up vote
    0
    down vote













    There are counterexamples to the Claim. Recall that an extension of a field $F$ of characteristic $p>0$ is separable if and only if it is linearly disjoint from $F^{1/p^infty}$ over $F$. Note that $F^{1/p^infty}/F$ is a normal extension. There is an insparable algebraic extension $K/F$ which does not intersect $F^{1/p^infty} smallsetminus F$ (see Does an inseparable extension have a purely inseparable element?). This gives a counterexample.






    share|cite|improve this answer

























      up vote
      0
      down vote













      There are counterexamples to the Claim. Recall that an extension of a field $F$ of characteristic $p>0$ is separable if and only if it is linearly disjoint from $F^{1/p^infty}$ over $F$. Note that $F^{1/p^infty}/F$ is a normal extension. There is an insparable algebraic extension $K/F$ which does not intersect $F^{1/p^infty} smallsetminus F$ (see Does an inseparable extension have a purely inseparable element?). This gives a counterexample.






      share|cite|improve this answer























        up vote
        0
        down vote










        up vote
        0
        down vote









        There are counterexamples to the Claim. Recall that an extension of a field $F$ of characteristic $p>0$ is separable if and only if it is linearly disjoint from $F^{1/p^infty}$ over $F$. Note that $F^{1/p^infty}/F$ is a normal extension. There is an insparable algebraic extension $K/F$ which does not intersect $F^{1/p^infty} smallsetminus F$ (see Does an inseparable extension have a purely inseparable element?). This gives a counterexample.






        share|cite|improve this answer












        There are counterexamples to the Claim. Recall that an extension of a field $F$ of characteristic $p>0$ is separable if and only if it is linearly disjoint from $F^{1/p^infty}$ over $F$. Note that $F^{1/p^infty}/F$ is a normal extension. There is an insparable algebraic extension $K/F$ which does not intersect $F^{1/p^infty} smallsetminus F$ (see Does an inseparable extension have a purely inseparable element?). This gives a counterexample.







        share|cite|improve this answer












        share|cite|improve this answer



        share|cite|improve this answer










        answered Nov 22 at 14:25









        unigermalto

        134




        134






























            draft saved

            draft discarded




















































            Thanks for contributing an answer to Mathematics 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.





            Some of your past answers have not been well-received, and you're in danger of being blocked from answering.


            Please pay close attention to the following guidance:


            • 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.


            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%2fmath.stackexchange.com%2fquestions%2f381775%2fwhen-are-nonintersecting-finite-degree-field-extensions-linearly-disjoint%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

            Ellipse (mathématiques)

            Quarter-circle Tiles

            Mont Emei