A question about the degree of an extension field Announcing the arrival of Valued Associate #679: Cesar Manara Planned maintenance scheduled April 23, 2019 at 23:30 UTC (7:30pm US/Eastern)two Non isomorphic root field-extension of the field.determine degree of field extensionMinimal polynomial and field extensionDegree of the field extension.Field extension of degree 3 and polynomial rootsFinding the degree of the splitting fieldDegree of an extension fieldAn irreducible polynomial of degree n over field is irreducible over extension of degree m if m and n are coprimeA question about extension fieldA question about finite field extension of a finite field

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A question about the degree of an extension field



Announcing the arrival of Valued Associate #679: Cesar Manara
Planned maintenance scheduled April 23, 2019 at 23:30 UTC (7:30pm US/Eastern)two Non isomorphic root field-extension of the field.determine degree of field extensionMinimal polynomial and field extensionDegree of the field extension.Field extension of degree 3 and polynomial rootsFinding the degree of the splitting fieldDegree of an extension fieldAn irreducible polynomial of degree n over field is irreducible over extension of degree m if m and n are coprimeA question about extension fieldA question about finite field extension of a finite field










1












$begingroup$


Consider $f(x) := x^3+2x+2$ and the field $mathbbZ_3$. $f(x)$ is obviously irreducible over $mathbbZ_3$. Let $a$ be a root in an extension field of $mathbbZ_3$, then why is it that $[mathbbZ_3(a):mathbbZ_3] = 3$? What is the basis of $mathbbZ_3(a)$ over $mathbbZ_3$?



I know that $mathbbZ_3(a) simeq mathbbZ_3[x]/<f(x)>$ and since $f(x)$ is irreducible in $mathbbZ_3$, any polynomial in $mathbbZ_3[x]$ can have degree atmost 2. But I don't understand how that ties to $[mathbbZ_3(a):mathbbZ_3] = 3$? And how does that imply $mathbbZ_3(a)simeq GF(3^3)$? Thanks.










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$endgroup$











  • $begingroup$
    See "Field and Galois Theory, Patrick Morandi, chapter 1, proposition 1.15".
    $endgroup$
    – Lucas Corrêa
    2 hours ago















1












$begingroup$


Consider $f(x) := x^3+2x+2$ and the field $mathbbZ_3$. $f(x)$ is obviously irreducible over $mathbbZ_3$. Let $a$ be a root in an extension field of $mathbbZ_3$, then why is it that $[mathbbZ_3(a):mathbbZ_3] = 3$? What is the basis of $mathbbZ_3(a)$ over $mathbbZ_3$?



I know that $mathbbZ_3(a) simeq mathbbZ_3[x]/<f(x)>$ and since $f(x)$ is irreducible in $mathbbZ_3$, any polynomial in $mathbbZ_3[x]$ can have degree atmost 2. But I don't understand how that ties to $[mathbbZ_3(a):mathbbZ_3] = 3$? And how does that imply $mathbbZ_3(a)simeq GF(3^3)$? Thanks.










share|cite|improve this question









$endgroup$











  • $begingroup$
    See "Field and Galois Theory, Patrick Morandi, chapter 1, proposition 1.15".
    $endgroup$
    – Lucas Corrêa
    2 hours ago













1












1








1





$begingroup$


Consider $f(x) := x^3+2x+2$ and the field $mathbbZ_3$. $f(x)$ is obviously irreducible over $mathbbZ_3$. Let $a$ be a root in an extension field of $mathbbZ_3$, then why is it that $[mathbbZ_3(a):mathbbZ_3] = 3$? What is the basis of $mathbbZ_3(a)$ over $mathbbZ_3$?



I know that $mathbbZ_3(a) simeq mathbbZ_3[x]/<f(x)>$ and since $f(x)$ is irreducible in $mathbbZ_3$, any polynomial in $mathbbZ_3[x]$ can have degree atmost 2. But I don't understand how that ties to $[mathbbZ_3(a):mathbbZ_3] = 3$? And how does that imply $mathbbZ_3(a)simeq GF(3^3)$? Thanks.










share|cite|improve this question









$endgroup$




Consider $f(x) := x^3+2x+2$ and the field $mathbbZ_3$. $f(x)$ is obviously irreducible over $mathbbZ_3$. Let $a$ be a root in an extension field of $mathbbZ_3$, then why is it that $[mathbbZ_3(a):mathbbZ_3] = 3$? What is the basis of $mathbbZ_3(a)$ over $mathbbZ_3$?



I know that $mathbbZ_3(a) simeq mathbbZ_3[x]/<f(x)>$ and since $f(x)$ is irreducible in $mathbbZ_3$, any polynomial in $mathbbZ_3[x]$ can have degree atmost 2. But I don't understand how that ties to $[mathbbZ_3(a):mathbbZ_3] = 3$? And how does that imply $mathbbZ_3(a)simeq GF(3^3)$? Thanks.







abstract-algebra galois-theory finite-fields






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share|cite|improve this question











share|cite|improve this question




share|cite|improve this question










asked 2 hours ago









manifoldedmanifolded

53019




53019











  • $begingroup$
    See "Field and Galois Theory, Patrick Morandi, chapter 1, proposition 1.15".
    $endgroup$
    – Lucas Corrêa
    2 hours ago
















  • $begingroup$
    See "Field and Galois Theory, Patrick Morandi, chapter 1, proposition 1.15".
    $endgroup$
    – Lucas Corrêa
    2 hours ago















$begingroup$
See "Field and Galois Theory, Patrick Morandi, chapter 1, proposition 1.15".
$endgroup$
– Lucas Corrêa
2 hours ago




$begingroup$
See "Field and Galois Theory, Patrick Morandi, chapter 1, proposition 1.15".
$endgroup$
– Lucas Corrêa
2 hours ago










2 Answers
2






active

oldest

votes


















2












$begingroup$

In general, the degree of $F(alpha)$ over $F$ is the degree of the minimal polynomial of $alpha$. In this case, the minimal polynomial is $f(x)=x^3+2x+2$ which has degree $3$. The basis is $1,alpha,alpha^2$.



Think of it this way: $F(alpha)$ should consist of elements of the form $p(alpha)/q(alpha)$, where $p,q$ are polynomials. But using the relation $alpha^3=-2alpha-2$, you can see that every polynomial in $alpha$ can be written as a linear combinations of $1,alpha,alpha^2$. And even $alpha^-1$ can be written as such. That means every element of $F(alpha)$ is a linear combination of $1,alpha,alpha^2$.



Let $K=mathbbF_3(alpha)$. To see why $Ksimeq mathbbF_9$, it's just a cardinality argument: since $K$ is a $3$-dimensional $mathbbF_3$-vector space, we know from linear algebra that $Ksimeq mathbbF_3^3$ as vector spaces. The right hand side has 27 elements. So $K$ is the field of 27 elements.






share|cite|improve this answer











$endgroup$












  • $begingroup$
    I see, thanks. Why is $f(x)$ the minimal polynomial for $alpha$? Why can't we have a polynomial of degree, say 2, whose zero is $alpha$?
    $endgroup$
    – manifolded
    2 hours ago










  • $begingroup$
    Thanks @egreg, my arithmetic is suspect.
    $endgroup$
    – Ehsaan
    2 hours ago











  • $begingroup$
    @manifolded: The minimal polynomial of $alpha$ has the property that it generates the ideal of all polynomials which vanish at $alpha$. It is the unique (monic) irreducible polynomial with $alpha$ as a root.
    $endgroup$
    – Ehsaan
    2 hours ago


















1












$begingroup$

Look at the situation from a more abstract point of view. Let $F$ be a field and $f(x)in F[x]$ an irreducible monic polynomial.



If $a$ is a root of $f(x)$ in some extension field $K$ of $F$, then, if $F(a)$ denotes the smallest subfield of $K$ containing $F$ and $a$, we have
$$
F(a)cong F[x]/langle f(x)rangle
$$

and moreover $F[a]$, the smallest subring of $K$ containing $F$ and $a$ is the same as $F(a)$. Therefore we can see $F(a)=F[a]=g(a):g(x)in F[x]$.



On the other hand, as $f(a)=0$, given $g(x)in F[x]$, we can perform the division and write $g(x)=f(x)q(x)+r(x)$, where $r$ has degree less than the degree of $f$. Thus we also have
$$
F(a)=F[a]=g(a):g(x)in F[x],deg g<deg f tag*
$$

which is probably what you refer to by saying “any polynomial in $mathbbZ_3[x]$ can have degree at most $2$” (which isn't a good way to express the fact).



Now, suppose $g(x)$ is a monic polynomial satisfying $g(a)=0$. Take $g$ of minimal degree. Since we can perform the division $f(x)=g(x)q(x)+r(x)$, the assumptions give us that $r(a)=0$; by minimality of $deg g$, we infer that $r(x)=0$. Therefore $g$ divides $f$. Since $f$ is irreducible, we deduce that $g(x)=f(x)$ (they can differ up to a nonzero multiplicative constant, but being both monic, the constant is $1$).



Hence $f(x)$ is the minimal polynomial of $a$.



Now we can see that the set $1,a,a^2,dots,a^n-1$ (where $n=deg f$) is a basis of $F[a]$ as a vector space over $F$. The fact it is a spanning set follows from (*); it is linearly independent because $f$ is the minimal polynomial and a linear combination of those elements is the value of a polynomial of lesser degree than $f$, so it cannot vanish unless all the coefficients are zero.



Finally apply this to your particular case: $mathbbZ_3[a]$ is a three-dimensional vector space over $mathbbZ_3$, so it has $3^3=27$ elements.






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    2 Answers
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    2 Answers
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    active

    oldest

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    2












    $begingroup$

    In general, the degree of $F(alpha)$ over $F$ is the degree of the minimal polynomial of $alpha$. In this case, the minimal polynomial is $f(x)=x^3+2x+2$ which has degree $3$. The basis is $1,alpha,alpha^2$.



    Think of it this way: $F(alpha)$ should consist of elements of the form $p(alpha)/q(alpha)$, where $p,q$ are polynomials. But using the relation $alpha^3=-2alpha-2$, you can see that every polynomial in $alpha$ can be written as a linear combinations of $1,alpha,alpha^2$. And even $alpha^-1$ can be written as such. That means every element of $F(alpha)$ is a linear combination of $1,alpha,alpha^2$.



    Let $K=mathbbF_3(alpha)$. To see why $Ksimeq mathbbF_9$, it's just a cardinality argument: since $K$ is a $3$-dimensional $mathbbF_3$-vector space, we know from linear algebra that $Ksimeq mathbbF_3^3$ as vector spaces. The right hand side has 27 elements. So $K$ is the field of 27 elements.






    share|cite|improve this answer











    $endgroup$












    • $begingroup$
      I see, thanks. Why is $f(x)$ the minimal polynomial for $alpha$? Why can't we have a polynomial of degree, say 2, whose zero is $alpha$?
      $endgroup$
      – manifolded
      2 hours ago










    • $begingroup$
      Thanks @egreg, my arithmetic is suspect.
      $endgroup$
      – Ehsaan
      2 hours ago











    • $begingroup$
      @manifolded: The minimal polynomial of $alpha$ has the property that it generates the ideal of all polynomials which vanish at $alpha$. It is the unique (monic) irreducible polynomial with $alpha$ as a root.
      $endgroup$
      – Ehsaan
      2 hours ago















    2












    $begingroup$

    In general, the degree of $F(alpha)$ over $F$ is the degree of the minimal polynomial of $alpha$. In this case, the minimal polynomial is $f(x)=x^3+2x+2$ which has degree $3$. The basis is $1,alpha,alpha^2$.



    Think of it this way: $F(alpha)$ should consist of elements of the form $p(alpha)/q(alpha)$, where $p,q$ are polynomials. But using the relation $alpha^3=-2alpha-2$, you can see that every polynomial in $alpha$ can be written as a linear combinations of $1,alpha,alpha^2$. And even $alpha^-1$ can be written as such. That means every element of $F(alpha)$ is a linear combination of $1,alpha,alpha^2$.



    Let $K=mathbbF_3(alpha)$. To see why $Ksimeq mathbbF_9$, it's just a cardinality argument: since $K$ is a $3$-dimensional $mathbbF_3$-vector space, we know from linear algebra that $Ksimeq mathbbF_3^3$ as vector spaces. The right hand side has 27 elements. So $K$ is the field of 27 elements.






    share|cite|improve this answer











    $endgroup$












    • $begingroup$
      I see, thanks. Why is $f(x)$ the minimal polynomial for $alpha$? Why can't we have a polynomial of degree, say 2, whose zero is $alpha$?
      $endgroup$
      – manifolded
      2 hours ago










    • $begingroup$
      Thanks @egreg, my arithmetic is suspect.
      $endgroup$
      – Ehsaan
      2 hours ago











    • $begingroup$
      @manifolded: The minimal polynomial of $alpha$ has the property that it generates the ideal of all polynomials which vanish at $alpha$. It is the unique (monic) irreducible polynomial with $alpha$ as a root.
      $endgroup$
      – Ehsaan
      2 hours ago













    2












    2








    2





    $begingroup$

    In general, the degree of $F(alpha)$ over $F$ is the degree of the minimal polynomial of $alpha$. In this case, the minimal polynomial is $f(x)=x^3+2x+2$ which has degree $3$. The basis is $1,alpha,alpha^2$.



    Think of it this way: $F(alpha)$ should consist of elements of the form $p(alpha)/q(alpha)$, where $p,q$ are polynomials. But using the relation $alpha^3=-2alpha-2$, you can see that every polynomial in $alpha$ can be written as a linear combinations of $1,alpha,alpha^2$. And even $alpha^-1$ can be written as such. That means every element of $F(alpha)$ is a linear combination of $1,alpha,alpha^2$.



    Let $K=mathbbF_3(alpha)$. To see why $Ksimeq mathbbF_9$, it's just a cardinality argument: since $K$ is a $3$-dimensional $mathbbF_3$-vector space, we know from linear algebra that $Ksimeq mathbbF_3^3$ as vector spaces. The right hand side has 27 elements. So $K$ is the field of 27 elements.






    share|cite|improve this answer











    $endgroup$



    In general, the degree of $F(alpha)$ over $F$ is the degree of the minimal polynomial of $alpha$. In this case, the minimal polynomial is $f(x)=x^3+2x+2$ which has degree $3$. The basis is $1,alpha,alpha^2$.



    Think of it this way: $F(alpha)$ should consist of elements of the form $p(alpha)/q(alpha)$, where $p,q$ are polynomials. But using the relation $alpha^3=-2alpha-2$, you can see that every polynomial in $alpha$ can be written as a linear combinations of $1,alpha,alpha^2$. And even $alpha^-1$ can be written as such. That means every element of $F(alpha)$ is a linear combination of $1,alpha,alpha^2$.



    Let $K=mathbbF_3(alpha)$. To see why $Ksimeq mathbbF_9$, it's just a cardinality argument: since $K$ is a $3$-dimensional $mathbbF_3$-vector space, we know from linear algebra that $Ksimeq mathbbF_3^3$ as vector spaces. The right hand side has 27 elements. So $K$ is the field of 27 elements.







    share|cite|improve this answer














    share|cite|improve this answer



    share|cite|improve this answer








    edited 2 hours ago

























    answered 2 hours ago









    EhsaanEhsaan

    1,040514




    1,040514











    • $begingroup$
      I see, thanks. Why is $f(x)$ the minimal polynomial for $alpha$? Why can't we have a polynomial of degree, say 2, whose zero is $alpha$?
      $endgroup$
      – manifolded
      2 hours ago










    • $begingroup$
      Thanks @egreg, my arithmetic is suspect.
      $endgroup$
      – Ehsaan
      2 hours ago











    • $begingroup$
      @manifolded: The minimal polynomial of $alpha$ has the property that it generates the ideal of all polynomials which vanish at $alpha$. It is the unique (monic) irreducible polynomial with $alpha$ as a root.
      $endgroup$
      – Ehsaan
      2 hours ago
















    • $begingroup$
      I see, thanks. Why is $f(x)$ the minimal polynomial for $alpha$? Why can't we have a polynomial of degree, say 2, whose zero is $alpha$?
      $endgroup$
      – manifolded
      2 hours ago










    • $begingroup$
      Thanks @egreg, my arithmetic is suspect.
      $endgroup$
      – Ehsaan
      2 hours ago











    • $begingroup$
      @manifolded: The minimal polynomial of $alpha$ has the property that it generates the ideal of all polynomials which vanish at $alpha$. It is the unique (monic) irreducible polynomial with $alpha$ as a root.
      $endgroup$
      – Ehsaan
      2 hours ago















    $begingroup$
    I see, thanks. Why is $f(x)$ the minimal polynomial for $alpha$? Why can't we have a polynomial of degree, say 2, whose zero is $alpha$?
    $endgroup$
    – manifolded
    2 hours ago




    $begingroup$
    I see, thanks. Why is $f(x)$ the minimal polynomial for $alpha$? Why can't we have a polynomial of degree, say 2, whose zero is $alpha$?
    $endgroup$
    – manifolded
    2 hours ago












    $begingroup$
    Thanks @egreg, my arithmetic is suspect.
    $endgroup$
    – Ehsaan
    2 hours ago





    $begingroup$
    Thanks @egreg, my arithmetic is suspect.
    $endgroup$
    – Ehsaan
    2 hours ago













    $begingroup$
    @manifolded: The minimal polynomial of $alpha$ has the property that it generates the ideal of all polynomials which vanish at $alpha$. It is the unique (monic) irreducible polynomial with $alpha$ as a root.
    $endgroup$
    – Ehsaan
    2 hours ago




    $begingroup$
    @manifolded: The minimal polynomial of $alpha$ has the property that it generates the ideal of all polynomials which vanish at $alpha$. It is the unique (monic) irreducible polynomial with $alpha$ as a root.
    $endgroup$
    – Ehsaan
    2 hours ago











    1












    $begingroup$

    Look at the situation from a more abstract point of view. Let $F$ be a field and $f(x)in F[x]$ an irreducible monic polynomial.



    If $a$ is a root of $f(x)$ in some extension field $K$ of $F$, then, if $F(a)$ denotes the smallest subfield of $K$ containing $F$ and $a$, we have
    $$
    F(a)cong F[x]/langle f(x)rangle
    $$

    and moreover $F[a]$, the smallest subring of $K$ containing $F$ and $a$ is the same as $F(a)$. Therefore we can see $F(a)=F[a]=g(a):g(x)in F[x]$.



    On the other hand, as $f(a)=0$, given $g(x)in F[x]$, we can perform the division and write $g(x)=f(x)q(x)+r(x)$, where $r$ has degree less than the degree of $f$. Thus we also have
    $$
    F(a)=F[a]=g(a):g(x)in F[x],deg g<deg f tag*
    $$

    which is probably what you refer to by saying “any polynomial in $mathbbZ_3[x]$ can have degree at most $2$” (which isn't a good way to express the fact).



    Now, suppose $g(x)$ is a monic polynomial satisfying $g(a)=0$. Take $g$ of minimal degree. Since we can perform the division $f(x)=g(x)q(x)+r(x)$, the assumptions give us that $r(a)=0$; by minimality of $deg g$, we infer that $r(x)=0$. Therefore $g$ divides $f$. Since $f$ is irreducible, we deduce that $g(x)=f(x)$ (they can differ up to a nonzero multiplicative constant, but being both monic, the constant is $1$).



    Hence $f(x)$ is the minimal polynomial of $a$.



    Now we can see that the set $1,a,a^2,dots,a^n-1$ (where $n=deg f$) is a basis of $F[a]$ as a vector space over $F$. The fact it is a spanning set follows from (*); it is linearly independent because $f$ is the minimal polynomial and a linear combination of those elements is the value of a polynomial of lesser degree than $f$, so it cannot vanish unless all the coefficients are zero.



    Finally apply this to your particular case: $mathbbZ_3[a]$ is a three-dimensional vector space over $mathbbZ_3$, so it has $3^3=27$ elements.






    share|cite|improve this answer









    $endgroup$

















      1












      $begingroup$

      Look at the situation from a more abstract point of view. Let $F$ be a field and $f(x)in F[x]$ an irreducible monic polynomial.



      If $a$ is a root of $f(x)$ in some extension field $K$ of $F$, then, if $F(a)$ denotes the smallest subfield of $K$ containing $F$ and $a$, we have
      $$
      F(a)cong F[x]/langle f(x)rangle
      $$

      and moreover $F[a]$, the smallest subring of $K$ containing $F$ and $a$ is the same as $F(a)$. Therefore we can see $F(a)=F[a]=g(a):g(x)in F[x]$.



      On the other hand, as $f(a)=0$, given $g(x)in F[x]$, we can perform the division and write $g(x)=f(x)q(x)+r(x)$, where $r$ has degree less than the degree of $f$. Thus we also have
      $$
      F(a)=F[a]=g(a):g(x)in F[x],deg g<deg f tag*
      $$

      which is probably what you refer to by saying “any polynomial in $mathbbZ_3[x]$ can have degree at most $2$” (which isn't a good way to express the fact).



      Now, suppose $g(x)$ is a monic polynomial satisfying $g(a)=0$. Take $g$ of minimal degree. Since we can perform the division $f(x)=g(x)q(x)+r(x)$, the assumptions give us that $r(a)=0$; by minimality of $deg g$, we infer that $r(x)=0$. Therefore $g$ divides $f$. Since $f$ is irreducible, we deduce that $g(x)=f(x)$ (they can differ up to a nonzero multiplicative constant, but being both monic, the constant is $1$).



      Hence $f(x)$ is the minimal polynomial of $a$.



      Now we can see that the set $1,a,a^2,dots,a^n-1$ (where $n=deg f$) is a basis of $F[a]$ as a vector space over $F$. The fact it is a spanning set follows from (*); it is linearly independent because $f$ is the minimal polynomial and a linear combination of those elements is the value of a polynomial of lesser degree than $f$, so it cannot vanish unless all the coefficients are zero.



      Finally apply this to your particular case: $mathbbZ_3[a]$ is a three-dimensional vector space over $mathbbZ_3$, so it has $3^3=27$ elements.






      share|cite|improve this answer









      $endgroup$















        1












        1








        1





        $begingroup$

        Look at the situation from a more abstract point of view. Let $F$ be a field and $f(x)in F[x]$ an irreducible monic polynomial.



        If $a$ is a root of $f(x)$ in some extension field $K$ of $F$, then, if $F(a)$ denotes the smallest subfield of $K$ containing $F$ and $a$, we have
        $$
        F(a)cong F[x]/langle f(x)rangle
        $$

        and moreover $F[a]$, the smallest subring of $K$ containing $F$ and $a$ is the same as $F(a)$. Therefore we can see $F(a)=F[a]=g(a):g(x)in F[x]$.



        On the other hand, as $f(a)=0$, given $g(x)in F[x]$, we can perform the division and write $g(x)=f(x)q(x)+r(x)$, where $r$ has degree less than the degree of $f$. Thus we also have
        $$
        F(a)=F[a]=g(a):g(x)in F[x],deg g<deg f tag*
        $$

        which is probably what you refer to by saying “any polynomial in $mathbbZ_3[x]$ can have degree at most $2$” (which isn't a good way to express the fact).



        Now, suppose $g(x)$ is a monic polynomial satisfying $g(a)=0$. Take $g$ of minimal degree. Since we can perform the division $f(x)=g(x)q(x)+r(x)$, the assumptions give us that $r(a)=0$; by minimality of $deg g$, we infer that $r(x)=0$. Therefore $g$ divides $f$. Since $f$ is irreducible, we deduce that $g(x)=f(x)$ (they can differ up to a nonzero multiplicative constant, but being both monic, the constant is $1$).



        Hence $f(x)$ is the minimal polynomial of $a$.



        Now we can see that the set $1,a,a^2,dots,a^n-1$ (where $n=deg f$) is a basis of $F[a]$ as a vector space over $F$. The fact it is a spanning set follows from (*); it is linearly independent because $f$ is the minimal polynomial and a linear combination of those elements is the value of a polynomial of lesser degree than $f$, so it cannot vanish unless all the coefficients are zero.



        Finally apply this to your particular case: $mathbbZ_3[a]$ is a three-dimensional vector space over $mathbbZ_3$, so it has $3^3=27$ elements.






        share|cite|improve this answer









        $endgroup$



        Look at the situation from a more abstract point of view. Let $F$ be a field and $f(x)in F[x]$ an irreducible monic polynomial.



        If $a$ is a root of $f(x)$ in some extension field $K$ of $F$, then, if $F(a)$ denotes the smallest subfield of $K$ containing $F$ and $a$, we have
        $$
        F(a)cong F[x]/langle f(x)rangle
        $$

        and moreover $F[a]$, the smallest subring of $K$ containing $F$ and $a$ is the same as $F(a)$. Therefore we can see $F(a)=F[a]=g(a):g(x)in F[x]$.



        On the other hand, as $f(a)=0$, given $g(x)in F[x]$, we can perform the division and write $g(x)=f(x)q(x)+r(x)$, where $r$ has degree less than the degree of $f$. Thus we also have
        $$
        F(a)=F[a]=g(a):g(x)in F[x],deg g<deg f tag*
        $$

        which is probably what you refer to by saying “any polynomial in $mathbbZ_3[x]$ can have degree at most $2$” (which isn't a good way to express the fact).



        Now, suppose $g(x)$ is a monic polynomial satisfying $g(a)=0$. Take $g$ of minimal degree. Since we can perform the division $f(x)=g(x)q(x)+r(x)$, the assumptions give us that $r(a)=0$; by minimality of $deg g$, we infer that $r(x)=0$. Therefore $g$ divides $f$. Since $f$ is irreducible, we deduce that $g(x)=f(x)$ (they can differ up to a nonzero multiplicative constant, but being both monic, the constant is $1$).



        Hence $f(x)$ is the minimal polynomial of $a$.



        Now we can see that the set $1,a,a^2,dots,a^n-1$ (where $n=deg f$) is a basis of $F[a]$ as a vector space over $F$. The fact it is a spanning set follows from (*); it is linearly independent because $f$ is the minimal polynomial and a linear combination of those elements is the value of a polynomial of lesser degree than $f$, so it cannot vanish unless all the coefficients are zero.



        Finally apply this to your particular case: $mathbbZ_3[a]$ is a three-dimensional vector space over $mathbbZ_3$, so it has $3^3=27$ elements.







        share|cite|improve this answer












        share|cite|improve this answer



        share|cite|improve this answer










        answered 2 hours ago









        egregegreg

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