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As stated above: <math>\sqrt[3]{4}=(\sqrt[3]{2})^2</math>, so [Q(<math>\sqrt[3]{2}+ \sqrt[3]{4} </math>):Q]=3. This means we need a polynomial of degree 3.  You can use the same process as 14 by letting x=<math>\sqrt[3]{2}+\sqrt[3]{4}</math> then find <math>x^3</math> which I found to equal 6x-6.  (I found it easier to refer to <math>\sqrt[3]{2}+\sqrt[3]{4}</math> as 2^(1/3) and 2^(2/3) when doing the calculations.)
 
As stated above: <math>\sqrt[3]{4}=(\sqrt[3]{2})^2</math>, so [Q(<math>\sqrt[3]{2}+ \sqrt[3]{4} </math>):Q]=3. This means we need a polynomial of degree 3.  You can use the same process as 14 by letting x=<math>\sqrt[3]{2}+\sqrt[3]{4}</math> then find <math>x^3</math> which I found to equal 6x-6.  (I found it easier to refer to <math>\sqrt[3]{2}+\sqrt[3]{4}</math> as 2^(1/3) and 2^(2/3) when doing the calculations.)
 
I think this is right as the polynomial has <math>\sqrt[3]{2}+\sqrt[3]{4}</math> as a zero.  Did anyone else get this?
 
I think this is right as the polynomial has <math>\sqrt[3]{2}+\sqrt[3]{4}</math> as a zero.  Did anyone else get this?
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See, I know that <math>\sqrt[3]{4}=(\sqrt[3]{2})^2</math> so <math>\sqrt[3]{4}</math> but that didn't help me.  I got 14 easily.  What else is different about this problem?

Revision as of 18:14, 3 December 2008

Following the same procedures as with a square root does not get me anywhere. Does anyone have any suggetions? on how to find the minimal polynomial for a cube root?! --Robertsr 23:49, 2 December 2008 (UTC)

Yea, I keep trying to solve this in a similar way as 14 but it doesn't work. Grrr.

Remember that $ \sqrt[3]{4}=(\sqrt[3]{2})^2 $ so $ \sqrt[3]{4} $ is the only important one

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As stated above: $ \sqrt[3]{4}=(\sqrt[3]{2})^2 $, so [Q($ \sqrt[3]{2}+ \sqrt[3]{4} $):Q]=3. This means we need a polynomial of degree 3. You can use the same process as 14 by letting x=$ \sqrt[3]{2}+\sqrt[3]{4} $ then find $ x^3 $ which I found to equal 6x-6. (I found it easier to refer to $ \sqrt[3]{2}+\sqrt[3]{4} $ as 2^(1/3) and 2^(2/3) when doing the calculations.) I think this is right as the polynomial has $ \sqrt[3]{2}+\sqrt[3]{4} $ as a zero. Did anyone else get this?

--- See, I know that $ \sqrt[3]{4}=(\sqrt[3]{2})^2 $ so $ \sqrt[3]{4} $ but that didn't help me. I got 14 easily. What else is different about this problem?

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