On Indices of Septic Number Fields Defined by Trinomials x7 + ax + b
Abstract
:1. Introduction
2. Main Results
- 1.
- If and , then .
- 2.
- If , divides and does not divide , then .
- 3.
- If , divides and , then .
- 4.
- If , divides and , then .
- 5.
- If , divides and does not divide , then .
- 6.
- If , does not divide both and , then .
3. A Short Introduction to Newton’s Polygon Techniques Applied on Prime Ideal Factorization
- 1.
- 2.
- If -regular, then
4. Proofs of Our Main Results
- 1.
- If divides and , then, by Theorem 6, does not divide if and only if .
- 2.
- For , divides and does not divide , we have . Let and . Since and , by Theorem 6, does not divide if and only if and , which means and or . That is, .
- 3.
- For , divides and , we have . Let . Since , by Theorem 6, does not divide if and only if , which means that or . That is, .
- 4.
- For , divides and , we have . Let and . Since and , by Theorem 6, does not divide if and only if and . That is, .
- 5.
- For , if divides and does not divide , then . Let . Then , by Theorem 6, does not divide if and only if .
- 6.
- For such that does not divide both and , if does not divide , then, by the formula , does not divide . If divides , then let be an integer such that . Then and . Thus divides in . As is the remainder of the Euclidean division of by , by Theorem 6, divides the index .
- 1.
- If divides and divides , then, for , we have in .
- (a)
- If has a single side, that is, , then the side, , is of degree . Thus there is a unique prime ideal of lying above .
- (b)
- If has two sides joining , , and , that is, , then is of degree , and so it provides a unique prime ideal of lying above with residue degree . Let be the degree of .
- i.
- If , then is of degree , and so there are exactly two prime ideals of lying above with residue degree each.
- ii.
- If , then the slope of is and is the residual polynomial of attached to . Thus, we have to use second order Newton polygon techniques. Let be the valuation of a second order Newton polygon; defined by for every non-zero polynomial . Let be the key polynomial of and let be the -Newton polygon of with respect to the valuation . It follows that:if , then for , we have . It follows that, if , then has a single side joining and . Thus is of degree , and so provides a unique prime ideal of lying above . If and , then has a single side joining , , and , with , which is irreducible over . Thus, provides a unique prime ideal of lying above with residue degree . Hence is not a common index divisor of .If and , then, for , we have is the -expansion of , and so has a single side joining and . In this case the side is of degree and provides a unique prime ideal of lying above . If and , then for , has a single side joining and . Thus is of degree , and so provides a unique prime ideal of lying above .If and , then, for , we have as the -expansion of , and has a single side joining , , and . So, is of degree with attached residual polynomial irreducible over . Thus, provides a unique prime ideal of lying above with residue degree .If and , then, for , has two sides joining , , and with . So, each has degree , and so provides two prime ideals of lying above with residue degree each. As provides a prime ideal of lying above with residue degree , we conclude that there are three prime ideals of lying above with residue degree each, and so is a common index divisor of . In this last case, with residue degree each prime ideal factor. Based on Engstrom’s result, we conclude that .
- iii.
- For , we have as the residual polynomial of attached to . Thus, provides a unique prime ideal of lying above , with residue degree and a unique prime ideal of lying above with residue degree . Thus, .
- iv.
- The case is similar to the case . In this case, if and only if and . In this case, with residue degree each factor. Based on Engstrom’s result, we conclude that .
- 2.
- . In this case, modulo . Let , , , and . Since provides a unique prime ideal of lying above , we conclude that is a common index divisor of if and only if provides two prime ideals of lying above of degree each or provides a unique prime ideal of lying above of degree , and provides at least one prime ideal of lying above of degree or also provides two prime ideals of lying above of degree each. That is if and only if one of the following conditions holds:
- (a)
- If and , then and has a single side of height , and so provides a unique prime ideal of lying above with residue degree . For , let . Then . Let , where and . It follows that , and so has a single side joining and . Thus, if is odd, then provides a unique prime ideal of lying above with residue degree . If for some positive integer, , then let , where and for some and . Thus, for some . Hence if , then and . More precisely, if , then , and so provides a unique prime ideal of lying above with residue degree . If , then . It follows that, if , and so provides a unique prime ideal of lying above with residue degree . If , then , and so provides two prime ideals of lying above with residue degree each. In these last two cases, we have divides and .For , we have and . In this case, modulo . Let , , , and . Since provides a unique prime ideal of of lying above with residue degree and provides a unique prime ideal of of lying above with residue degree , we conclude that if and only if provides a unique prime ideal of of lying above with residue degree or provides two distinct prime ideals of of lying above with residue degree each. If , then provides a unique prime ideal of lying above with residue degree , and so . If , then provides a unique prime ideal of lying above with residue degree , and so . For , let us replace by and consider the -Newton polygon of with respect to . It follows that, if , then provides two prime ideals of lying above with residue degree each, and so . If , then provides a unique prime ideal of lying above with residue degree , and so .
- (b)
- and because has two sides.
- (c)
- If and , then provides a unique prime ideal of lying above with residue degree and provides two prime ideals of lying above with residue degree each because has a single side of degree with its attached residual polynomial of . In this case, with residue degrees and , and so .
- (d)
- and . In this case, provides a unique prime ideal of lying above with residue degree and has two sides. More precisely, with residue degrees and , and so .
- (e)
- If and because if , then has two sides, and if , then has a single side of degree , which provides a single prime ideal of lying above with residue degree and has a single side of degree . Thus, there are prime ideals of lying above with residue degree each.
- (f)
- If and , then . If , then, for , has a single side of degree . Since , then has a single side of height . Thus, there are two prime ideals of lying above with residue degree each and one prime ideal with residue degree . If , then, for , has a single side of degree , and its attached residual polynomial of is . Since , we conclude that has a single side of degree , and then there are prime ideals of lying above with residue degree each, and so divides . If , then, for , has two sides of degree each, and so there are prime ideals of lying above with residue degree each, and so divides .
- 1.
- and .
- 2.
- .
- 3.
- .
- 1.
- and , then for , in . It follows that:
- (a)
- If , then has a single side of degree , and so there is a unique prime ideal of lying above .
- (b)
- If , then has two sides joining , , and . Since is of degree , provides a unique prime ideal of lying above with residue degree . Thus, if and only if provides at least three prime ideals of lying above , with residue degree each. If , then is of degree , and so provides exactly one prime ideal of lying above , with residue degree each. If , then is of degree , and so provides at most two prime ideal of lying above . Hence is not a common index divisor of . If , then is of degree and its attached residual polynomial of is . So, we have to use a second order Newton polygon. Let be the valuation of the second order Newton polygon. is defined by for every non-zero polynomial of . Let be a key polynomial of and the -Newton polygon of with respect to . It follows that: if , then, for , we have as the -expansion of . We have the following cases:
- i.
- If , then has a single side joining and . Thus, is of degree and provides a unique prime ideal of lying above with residue degree .
- ii.
- If and , then has a single side joining and . Thus, is of degree and provides a unique prime ideal of lying above with residue degree .
- iii.
- If and , then has a single side joining and and its attached residual polynomial of is , which is irreducible over because is of degree . Thus, provides a unique prime ideal of lying above with residue degree .
- iv.
- If and , then has two sides joining , , and with . Thus, is of degree , of degree , and is its attached residual polynomial of , which is irreducible over . Thus, provides a unique prime ideal of lying above , with residue degree and a unique prime ideal of lying above with residue degree .
Similarly, for , let . Then, is the -expansion of . Analogous to the case , in every case does not divide . If , then in . So, there is exactly a unique prime ideal of lying above with residue degree , and the other prime ideals of lying above are of residue degrees at least each prime ideal factor. Hence, . - (c)
- If , then in . Let , , , and . It follows that:
- i.
- If and , then and . Thus, a provides a unique prime ideal of lying above with residue degree , and each provides two prime ideals of lying above with residue degree each prime ideal factor. In these two cases, .
- ii.
- If and , then and . Thus, and each provide a unique prime ideal of lying above with residue degree , and provides two prime ideals of lying above with residue degree each. Similarly, if and , then and . Thus, and each provide a unique prime ideal of lying above with residue degree , and provides two prime ideals of lying above with residue degree each. In these two cases, .
- iii.
- If and , then has a single side joining and , and has a single side joining and . Thus, there are prime ideals of lying above with residue degree each, and so .
- iv.
- Similarly, if and , then there are prime ideals of lying above with residue degree each, and so .
- v.
- If and , then . Let . Then . Let and , where and . It follows that , and so has a single side joining and . Remark that, since and , , and so provides a unique prime ideal of lying above with residue degree . Thus, if and only if provides at least two prime ideals of lying above with residue degree each prime ideal factor.
- A.
- If , then has a single side of degree , and so provides a unique prime ideal of lying above with residue degree .
- B.
- If , then has a single side joining and , with its attached residual polynomial of . Since and , we have and . Thus, . Since is square free and , then has at most one root in . Thus, provides at most a unique prime ideal of lying above with residue degree . Therefore, .
- C.
- If , then has two sides joining and . It follows that, since is of degree , it provides a unique prime ideal of lying above with residue degree . Moreover, if is even, then is of degree , and so provides two prime ideals of lying above with residue degree each. In this case, . If , then is of degree , with residual polynomial . Since , we have and . Thus, . It follows that, if , then has two different factors of degree each, and so provides two prime ideals of lying above with residue degree each. In this case, there are exactly five prime ideals of lying above with residue degree each and, according to Engstrom’s results, . But, if , then is irreducible over , and so provides a unique prime ideal of lying above with residue degree . In this last case, there are exactly three prime ideals of lying above with residue degree each, and so .
- 1.
- So, . Since and , then , which means . In order to show that , it suffices to show that for every value , such that is irreducible and , there are at most four prime ideals of lying above with residue degree , where is the number field generated by a complex root of .
- (a)
- For , if , then has a single side and it is of degree . Thus, there is a unique prime ideal, , of lying above with residue degree . More precisely, .If , then has two sides. More precisely, is of degree . Let be degree of . Since is the length of , then . Thus, provides a unique prime ideal, , of lying above with residue degree and provides at most three prime ideals, , of lying above with residue degree each.
- (b)
- For , since in , there are at most three prime ideals, , of lying above with residue degree each.
- (c)
- For , since in , there are at most three prime ideals, , of lying above with residue degree each.
- (d)
- For , since in , there are at most three prime ideals of lying above with residue degree each.
- (e)
- For , since in , there are at most three prime ideals, , of lying above with residue degree each.
5. Examples
- 1.
- For and , since is -Eisenstein for every , we conclude that is irreducible over , and (resp. ) does not divide . Thus, (resp. ) does not divide , and so .
- 2.
- For and , since is irreducible over , is irreducible over . By the first item of Theorem 2, we have . By Theorem 3, . Thus, .
- 3.
- For and , since is irreducible over , is irreducible over . Again, since and , by Theorem 2, . By Theorem 3, . Thus, .
- 4.
- For and , since is irreducible over , is irreducible over . Since is a prime ideal of , . Also, since and , by Theorem 3, . Thus, .
- 5.
- For and , since is irreducible over , is irreducible over . Since and , by Theorem 2, . Similarly, since and , by Theorem 3, . Thus, .
- 6.
- For and , since is irreducible over , is irreducible over . Since and , by Theorem 2, . Similarly, since and , by Theorem 3, . Thus, .
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
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El Fadil, L. On Indices of Septic Number Fields Defined by Trinomials x7 + ax + b. Mathematics 2023, 11, 4441. https://doi.org/10.3390/math11214441
El Fadil L. On Indices of Septic Number Fields Defined by Trinomials x7 + ax + b. Mathematics. 2023; 11(21):4441. https://doi.org/10.3390/math11214441
Chicago/Turabian StyleEl Fadil, Lhoussain. 2023. "On Indices of Septic Number Fields Defined by Trinomials x7 + ax + b" Mathematics 11, no. 21: 4441. https://doi.org/10.3390/math11214441
APA StyleEl Fadil, L. (2023). On Indices of Septic Number Fields Defined by Trinomials x7 + ax + b. Mathematics, 11(21), 4441. https://doi.org/10.3390/math11214441