DIFFERENTIALLY LARGE FIELDS

Omar Leon Sanchez; Marcus Tressl

DIFFERENTIALLY LARGE FIELDS

Pure Mathematics

Research output: Contribution to journal › Article › peer-review

Abstract

We introduce the notion of differential largeness for fields equipped with several commuting derivations (as an analogue to largeness of fields). We lay out the foundations of this new class of “tame” differential fields. We state several characterizations and exhibit plenty of examples and applications. Our results strongly indicate that differentially large fields will play a key role in differential field arithmetic. For instance, we characterise differential largeness in terms of being existentially closed in their power series field (furnished with natural derivations), we give explicit constructions of differentially large fields in terms of iterated powers series, we prove that the class of differentially large fields is elementary, and we show that differential largeness is preserved under algebraic extensions, therefore showing that their algebraic closure is differentially closed.

Original language	English
Journal	Algebra and Number Theory
Publication status	Accepted/In press - 20 Mar 2023

Keywords

differential fields
large fields
Taylor morphism
Picard-Vessiot theory
elimination theory
existentially closed structures

Embargoed Document

DifferentiallyLarge
Accepted author manuscript, 661 KB
Embargo ends: 1/01/33

Cite this

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title = "DIFFERENTIALLY LARGE FIELDS",

abstract = "We introduce the notion of differential largeness for fields equipped with several commuting derivations (as an analogue to largeness of fields). We lay out the foundations of this new class of “tame” differential fields. We state several characterizations and exhibit plenty of examples and applications. Our results strongly indicate that differentially large fields will play a key role in differential field arithmetic. For instance, we characterise differential largeness in terms of being existentially closed in their power series field (furnished with natural derivations), we give explicit constructions of differentially large fields in terms of iterated powers series, we prove that the class of differentially large fields is elementary, and we show that differential largeness is preserved under algebraic extensions, therefore showing that their algebraic closure is differentially closed.",

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author = "{Leon Sanchez}, Omar and Marcus Tressl",

year = "2023",

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language = "English",

journal = "Algebra and Number Theory",

issn = "1937-0652",

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T1 - DIFFERENTIALLY LARGE FIELDS

AU - Leon Sanchez, Omar

AU - Tressl, Marcus

PY - 2023/3/20

Y1 - 2023/3/20

N2 - We introduce the notion of differential largeness for fields equipped with several commuting derivations (as an analogue to largeness of fields). We lay out the foundations of this new class of “tame” differential fields. We state several characterizations and exhibit plenty of examples and applications. Our results strongly indicate that differentially large fields will play a key role in differential field arithmetic. For instance, we characterise differential largeness in terms of being existentially closed in their power series field (furnished with natural derivations), we give explicit constructions of differentially large fields in terms of iterated powers series, we prove that the class of differentially large fields is elementary, and we show that differential largeness is preserved under algebraic extensions, therefore showing that their algebraic closure is differentially closed.

AB - We introduce the notion of differential largeness for fields equipped with several commuting derivations (as an analogue to largeness of fields). We lay out the foundations of this new class of “tame” differential fields. We state several characterizations and exhibit plenty of examples and applications. Our results strongly indicate that differentially large fields will play a key role in differential field arithmetic. For instance, we characterise differential largeness in terms of being existentially closed in their power series field (furnished with natural derivations), we give explicit constructions of differentially large fields in terms of iterated powers series, we prove that the class of differentially large fields is elementary, and we show that differential largeness is preserved under algebraic extensions, therefore showing that their algebraic closure is differentially closed.

KW - differential fields

KW - large fields

KW - Taylor morphism

KW - Picard-Vessiot theory

KW - elimination theory

KW - existentially closed structures

M3 - Article

SN - 1937-0652

JO - Algebra and Number Theory

JF - Algebra and Number Theory

ER -

DIFFERENTIALLY LARGE FIELDS

Abstract

Keywords

Embargoed Document

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