p-adic exponential function

Mathematical function

In mathematics, particularly p-adic analysis, the p-adic exponential function is a p-adic analogue of the usual exponential function on the complex numbers. As in the complex case, it has an inverse function, named the p-adic logarithm.

Definition

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The usual exponential function on C is defined by the infinite series

\exp(z)=\sum _{n=0}^{\infty }{\frac {z^{n}}{n!}}.

{\displaystyle \exp(z)=\sum _{n=0}^{\infty }{\frac {z^{n}}{n!}}.}

Entirely analogously, one defines the exponential function on C_p, the completion of the algebraic closure of Q_p, by

\exp _{p}(z)=\sum _{n=0}^{\infty }{\frac {z^{n}}{n!}}.

{\displaystyle \exp _{p}(z)=\sum _{n=0}^{\infty }{\frac {z^{n}}{n!}}.}

However, unlike exp which converges on all of C, exp_p only converges on the disc

|z|_{p}<p^{-1/(p-1)}.

{\displaystyle |z|_{p}<p^{-1/(p-1)}.}

This is because p-adic series converge if and only if the summands tend to zero, and since the n! in the denominator of each summand tends to make them large p-adically, a small value of z is needed in the numerator. It follows from Legendre's formula that if $|z|_{p}<p^{-1/(p-1)}$ {\displaystyle |z|_{p}<p^{-1/(p-1)}} then ${\frac {z^{n}}{n!}}$ {\displaystyle {\frac {z^{n}}{n!}}} tends to $0$ {\displaystyle 0}, p-adically.

Although the p-adic exponential is sometimes denoted e^x, the number e itself has no p-adic analogue. This is because the power series exp_p(x) does not converge at x = 1. It is possible to choose a number e to be a p-th root of exp_p(p) for p ≠ 2,^[a] but there are multiple such roots and there is no canonical choice among them.^[1]

p-adic logarithm function

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The power series

\log _{p}(1+x)=\sum _{n=1}^{\infty }{\frac {(-1)^{n+1}x^{n}}{n}},

{\displaystyle \log _{p}(1+x)=\sum _{n=1}^{\infty }{\frac {(-1)^{n+1}x^{n}}{n}},}

converges for x in C_p satisfying |x|_p < 1 and so defines the p-adic logarithm function log_p(z) for |z − 1|_p < 1 satisfying the usual property log_p(zw) = log_pz + log_pw. The function log_p can be extended to all of C×ばつ
p (the set of nonzero elements of C_p) by imposing that it continues to satisfy this last property and setting log_p(p) = 0. Specifically, every element w of C×ばつ
p can be written as w = p^r·ζ·z with r a rational number, ζ a root of unity, and |z − 1|_p < 1,^[2] in which case log_p(w) = log_p(z).^[b] This function on C×ばつ
p is sometimes called the Iwasawa logarithm to emphasize the choice of log_p(p) = 0. In fact, there is an extension of the logarithm from |z − 1|_p < 1 to all of C×ばつ
p for each choice of log_p(p) in C_p.^[3]

Properties

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If z and w are both in the radius of convergence for exp_p, then their sum is too and we have the usual addition formula: exp_p(z + w) = exp_p(z)exp_p(w).

Similarly if z and w are nonzero elements of C_p then log_p(zw) = log_pz + log_pw.

For z in the domain of exp_p, we have exp_p(log_p(1+z)) = 1+z and log_p(exp_p(z)) = z.

The roots of the Iwasawa logarithm log_p(z) are exactly the elements of C_p of the form p^r·ζ where r is a rational number and ζ is a root of unity.^[4]

Note that there is no analogue in C_p of Euler's identity, e^2πi = 1. This is a corollary of Strassmann's theorem.

Another major difference to the situation in C is that the domain of convergence of exp_p is much smaller than that of log_p. A modified exponential function — the Artin–Hasse exponential — can be used instead which converges on |z|_p < 1.

Notes

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^ or a 4th root of exp₂(4), for p = 2
^ In factoring w as above, there is a choice of a root involved in writing p^r since r is rational; however, different choices differ only by multiplication by a root of unity, which gets absorbed into the factor ζ.