1 + 1 + 1 + 1 + ⋯

This value can be justified by certain mathematical methods for obtaining values from divergent series, including zeta function regularization.

1 + 1 + 1 + 1 + ⋯ is a divergent series, meaning that its sequence of partial sums does not converge to a limit in the real numbers.

The sequence 1n can be thought of as a geometric series with the common ratio 1.

⁠, but this summation method fails for 1 + 1 + 1 + 1 + ⋯, producing a division by zero.

Together with Grandi's series, this is one of two geometric series with rational ratio that diverges both for the real numbers and for all systems of p-adic numbers.

In the context of the extended real number line since its sequence of partial sums increases monotonically without bound.

Where the sum of n0 occurs in physical applications, it may sometimes be interpreted by zeta function regularization, as the value at s = 0 of the Riemann zeta function: The two formulas given above are not valid at zero however, but the analytic continuation is Using this one gets (given that Γ(1) = 1), where the power series expansion for ζ(s) about s = 1 follows because ζ(s) has a simple pole of residue one there.

Emilio Elizalde presents a comment from others about the series, suggesting the centrality of the zeta function regularization of this series in physics: In a short period of less than a year, two distinguished physicists, A. Slavnov and F. Yndurain, gave seminars in Barcelona, about different subjects.

It was remarkable that, in both presentations, at some point the speaker addressed the audience with these words: 'As everybody knows, 1 + 1 + 1 + ⋯ = −⁠1/2⁠.'