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typo on the exponent
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Gerry Myerson
Gerry Myerson
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Promoting my comments to an answer, as suggested by OP:

  1. A polynomial with real coefficients is guaranteed to have a real zero if its degree is odd, and there is no guarantee of a real zero if its degree is even.

  2. For integer $n\ge0$, $\int x^ne^{-x^2}\,dx$ is elementary if and only if $n$ is odd.

  3. For integer $n\geq 2$$n\ge2$, $\zeta(n)$ is known for $n$ even, in the sense that it is a rational multiple of $\pi^n$, with a simple expression for the rational in terms of Bernoulli numbers. It follows that it is transcendental for even $n$. Much less is known about the value of $\zeta(n)$ for odd $n$.

Promoting my comments to an answer, as suggested by OP:

  1. A polynomial with real coefficients is guaranteed to have a real zero if its degree is odd, and there is no guarantee of a real zero if its degree is even.

  2. For integer $n\ge0$, $\int x^ne^{-x^2}\,dx$ is elementary if and only if $n$ is odd.

  3. For integer $n\geq 2$, $\zeta(n)$ is known for $n$ even, in the sense that it is a rational multiple of $\pi^n$, with a simple expression for the rational in terms of Bernoulli numbers. It follows that it is transcendental for even $n$. Much less is known about the value of $\zeta(n)$ for odd $n$.

Promoting my comments to an answer, as suggested by OP:

  1. A polynomial with real coefficients is guaranteed to have a real zero if its degree is odd, and there is no guarantee of a real zero if its degree is even.

  2. For integer $n\ge0$, $\int x^ne^{-x^2}\,dx$ is elementary if and only if $n$ is odd.

  3. For integer $n\ge2$, $\zeta(n)$ is known for $n$ even, in the sense that it is a rational multiple of $\pi^n$, with a simple expression for the rational in terms of Bernoulli numbers. It follows that it is transcendental for even $n$. Much less is known about $\zeta(n)$ for odd $n$.

typo on the exponent
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edit approved Jun 1, 2023 at 22:11
Luis Ferroni
edit approved Jun 1, 2023 at 22:11
Luis Ferroni
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Promoting my comments to an answer, as suggested by OP:

  1. A polynomial with real coefficients is guaranteed to have a real zero if its degree is odd, and there is no guarantee of a real zero if its degree is even.

  2. For integer $n\ge0$, $\int x^ne^{-x^2}\,dx$ is elementary if and only if $n$ is odd.

  3. For integer $n\ge2$$n\geq 2$, $\zeta(n)$ is known for $n$ even, in the sense that it is a rational multiple of $\pi$$\pi^n$, with a simple expression for the rational in terms of Bernoulli numbers. It follows that it is transcendental for even $n$. Much less is known about the value of $\zeta(n)$ for odd $n$.

Promoting my comments to an answer, as suggested by OP:

  1. A polynomial with real coefficients is guaranteed to have a real zero if its degree is odd, and there is no guarantee of a real zero if its degree is even.

  2. For integer $n\ge0$, $\int x^ne^{-x^2}\,dx$ is elementary if and only if $n$ is odd.

  3. For integer $n\ge2$, $\zeta(n)$ is known for $n$ even, in the sense that it is a rational multiple of $\pi$, with a simple expression for the rational in terms of Bernoulli numbers. It follows that it is transcendental for even $n$. Much less is known about $\zeta(n)$ for odd $n$.

Promoting my comments to an answer, as suggested by OP:

  1. A polynomial with real coefficients is guaranteed to have a real zero if its degree is odd, and there is no guarantee of a real zero if its degree is even.

  2. For integer $n\ge0$, $\int x^ne^{-x^2}\,dx$ is elementary if and only if $n$ is odd.

  3. For integer $n\geq 2$, $\zeta(n)$ is known for $n$ even, in the sense that it is a rational multiple of $\pi^n$, with a simple expression for the rational in terms of Bernoulli numbers. It follows that it is transcendental for even $n$. Much less is known about the value of $\zeta(n)$ for odd $n$.

Post Made Community Wiki by Asaf Karagila
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Gerry Myerson
Gerry Myerson
  • 39.9k
  • 10
  • 186
  • 247

Promoting my comments to an answer, as suggested by OP:

  1. A polynomial with real coefficients is guaranteed to have a real zero if its degree is odd, and there is no guarantee of a real zero if its degree is even.

  2. For integer $n\ge0$, $\int x^ne^{-x^2}\,dx$ is elementary if and only if $n$ is odd.

  3. For integer $n\ge2$, $\zeta(n)$ is known for $n$ even, in the sense that it is a rational multiple of $\pi$, with a simple expression for the rational in terms of Bernoulli numbers. It follows that it is transcendental for even $n$. Much less is known about $\zeta(n)$ for odd $n$.