No Arabic abstract
Let $Z_n(s; a_1,..., a_n)$ be the Epstein zeta function defined as the meromorphic continuation of the function sum_{kinZ^nsetminus{0}}(sum_{i=1}^n [a_i k_i]^2)^{-s}, text{Re} s>frac{n}{2} to the complex plane. We show that for fixed $s eq n/2$, the function $Z_n(s; a_1,..., a_n)$, as a function of $(a_1,..., a_n)in (R^+)^n$ with fixed $prod_{i=1}^n a_i$, has a unique minimum at the point $a_1=...=a_n$. When $sum_{i=1}^n c_i$ is fixed, the function $$(c_1,..., c_n)mapsto Z_n(s; e^{c_1},..., e^{c_n})$$ can be shown to be a convex function of any $(n-1)$ of the variables ${c_1,...,c_n}$. These results are then applied to the study of the sign of $Z_n(s; a_1,..., a_n)$ when $s$ is in the critical range $(0, n/2)$. It is shown that when $1leq nleq 9$, $Z_n(s; a_1,..., a_n)$ as a function of $(a_1,..., a_n)in (R^+)^n$, can be both positive and negative for every $sin (0,n/2)$. When $ngeq 10$, there are some open subsets $I_{n,+}$ of $sin(0,n/2)$, where $Z_{n}(s; a_1,..., a_n)$ is positive for all $(a_1,..., a_n)in(R^+)^n$. By regarding $Z_n(s; a_1,..., a_n)$ as a function of $s$, we find that when $ngeq 10$, the generalized Riemann hypothesis is false for all $(a_1,...,a_n)$.
We introduce a polynomial zeta function $zeta^{(p)}_{P_n}$, related to certain problems of mathematical physics, and compute its value and the value of its first derivative at the origin $s=0$, by means of a very simple technique. As an application, we compute the determinant of the Dirac operator on quaternionic vector spaces.
An elementary quantum-mechanical derivation of the conditions for a system of functions to form a Reisz basis of a Hilbert space on a finite interval is presented.
In this paper, whose aims are mainly pedagogical, we illustrate how to use the local zeta regularization to compute the stress-energy tensor of the Casimir effect. Our attention is devoted to the case of a neutral, massless scalar field in flat space-time, on a space domain with suitable (e.g., Dirichlet) boundary conditions. After a simple outline of the local zeta method, we exemplify it in the typical case of a field between two parallel plates, or outside them. The results are shown to agree with the ones obtained by more popular methods, such as point splitting regularization. In comparison with these alternative methods, local zeta regularization has the advantage to give directly finite results via analitic continuation, with no need to remove or subtract divergent quantities.
We present a summary of recent and older results on Bessel integrals and their relation with zeta numbers.
The differential-equation eigenvalue problem associated with a recently-introduced Hamiltonian, whose eigenvalues correspond to the zeros of the Riemann zeta function, is analyzed using Fourier and WKB analysis. The Fourier analysis leads to a challenging open problem concerning the formulation of the eigenvalue problem in the momentum space. The WKB analysis gives the exact asymptotic behavior of the eigenfunction.