Mixed sectional-Ricci curvature obstructions on tori

We establish new obstruction results to the existence of Riemannian metrics on tori satisfying mixed bounds on both their sectional and Ricci curvatures. More precisely, from Lohkamp’s theorem, every torus of dimension at least three admits Riemannian metrics with negative Ricci curvature. We show that the sectional curvature of these metrics cannot be bounded from above by an arbitrarily small positive constant. In particular, if the Ricci curvature of a Riemannian torus is negative, bounded away from zero, then there exist some planar directions in this torus where the sectional curvature is positive, bounded away from zero. All constants are explicit and depend only on the dimension of the torus.

Resonances for Perturbed Periodic Schrödinger Operator

In the semiclassical regime, we obtain a lower bound for the counting function of resonances corresponding to the perturbed periodic Schrödinger operatorPh=-Δ+Vx+W(hx). HereVis a periodic potential,Wa decreasing perturbation andha small positive constant.

Quantum addition circuits and unbounded fan-out

We first show how to construct an $O(n)$-depth $O(n)$-size quantum circuit for addition of two $n$-bit binary numbers with no ancillary qubits. The exact size is $7n-6$, which is smaller than that of any other quantum circuit ever constructed for addition with no ancillary qubits. Using the circuit, we then propose a method for constructing an $O(d(n))$-depth $O(n)$-size quantum circuit for addition with $O(n/d(n))$ ancillary qubits for any $d(n) = \Omega(\log n)$. If we are allowed to use unbounded fan-out gates with length $O(n^{\varepsilon})$ for an arbitrary small positive constant $\varepsilon$, we can modify the method and construct an $O(e(n))$-depth $O(n)$-size circuit with $o(n)$ ancillary qubits for any $e(n) = \Omega(\log^* n)$. In particular, these methods yield efficient circuits with depth $O(\log n)$ and with depth $O(\log^* n)$, respectively. We apply our circuits to constructing efficient quantum circuits for Shor's discrete logarithm algorithm.

Resonances for Slowly Varying Perturbations of a Periodic Schrödinger Operator

We study the resonances of the operator . Here V is a periodic potential, φ a decreasing perturbation and h a small positive constant. We prove the existence of shape resonances near the edges of the spectral bands of , and we give its asymptotic expansions in powers of .

Uniform asymptotic expansions for oblate spheroidal functions I: positive separation parameter λ

SynopsisUniform asymptotic expansions are derived for solutions of the spheroidal wave equation, in the oblate case where the parameter µ is real and nonnegative, the separation parameter λ is real and positive, and γ is purely imaginary (γ = iu). As u →∞, three types of expansions are derived for oblate spheroidal functions, which involve elementary, Airy and Bessel functions. Let δ be an arbitrary small positive constant. The expansions are uniformly valid for λ/u2 fixed and lying in the interval (0,2), and for λ / u2when 0<λ/u2 < 1, and when 1 = 1≦λ/u2 < 2. The union of the domains of validity of the various expansions cover the half- plane arg (z)≦ = π/2.