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Let
$H=-\unicode[STIX]{x1D6E5}+V$
be a Schrödinger operator with some general signed potential
$V$
. This paper is mainly devoted to establishing the
$L^{q}$
-boundedness of the Riesz transform
$\unicode[STIX]{x1D6FB}H^{-1/2}$
for
$q>2$
. We mainly prove that under certain conditions on
$V$
, the Riesz transform
$\unicode[STIX]{x1D6FB}H^{-1/2}$
is bounded on
$L^{q}$
for all
$q\in [2,p_{0})$
with a given
$2<p_{0}<n$
. As an application, the main result can be applied to the operator
$H=-\unicode[STIX]{x1D6E5}+V_{+}-V_{-}$
, where
$V_{+}$
belongs to the reverse Hölder class
$B_{\unicode[STIX]{x1D703}}$
and
$V_{-}\in L^{n/2,\infty }$
with a small norm. In particular, if
$V_{-}=-\unicode[STIX]{x1D6FE}|x|^{-2}$
for some positive number
$\unicode[STIX]{x1D6FE}$
,
$\unicode[STIX]{x1D6FB}H^{-1/2}$
is bounded on
$L^{q}$
for all
$q\in [2,n/2)$
and
$n>4$
.
An interchange ring,
$(R,+,\bullet )$
, is an abelian group with a second binary operation defined so that the interchange law
$(w+x)\bullet (y+z)=(w\bullet y)+(x\bullet z)$
holds. An interchange near ring is the same structure based on a group which may not be abelian. It is shown that each interchange (near) ring based on a group
$G$
is formed from a pair of endomorphisms of
$G$
whose images commute, and that all interchange (near) rings based on
$G$
can be characterized in this manner. To obtain an associative interchange ring, the endomorphisms must be commuting idempotents in the endomorphism semigroup of
$G$
. For
$G$
a finite abelian group, we develop a group-theoretic analogue of the simultaneous diagonalization of idempotent linear operators and show that pairs of endomorphisms which yield associative interchange rings can be diagonalized and then put into a canonical form. A best possible upper bound of
$4^{r}$
can be given for the number of distinct isomorphism classes of associative interchange rings based on a finite abelian group
$A$
which is a direct sum of
$r$
cyclic groups of prime power order. If
$A$
is a direct sum of
$r$
copies of the same cyclic group of prime power order, we show that there are exactly
${\textstyle \frac{1}{6}}(r+1)(r+2)(r+3)$
distinct isomorphism classes of associative interchange rings based on
$A$
. Several examples are given and further comments are made about the general theory of interchange rings.
We investigate properties which ensure that a given finite graph is the commuting graph of a group or semigroup. We show that all graphs on at least two vertices such that no vertex is adjacent to all other vertices is the commuting graph of some semigroup. Moreover, we obtain complete classifications of the graphs with an isolated vertex or edge that are the commuting graph of a group and the cycles that are the commuting graph of a centrefree semigroup.
We prove that an operator system is (min, ess)-nuclear if its
$C^{\ast }$
-envelope is nuclear. This allows us to deduce that an operator system associated to a generating set of a countable discrete group by Farenick et al. [‘Operator systems from discrete groups’, Comm. Math. Phys.329(1) (2014), 207–238] is (min, ess)-nuclear if and only if the group is amenable. We also make a detailed comparison between ess and other operator system tensor products and show that an operator system associated to a minimal generating set of a finitely generated discrete group (respectively, a finite graph) is (min, max)-nuclear if and only if the group is of order less than or equal to three (respectively, every component of the graph is complete).
Metric regularity theory lies in the very heart of variational analysis, a relatively new discipline whose appearance was, to a large extent, determined by the needs of modern optimization theory in which such phenomena as nondifferentiability and set-valued mappings naturally appear. The roots of the theory go back to such fundamental results of the classical analysis as the implicit function theorem, Sard theorem and some others. The paper offers a survey of the state of the art of some principal parts of the theory along with a variety of its applications in analysis and optimization.
We study the variational problem for
$N$
-parallel curves on a Finsler surface by means of exterior differential systems using Griffiths’ method. We obtain the conditions when these curves are extremals of a length functional and write the explicit form of Euler–Lagrange equations for this type of variational problem.