English

Linear maps which are anti-derivable at zero

Operator Algebras 2020-03-05 v3 Functional Analysis

Abstract

Let T:AXT:A\to X be a bounded linear operator, where AA is a C^*-algebra, and XX denotes an essential Banach AA-bimodule. We prove that the following statements are equivalent: (a)(a) TT is anti-derivable at zero (i.e. ab=0ab =0 in AA implies T(b)a+bT(a)=0T(b) a + b T(a)=0); (b)(b) There exist an anti-derivation d:AXd:A\to X^{**} and an element ξX\xi \in X^{**} satisfying ξa=aξ,\xi a = a \xi, ξ[a,b]=0,\xi [a,b]=0, T(ab)=bT(a)+T(b)abξa,T(a b) = b T(a) + T(b) a - b \xi a, and T(a)=d(a)+ξa,T(a) = d(a) + \xi a, for all a,bAa,b\in A. We also prove a similar equivalence when XX is replaced with AA^{**}. This provides a complete characterization of those bounded linear maps from AA into XX or into AA^{**} which are anti-derivable at zero. We also present a complete characterization of those continuous linear operators which are ^*-anti-derivable at zero.

Keywords

Cite

@article{arxiv.1911.04134,
  title  = {Linear maps which are anti-derivable at zero},
  author = {Doha Adel Abulhamil and Fatmah B. Jamjoom and Antonio M. Peralta},
  journal= {arXiv preprint arXiv:1911.04134},
  year   = {2020}
}
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