Linear isometries between real JB*-triples and C*-algebras (1309.3838v1)

Abstract: Let $T: A\to B$ be a (not necessarily surjective) linear isometry between two real JB$^*$-triples. Then for each $a\in A$ there exists a tripotent $u_a$ in the bidual, $B'',$ of $B$ such that \begin{enumerate}[$(a)$] \item ${u_a,T({f,g,h}),u_a}={u_a,{T(f),T(g),T(h)},u_a}$, for all $f,g,h$ in the real JB$^*$-subtriple, $A_a,$ generated by $a$; \item The mapping ${u_a,T(\cdot),u_a} :A_a\rightarrow B''$ is a linear isometry. \end{enumerate} Furthermore, when $B$ is a real C$^*$-algebra, the projection $p=p_a= u_a^* u_a$ satisfies that $T(\cdot)p :A_a\rightarrow B''$ is an isometric triple homomorphism. When $A$ and $B$ are real C$^*$-algebras and $A$ is abelian of real type, then there exists a partial isometry $u\in B''$ such that the mapping $T(\cdot)u^*u :A\rightarrow B''$ is an isometric triple homomorphism. These results generalise, to the real setting, some previous contributions due to C.-H. Chu and N.-C. Wong, and C.-H. Chu and M. Mackey in 2004 and 2005. We give an example of a non-surjective real linear isometry which cannot be complexified to a complex isometry, showing that the results in the real setting can not be derived by a mere complexification argument.