2004
DOI: 10.1016/j.jfa.2004.02.009
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The lattice of closed ideals in the Banach algebra of operators on certain Banach spaces

Abstract: Very few Banach spaces E are known for which the lattice of closed ideals in the Banach algebra BðEÞ of all (bounded, linear) operators on E is fully understood. Indeed, up to now the only such Banach spaces are, up to isomorphism, Hilbert spaces and the sequence spaces c 0 and c p for 1ppoN: We add a new member to this family by showing that there are exactly four closed ideals in BðEÞ for the Banach space E :¼ ð"c n 2 Þ c0 ; that is, E is the c 0 -direct sum of the finite-dimensional Hilbert spaces c 1 2 ; c… Show more

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Cited by 34 publications
(34 citation statements)
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“…For a sequence of operators U m : (⊕ m i=1 H i ) ℓ ∞ (m) → K, where H i and K are Hilbert spaces, [7,Lemma 5.3] leads to a dichotomy theorem analogous to Corollary 7. As a result, one may adapt the foregoing arguments to prove that for E = (⊕ℓ 2 (n)) ℓ 1 , G ℓ 1 (E)) is the unique maximal ideal of L(E).…”
Section: Theorem 5 Suppose That T ∈ L(e) and Condition ( * ) Holds Letmentioning
confidence: 99%
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“…For a sequence of operators U m : (⊕ m i=1 H i ) ℓ ∞ (m) → K, where H i and K are Hilbert spaces, [7,Lemma 5.3] leads to a dichotomy theorem analogous to Corollary 7. As a result, one may adapt the foregoing arguments to prove that for E = (⊕ℓ 2 (n)) ℓ 1 , G ℓ 1 (E)) is the unique maximal ideal of L(E).…”
Section: Theorem 5 Suppose That T ∈ L(e) and Condition ( * ) Holds Letmentioning
confidence: 99%
“…In this note, we make a small contribution to the program by identifying the unique maximal ideal in the algebra L(E), where E = (⊕ℓ ∞ (n)) ℓ 1 . Our method is slightly more general in the sense that it works also for the space E = (⊕ℓ 2 (n)) ℓ 1 , which gives an alternate proof of the main result of [9]. Let E n be finite dimensional Banach spaces and let E = (⊕E n ) ℓ 1 .…”
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confidence: 99%
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