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I'm looking for a proof of the following statement:

Let $X$ be a Banach space and $T$ be a closed map on $X$. For any relatively compact map $A$ the essential spectrum of $T$ and $T+A$ are the same.

This is proven in Kato's Perturbation Theory in IV - Stability Theorems- Section 5. The proof goes via the theory of semi-Fredholm operators, however I would like to know of any other references/proof techniques/books I can look at to see this proof. (I don't like Kato.)

The corresponding result in Hilbert spaces (Weyls theorem) I've seen several proofs for, so I am looking for the result for Banach spaces.

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    $\begingroup$ This site should not become a shortcut to substitute for literature searches. Voting to close. $\endgroup$
    – Michael Renardy
    Commented Feb 23, 2014 at 21:34
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    $\begingroup$ I started a meta thread on the suitability of this question, which I personally think is fine. $\endgroup$
    – Nate Eldredge
    Commented Feb 24, 2014 at 4:31
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    $\begingroup$ While I am essentially on Nate's side of the suitability issue of the question, I would feel better about it if the original poster said something like "I did a web search on 'stability Banach spectrum' as well as consult texts X and Y without success.", so that a variation of Michael's sentiment, "this site is not a reference desk/not for easy literature searches" is not so applicable to the question. Gerhard "Not Until We Build One" Paseman, 2014.02.24 $\endgroup$
    – Gerhard Paseman
    Commented Feb 24, 2014 at 19:20

2 Answers 2

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As an answer to this question (which I spent quite a while longer looking for) I found the following reference: http://evm.ivic.gob.ve/libropaiena.pdf, a book written by Pietro Aiena.

This book is wonderful: and if anyone in the future finds this question I highly recommend it. It contains several possible generalizations of Weyl's theorem to the Banach case, eg, through Fredholm indices, and he contains a lengthy discussion on the relation between Weyl's theorem and Brouwders theorem. It also has lengthy references which provide an excellent starting point for any further questions on the topic/if the original papers are needed.

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Claim: If $T$ is a closed Fredholm operator acting on a complex Banach space $X$ and $A$ is a relatively $T$-compact operator, then the fact that $T+A$ is Fredholm can be derived from the stability under compact perturbations of the bounded Fredholm operators:

Indeed, denoting $X_T$ the domain $D(T)$ with the graph norm $\|x\|_T :=\|x\| +\|Tx\|$, and $j_T$ the inclusion on $X_T$ into $X$, then $Tj_T$ is a bounded Fredholm operator and $Aj_T$ is a compact operator (note that $D(T)\subset D(A)$). Thus $(T+A)j_T$ is bounded Fredholm, hence $T+A$ Fredholm.

The essential spectrum of $T$ is $\sigma_e(T):=\{\lambda : T-\lambda I \textrm{ Fredhom }\}$. The fact that $\sigma_e(T+A)=\sigma_e(T)$ is obtained by applying the Claim to $T-\lambda I$.

In S. Goldberg, Unbounded linear operators, McGraw-Hill 1966, you can find additional details.

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