From 28407333ffceca9b99fae721c30e8ae146a863da Mon Sep 17 00:00:00 2001
From: Justin Gassner <justin.gassner@mailbox.org>
Date: Wed, 14 Feb 2024 07:24:38 +0100
Subject: Update

---
 pages/unbounded-operators/graph-and-closedness.md | 15 +++++----------
 1 file changed, 5 insertions(+), 10 deletions(-)

(limited to 'pages/unbounded-operators/graph-and-closedness.md')

diff --git a/pages/unbounded-operators/graph-and-closedness.md b/pages/unbounded-operators/graph-and-closedness.md
index a9bf738..04a6789 100644
--- a/pages/unbounded-operators/graph-and-closedness.md
+++ b/pages/unbounded-operators/graph-and-closedness.md
@@ -6,17 +6,12 @@ description: >
   The Hellinger–Toeplitz Theorem states that an everywhere-defined symmetric
   operator on a Hilbert space is bounded. We give a proof using the Uniform
   Boundedness Theorem. We give another proof using the Closed Graph Theorem.
-# spellchecker:dictionaries latex
-# spellchecker:words Hellinger Toeplitz innerp hilb Schwarz functionals enspace Riesz
 ---
 
 # {{ page.title }}
 
-
-{: .definition-title }
-
-> Definition (Graph of an Operator)
->
-> The *graph* of an operator $T$ in a Hilbert space $\hilb{H}$
-> is the set of all pairs $(x,y) \in \hilb{H}\times\hilb{H}$
-> where $x$ lies in the domain of $T$ and $y=Tx$.
+{% definition Graph of an Operator %}
+The *graph* of an operator $T$ in a Hilbert space $\hilb{H}$
+is the set of all pairs $(x,y) \in \hilb{H}\times\hilb{H}$
+where $x$ lies in the domain of $T$ and $y=Tx$.
+{% enddefinition %}
-- 
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