From 5092a5a3a628275dcfe0c4eaaef0b418c95588a7 Mon Sep 17 00:00:00 2001
From: Claude Meny <claude.meny@irap.omp.eu>
Date: Mon, 13 Jan 2020 19:24:26 +0100
Subject: [PATCH] Update textbook.fr.md

---
 .../04.differential-operators/04.curl/textbook.fr.md            | 2 +-
 1 file changed, 1 insertion(+), 1 deletion(-)

diff --git a/01.curriculum/01.physics-chemistry-biology/03.Niv3/05.math-tools-for-physics/04.differential-operators/04.curl/textbook.fr.md b/01.curriculum/01.physics-chemistry-biology/03.Niv3/05.math-tools-for-physics/04.differential-operators/04.curl/textbook.fr.md
index ffce5006e..01afe363d 100644
--- a/01.curriculum/01.physics-chemistry-biology/03.Niv3/05.math-tools-for-physics/04.differential-operators/04.curl/textbook.fr.md
+++ b/01.curriculum/01.physics-chemistry-biology/03.Niv3/05.math-tools-for-physics/04.differential-operators/04.curl/textbook.fr.md
@@ -252,7 +252,7 @@ je peux maintenant calculer la composante selon  du vecteur rotationnel du champ
 vectoriel au point M. En reprenant la définition (1), j'obtiens
 
 $`\overrightarrow{rot} \; \overrightarrow{X_M} \cdot \overrightarrow{e_z}
-=\lim_{C \to 0} \: \dfrac{\oint_{ABCD} \overrightarrow{X} \cdot \overrightarrow{dl}}{\iint_{ABCD} dS}`$
+= \lim_{C \to 0} \; \dfrac{\oint_{ABCD} \overrightarrow{X} \cdot \overrightarrow{dl}}{\iint_{ABCD} dS}`$
 $`=\left.\dfrac{\partial Y}{\partial y}\right|_M -\left.\dfrac{\partial X}{\partial y}\right|_M`$