diff --git a/superconductivity_assignment2_kvkempen.pdf b/superconductivity_assignment2_kvkempen.pdf
index 78cf357..1891b43 100644
Binary files a/superconductivity_assignment2_kvkempen.pdf and b/superconductivity_assignment2_kvkempen.pdf differ
diff --git a/superconductivity_assignment2_kvkempen.tex b/superconductivity_assignment2_kvkempen.tex
index 2e489e5..8cbf2a1 100755
--- a/superconductivity_assignment2_kvkempen.tex
+++ b/superconductivity_assignment2_kvkempen.tex
@@ -246,7 +246,7 @@ Flux passes through these regions in multiples of $\Phi_0$, but usually just one
 and a supercurrent is generated to expel the field from the rest of the material.
 This supercurrent moves around these region in a vortex-like shape.
 
-Please see the figure below for a beautiful drawing.\footnotemark
+Please see the figure below for a beautiful drawing.
 It was not specified what the direction of $\vec{B_E}$ was with respect to the cylinder orientation, so I chose what I thought was most reasonable as an example.
 
 \begin{figure}
@@ -254,7 +254,6 @@ It was not specified what the direction of $\vec{B_E}$ was with respect to the c
 	\includegraphics[width=.6\textwidth]{SchermafbeeldingKees-vortex-by-fleur-ahlers.png}
 	\caption{The direction of $\vec{J_s}$ is such that a magnetic field is generated to counteract and even expel the external field. Around the vortices, that menas that the supercurrents run anti-clockwise. Around the outside border of the cylinder, however, $\vec{J_s}$ runs clockwise to cancel $\vec{B_E}$.}
 \end{figure}
-\footnotetext{Fleur Ahlers saw my drawing and asked whether she could draw it on the computer. Afterwards I asked her `Wil je weten wat je hebt getekend?' and her answer was `Nee'.}
 
 \bibliographystyle{vancouver}
 \bibliography{references.bib}