From a7c23d52429f0729157480d58c2d5a7220446022 Mon Sep 17 00:00:00 2001
From: Ian Jauslin <ian@jauslin.org>
Date: Wed, 24 Mar 2021 18:37:22 -0400
Subject: Update to v1.0

  Changed: title.

  Added: comment in caption of Fig 1 on the dimensionless nature of all
  figures.
---
 Carlen_Holzmann_Jauslin_Lieb_2020.tex | 3 ++-
 1 file changed, 2 insertions(+), 1 deletion(-)

(limited to 'Carlen_Holzmann_Jauslin_Lieb_2020.tex')

diff --git a/Carlen_Holzmann_Jauslin_Lieb_2020.tex b/Carlen_Holzmann_Jauslin_Lieb_2020.tex
index 67398df..93b8791 100644
--- a/Carlen_Holzmann_Jauslin_Lieb_2020.tex
+++ b/Carlen_Holzmann_Jauslin_Lieb_2020.tex
@@ -15,7 +15,7 @@
 
 \begin{document}
 
-\title{A fresh look at a simplified approach to the Bose gas}
+\title{A simplified approach to the repulsive Bose gas from low to high densities and its numerical accuracy}
 
 \author{Eric A. Carlen}
 \affiliation{\it Department of Mathematics, Rutgers University}
@@ -483,6 +483,7 @@ For $\alpha=16$ this is even clearer, and one sees that the Medium Equation is m
     The energy as a function of density for the potential $e^{-|\mathbf x|}$ (top) and $16e^{-|\mathbf x|}$ (bottom).
     We compare the predictions of the Big, Medium and Simple Equations to a QMC simulation.
     For comparison, we also plot the Lee-Huang-Yang (LHY) energy\-~(\ref{lhy}).
+    (All quantities plotted in this and the following figures are dimensionless.)
   }
   \label{fig:energy}
 \end{figure}
-- 
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