From 78f1a06ea606b109d9f9f794a9f8da5939f38e6b Mon Sep 17 00:00:00 2001
From: sjplimp <sjplimp@f3b2605a-c512-4ea7-a41b-209d697bcdaa>
Date: Fri, 25 May 2012 15:04:57 +0000
Subject: [PATCH] git-svn-id: svn://svn.icms.temple.edu/lammps-ro/trunk@8187
 f3b2605a-c512-4ea7-a41b-209d697bcdaa

---
 doc/pair_gran.html | 7 +++++--
 doc/pair_gran.txt  | 5 ++++-
 2 files changed, 9 insertions(+), 3 deletions(-)

diff --git a/doc/pair_gran.html b/doc/pair_gran.html
index cef4ccafab..eb452764c6 100644
--- a/doc/pair_gran.html
+++ b/doc/pair_gran.html
@@ -131,8 +131,11 @@ constant with units of force/distance.  In the Hertzian case, Kn is
 like a non-linear spring constant with units of force/area or
 pressure, and as shown in the <A HREF = "#Zhang">(Zhang)</A> paper, Kn = 4G /
 (3(1-nu)) where nu = the Poisson ratio, G = shear modulus = E /
-(2(1+nu)), and E = Young's modulus.  Similarly, Kt = 8G / (2-nu).
-Thus in the Hertzian case Kn and Kt can be set to values that
+(2(1+nu)), and E = Young's modulus.  Similarly, Kt = 4G / (2-nu).
+(NOTE: in an earlier version of the manual, we incorrectly stated that
+Kt = 8G / (2-nu).)
+</P>
+<P>Thus in the Hertzian case Kn and Kt can be set to values that
 corresponds to properties of the material being modeled.  This is also
 true in the Hookean case, except that a spring constant must be chosen
 that is appropriate for the absolute size of particles in the model.
diff --git a/doc/pair_gran.txt b/doc/pair_gran.txt
index e15a6aca5f..1027bb77f1 100644
--- a/doc/pair_gran.txt
+++ b/doc/pair_gran.txt
@@ -117,7 +117,10 @@ constant with units of force/distance.  In the Hertzian case, Kn is
 like a non-linear spring constant with units of force/area or
 pressure, and as shown in the "(Zhang)"_#Zhang paper, Kn = 4G /
 (3(1-nu)) where nu = the Poisson ratio, G = shear modulus = E /
-(2(1+nu)), and E = Young's modulus.  Similarly, Kt = 8G / (2-nu).
+(2(1+nu)), and E = Young's modulus.  Similarly, Kt = 4G / (2-nu).
+(NOTE: in an earlier version of the manual, we incorrectly stated that
+Kt = 8G / (2-nu).)
+
 Thus in the Hertzian case Kn and Kt can be set to values that
 corresponds to properties of the material being modeled.  This is also
 true in the Hookean case, except that a spring constant must be chosen