[cig-commits] r15773 - doc/geodynamics.org/benchmarks/trunk/long

[luis at geodynamics.org]

Author: luis
Date: 2009-10-05 15:49:31 -0700 (Mon, 05 Oct 2009)
New Revision: 15773

Modified:
   doc/geodynamics.org/benchmarks/trunk/long/geomod2008.html
   doc/geodynamics.org/benchmarks/trunk/long/geomod2008.rst
Log:
Fixes to long/geomod2008.rst

Modified: doc/geodynamics.org/benchmarks/trunk/long/geomod2008.html
===================================================================
--- doc/geodynamics.org/benchmarks/trunk/long/geomod2008.html	2009-10-05 22:49:26 UTC (rev 15772)
+++ doc/geodynamics.org/benchmarks/trunk/long/geomod2008.html	2009-10-05 22:49:31 UTC (rev 15773)
@@ -26,7 +26,7 @@
 thickness of the material goes to zero. However, analog experiments
 suggest a finite cohesion, so this benchmark specifies a boundary
 cohesion.</p>
-<p>We modeled the wedge using a relatively low viscosity ($1Pa cdot s$)
+<p>We modeled the wedge using a relatively low viscosity (1Pa cdot s$)
 air layer on top. This low viscosity region does not, for the most part,
 affect the dynamics.</p>
 <p>We modeled boundary friction by first fixing the sand to the boundary. We
@@ -47,16 +47,38 @@
 reduce the boundary friction to $1^{deg}$. The wedge quickly becomes
 unstable and collapses.</p>
 <div class="figure">
-<img alt="images/Geomod2008_wedge_setup.epsFigure[fig:Wedge_setup]Setupforthestablewedgebenchmark.ImagecourtesyofSusanneBuiter." src="images/Geomod2008_wedge_setup.epsFigure[fig:Wedge_setup]Setupforthestablewedgebenchmark.ImagecourtesyofSusanneBuiter." />
+<img alt="images/Geomod2008_wedge_setup.png" src="images/Geomod2008_wedge_setup.png" />
+<p class="caption">Figure [fig:Wedge_setup]</p>
+<div class="legend">
+Setup for the stable wedge benchmark. Image courtesy of Susanne Buiter.</div>
 </div>
 <div class="figure">
-<img alt="images/Stable_wedge_sri.pngFigure[fig:Stable_sri]Strainrateinvariantforthestablewedgebenchmarkwithinthewedge.Outsidethewedge,thestrainratesarelargebecauseoftheair'slowviscosity.Theresolutionis512.128,andthewedgehastranslated4cm." src="images/Stable_wedge_sri.pngFigure[fig:Stable_sri]Strainrateinvariantforthestablewedgebenchmarkwithinthewedge.Outsidethewedge,thestrainratesarelargebecauseoftheair'slowviscosity.Theresolutionis512.128,andthewedgehastranslated4cm." />
+<img alt="images/Stable_wedge_sri.png" src="images/Stable_wedge_sri.png" />
+<p class="caption">Figure [fig:Stable_sri]</p>
+<div class="legend">
+Strain rate invariant for the stable wedge benchmark within the wedge.
+Outside the wedge, the strain rates are large because of the air's low
+viscosity. The resolution is 512.128, and the wedge has translated
+4 cm.</div>
 </div>
 <div class="figure">
-<img alt="images/Stable_wedge_particles.pngFigure[fig:Stable_particles]Materialparticlesforthestablewedgebenchmark.Thedeformationatthetipiscausedbyafiniteboundarycohesion,althoughtheactualstructureisnotresolved.Theresolutionis512x128,andthewedgehastranslated4cm." src="images/Stable_wedge_particles.pngFigure[fig:Stable_particles]Materialparticlesforthestablewedgebenchmark.Thedeformationatthetipiscausedbyafiniteboundarycohesion,althoughtheactualstructureisnotresolved.Theresolutionis512x128,andthewedgehastranslated4cm." />
+<img alt="images/Stable_wedge_particles.png" src="images/Stable_wedge_particles.png" />
+<p class="caption">Figure [fig:Stable_particles]</p>
+<div class="legend">
+Material particles for the stable wedge benchmark. The deformation at
+the tip is caused by a finite boundary cohesion, although the actual
+structure is not resolved. The resolution is 512x128, and the wedge has
+translated 4 cm.</div>
 </div>
 <div class="figure">
-<img alt="images/Stable_wedge_unstable.pngFigure[fig:Stable_unstable]Strainrateinvariantandvelocityarrowsforthestablewedgebenchmark,butwiththefrictionanglereducedto$1^{\deg}$.NotethatthestrainratesaremuchhigherthaninFigure[fig:Stable_sri].Thewedgecollapsesalmostimmediately.Theresolutionis512x128,andthewedgehastranslated0.17cm." src="images/Stable_wedge_unstable.pngFigure[fig:Stable_unstable]Strainrateinvariantandvelocityarrowsforthestablewedgebenchmark,butwiththefrictionanglereducedto$1^{\deg}$.NotethatthestrainratesaremuchhigherthaninFigure[fig:Stable_sri].Thewedgecollapsesalmostimmediately.Theresolutionis512x128,andthewedgehastranslated0.17cm." />
+<img alt="images/Stable_wedge_unstable.png" src="images/Stable_wedge_unstable.png" />
+<p class="caption">Figure [fig:Stable_unstable]</p>
+<div class="legend">
+Strain rate invariant and velocity arrows for the stable wedge
+benchmark, but with the friction angle reduced to $1^{deg}$. Note that
+the strain rates are much higher than in Figure [fig:Stable_sri]. The
+wedge collapses almost immediately. The resolution is 512x128, and the
+wedge has translated 0.17 cm.</div>
 </div>
 </div>
 <div class="section" id="unstable-shortening">
@@ -73,25 +95,59 @@
 [fig:unstable_particles_512] show results at different times and
 different resolutions.</p>
 <div class="figure">
-<img alt="images/Geomod2008_unstable_setup.epsFigure[fig:Unstable-setup]Setupfortheunstableshorteningbenchmark.ImagecourtesyofSusanneBuiter." src="images/Geomod2008_unstable_setup.epsFigure[fig:Unstable-setup]Setupfortheunstableshorteningbenchmark.ImagecourtesyofSusanneBuiter." />
+<img alt="images/Geomod2008_unstable_setup.png" src="images/Geomod2008_unstable_setup.png" />
+<p class="caption">Figure [fig:Unstable-setup]</p>
+<div class="legend">
+Setup for the unstable shortening benchmark.
+Image courtesy of Susanne Buiter.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_unstable_sri128x32.pngFigure[fig:unstable_sri_128]Strainrateinvariantfortheunstableshorteningbenchmarkwitharesolutionof128x32.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_unstable_sri128x32.pngFigure[fig:unstable_sri_128]Strainrateinvariantfortheunstableshorteningbenchmarkwitharesolutionof128x32.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_unstable_sri128x32.png" src="images/Geomod2008_unstable_sri128x32.png" />
+<p class="caption">Figure [fig:unstable_sri_128]</p>
+<div class="legend">
+Strain rate invariant for the unstable shortening benchmark with a
+resolution of 128x32. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_unstable_sri256x64.pngFigure[fig:unstable_sri_256]Strainrateinvariantfortheunstableshorteningbenchmarkwitharesolutionof256x64.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_unstable_sri256x64.pngFigure[fig:unstable_sri_256]Strainrateinvariantfortheunstableshorteningbenchmarkwitharesolutionof256x64.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_unstable_sri256x64.png" src="images/Geomod2008_unstable_sri256x64.png" />
+<p class="caption">Figure [fig:unstable_sri_256]</p>
+<div class="legend">
+Strain rate invariant for the unstable shortening benchmark with a
+resolution of 256x64. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_unstable_sri512x128.pngFigure[fig:unstable_sri_512]Strainrateinvariantfortheunstableshorteningbenchmarkwitharesolutionof512x128.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_unstable_sri512x128.pngFigure[fig:unstable_sri_512]Strainrateinvariantfortheunstableshorteningbenchmarkwitharesolutionof512x128.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_unstable_sri512x128.png" src="images/Geomod2008_unstable_sri512x128.png" />
+<p class="caption">Figure [fig:unstable_sri_512]</p>
+<div class="legend">
+Strain rate invariant for the unstable shortening benchmark with a
+resolution of 512x128. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_unstable_particles128x32.pngFigure[fig:unstable_particles_128]Materialparticlesfortheunstableshorteningbenchmarkwitharesolutionof128x32.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_unstable_particles128x32.pngFigure[fig:unstable_particles_128]Materialparticlesfortheunstableshorteningbenchmarkwitharesolutionof128x32.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_unstable_particles128x32.png" src="images/Geomod2008_unstable_particles128x32.png" />
+<p class="caption">Figure [fig:unstable_particles_128]</p>
+<div class="legend">
+Material particles for the unstable shortening benchmark with a
+resolution of 128x32. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_unstable_particles256x64.pngFigure[fig:unstable_particles_256]Materialparticlesfortheunstableshorteningbenchmarkwitharesolutionof256x64.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_unstable_particles256x64.pngFigure[fig:unstable_particles_256]Materialparticlesfortheunstableshorteningbenchmarkwitharesolutionof256x64.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_unstable_particles256x64.png" src="images/Geomod2008_unstable_particles256x64.png" />
+<p class="caption">Figure [fig:unstable_particles_256]</p>
+<div class="legend">
+Material particles for the unstable shortening benchmark with a
+resolution of 256x64. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_unstable_particles512x128.pngFigure[fig:unstable_particles_512]Materialparticlesfortheunstableshorteningbenchmarkwitharesolutionof512x128.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_unstable_particles512x128.pngFigure[fig:unstable_particles_512]Materialparticlesfortheunstableshorteningbenchmarkwitharesolutionof512x128.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_unstable_particles512x128.png" src="images/Geomod2008_unstable_particles512x128.png" />
+<p class="caption">Figure [fig:unstable_particles_512]</p>
+<div class="legend">
+Material particles for the unstable shortening benchmark with a
+resolution of 512x128. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 </div>
 <div class="section" id="brittle-shortening">
@@ -99,7 +155,7 @@
 <p>This benchmark is very similar to unstable shortening. The only
 difference is that part of the bottom is also moving along as shown in
 Figure [fig:Brittle_setup]. This causes the deformation to start from
-inside the sand box, rather than along the walls. F
+inside the sand box, rather than along the walls.
 Figures
 [fig:brittle_sri_128],
 [fig:brittle_sri_256],
@@ -109,25 +165,59 @@
 [fig:brittle_particles_512] show results at different times and
 different resolutions.</p>
 <div class="figure">
-<img alt="images/Geomod2008_brittle_setup.epsFigure[fig:Brittle_setup]Setupforthebrittleshorteningbenchmark.ImagecourtesyofSusanneBuiter." src="images/Geomod2008_brittle_setup.epsFigure[fig:Brittle_setup]Setupforthebrittleshorteningbenchmark.ImagecourtesyofSusanneBuiter." />
+<img alt="images/Geomod2008_brittle_setup.png" src="images/Geomod2008_brittle_setup.png" />
+<p class="caption">Figure [fig:Brittle_setup]</p>
+<div class="legend">
+Setup for the brittle shortening benchmark.
+Image courtesy of Susanne Buiter.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_brittle_sri128x32.pngFigure[fig:brittle_sri_128]Strainrateinvariantforthebrittleshorteningbenchmarkwitharesolutionof128x32.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_brittle_sri128x32.pngFigure[fig:brittle_sri_128]Strainrateinvariantforthebrittleshorteningbenchmarkwitharesolutionof128x32.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_brittle_sri128x32.png" src="images/Geomod2008_brittle_sri128x32.png" />
+<p class="caption">Figure [fig:brittle_sri_128]</p>
+<div class="legend">
+Strain rate invariant for the brittle shortening benchmark with a
+resolution of 128x32. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_brittle_sri256x64.pngFigure[fig:brittle_sri_256]Strainrateinvariantforthebrittleshorteningbenchmarkwitharesolutionof256x64.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_brittle_sri256x64.pngFigure[fig:brittle_sri_256]Strainrateinvariantforthebrittleshorteningbenchmarkwitharesolutionof256x64.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_brittle_sri256x64.png" src="images/Geomod2008_brittle_sri256x64.png" />
+<p class="caption">Figure [fig:brittle_sri_256]</p>
+<div class="legend">
+Strain rate invariant for the brittle shortening benchmark with a
+resolution of 256x64. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_brittle_sri512x128.pngFigure[fig:brittle_sri_512]Strainrateinvariantforthebrittleshorteningbenchmarkwitharesolutionof512x128.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_brittle_sri512x128.pngFigure[fig:brittle_sri_512]Strainrateinvariantforthebrittleshorteningbenchmarkwitharesolutionof512x128.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_brittle_sri512x128.png" src="images/Geomod2008_brittle_sri512x128.png" />
+<p class="caption">Figure [fig:brittle_sri_512]</p>
+<div class="legend">
+Strain rate invariant for the brittle shortening benchmark with a
+resolution of 512x128. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_brittle_particles128x32.pngFigure[fig:brittle_particles_128]Materialparticlesforthebrittleshorteningbenchmarkwitharesolutionof128x32.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_brittle_particles128x32.pngFigure[fig:brittle_particles_128]Materialparticlesforthebrittleshorteningbenchmarkwitharesolutionof128x32.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_brittle_particles128x32.png" src="images/Geomod2008_brittle_particles128x32.png" />
+<p class="caption">Figure [fig:brittle_particles_128]</p>
+<div class="legend">
+Material particles for the brittle shortening benchmark with a
+resolution of 128x32. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_brittle_particles256x64.pngFigure[fig:brittle_particles_256]Materialparticlesforthebrittleshorteningbenchmarkwitharesolutionof256x64.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_brittle_particles256x64.pngFigure[fig:brittle_particles_256]Materialparticlesforthebrittleshorteningbenchmarkwitharesolutionof256x64.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_brittle_particles256x64.png" src="images/Geomod2008_brittle_particles256x64.png" />
+<p class="caption">Figure [fig:brittle_particles_256]</p>
+<div class="legend">
+Material particles for the brittle shortening benchmark with a
+resolution of 256x64. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 <div class="figure">
-<img alt="images/Geomod2008_brittle_particles512x128.pngFigure[fig:brittle_particles_512]Materialparticlesforthebrittleshorteningbenchmarkwitharesolutionof512x128.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." src="images/Geomod2008_brittle_particles512x128.pngFigure[fig:brittle_particles_512]Materialparticlesforthebrittleshorteningbenchmarkwitharesolutionof512x128.Thesnapshotsaretakenat0,2.5,5,7.5,and10cmofshortening." />
+<img alt="images/Geomod2008_brittle_particles512x128.png" src="images/Geomod2008_brittle_particles512x128.png" />
+<p class="caption">Figure [fig:brittle_particles_512]</p>
+<div class="legend">
+Material particles for the brittle shortening benchmark with a
+resolution of 512x128. The snapshots are taken at 0, 2.5, 5, 7.5, and
+10 cm of shortening.</div>
 </div>
 </div>
 </div>

Modified: doc/geodynamics.org/benchmarks/trunk/long/geomod2008.rst
===================================================================
--- doc/geodynamics.org/benchmarks/trunk/long/geomod2008.rst	2009-10-05 22:49:26 UTC (rev 15772)
+++ doc/geodynamics.org/benchmarks/trunk/long/geomod2008.rst	2009-10-05 22:49:31 UTC (rev 15773)
@@ -22,7 +22,7 @@
 suggest a finite cohesion, so this benchmark specifies a boundary
 cohesion.
 
-We modeled the wedge using a relatively low viscosity ($1\ Pa \cdot s$)
+We modeled the wedge using a relatively low viscosity (1\ Pa \cdot s$)
 air layer on top. This low viscosity region does not, for the most part,
 affect the dynamics.
 
@@ -45,26 +45,34 @@
 reduce the boundary friction to $1^{\deg}$. The wedge quickly becomes
 unstable and collapses.
 
-.. figure:: images/Geomod2008_wedge_setup.eps
+.. figure:: images/Geomod2008_wedge_setup.png
+
    Figure [fig:Wedge_setup]
+
    Setup for the stable wedge benchmark. Image courtesy of Susanne Buiter.
 
 .. figure:: images/Stable_wedge_sri.png
+
    Figure [fig:Stable_sri]
+
    Strain rate invariant for the stable wedge benchmark within the wedge.
    Outside the wedge, the strain rates are large because of the air's low
    viscosity. The resolution is 512.128, and the wedge has translated
    4 cm.
 
 .. figure:: images/Stable_wedge_particles.png
+
    Figure [fig:Stable_particles]
+
    Material particles for the stable wedge benchmark. The deformation at
    the tip is caused by a finite boundary cohesion, although the actual
    structure is not resolved. The resolution is 512x128, and the wedge has
    translated 4 cm.
 
 .. figure:: images/Stable_wedge_unstable.png
+
    Figure [fig:Stable_unstable]
+
    Strain rate invariant and velocity arrows for the stable wedge
    benchmark, but with the friction angle reduced to $1^{\deg}$. Note that
    the strain rates are much higher than in Figure [fig:Stable_sri]. The
@@ -87,43 +95,57 @@
 [fig:unstable_particles_512] show results at different times and
 different resolutions.
 
-.. figure:: images/Geomod2008_unstable_setup.eps
+.. figure:: images/Geomod2008_unstable_setup.png
+
    Figure [fig:Unstable-setup]
+
    Setup for the unstable shortening benchmark.
    Image courtesy of Susanne Buiter.
 
 .. figure:: images/Geomod2008_unstable_sri128x32.png
+
    Figure [fig:unstable_sri_128]
+
    Strain rate invariant for the unstable shortening benchmark with a
    resolution of 128x32. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.
 
 .. figure:: images/Geomod2008_unstable_sri256x64.png
+
    Figure [fig:unstable_sri_256]
+
    Strain rate invariant for the unstable shortening benchmark with a
    resolution of 256x64. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.
 
 .. figure:: images/Geomod2008_unstable_sri512x128.png
+
    Figure [fig:unstable_sri_512]
+
    Strain rate invariant for the unstable shortening benchmark with a
    resolution of 512x128. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.
 
 .. figure:: images/Geomod2008_unstable_particles128x32.png
+
    Figure [fig:unstable_particles_128]
+
    Material particles for the unstable shortening benchmark with a
    resolution of 128x32. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.
 
 .. figure:: images/Geomod2008_unstable_particles256x64.png
+
    Figure [fig:unstable_particles_256]
+
    Material particles for the unstable shortening benchmark with a
    resolution of 256x64. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.
 
 .. figure:: images/Geomod2008_unstable_particles512x128.png
+
    Figure [fig:unstable_particles_512]
+
    Material particles for the unstable shortening benchmark with a
    resolution of 512x128. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.
@@ -135,7 +157,7 @@
 This benchmark is very similar to unstable shortening. The only
 difference is that part of the bottom is also moving along as shown in
 Figure [fig:Brittle_setup]. This causes the deformation to start from
-inside the sand box, rather than along the walls. F
+inside the sand box, rather than along the walls.
 Figures
 [fig:brittle_sri_128],
 [fig:brittle_sri_256],
@@ -145,43 +167,57 @@
 [fig:brittle_particles_512] show results at different times and
 different resolutions.
 
-.. figure:: images/Geomod2008_brittle_setup.eps
+.. figure:: images/Geomod2008_brittle_setup.png
+
    Figure [fig:Brittle_setup]
+
    Setup for the brittle shortening benchmark.
    Image courtesy of Susanne Buiter.
 
 .. figure:: images/Geomod2008_brittle_sri128x32.png
+
    Figure [fig:brittle_sri_128]
+
    Strain rate invariant for the brittle shortening benchmark with a
    resolution of 128x32. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.
 
 .. figure:: images/Geomod2008_brittle_sri256x64.png
+
    Figure [fig:brittle_sri_256]
+
    Strain rate invariant for the brittle shortening benchmark with a
    resolution of 256x64. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.
 
 .. figure:: images/Geomod2008_brittle_sri512x128.png
+
    Figure [fig:brittle_sri_512]
+
    Strain rate invariant for the brittle shortening benchmark with a
    resolution of 512x128. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.
 
 .. figure:: images/Geomod2008_brittle_particles128x32.png
+
    Figure [fig:brittle_particles_128]
+
    Material particles for the brittle shortening benchmark with a
    resolution of 128x32. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.
 
 .. figure:: images/Geomod2008_brittle_particles256x64.png
+
    Figure [fig:brittle_particles_256]
+
    Material particles for the brittle shortening benchmark with a
    resolution of 256x64. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.
 
 .. figure:: images/Geomod2008_brittle_particles512x128.png
+
    Figure [fig:brittle_particles_512]
+
    Material particles for the brittle shortening benchmark with a
    resolution of 512x128. The snapshots are taken at 0, 2.5, 5, 7.5, and
    10 cm of shortening.