adamsgaard.dk

my academic webpage
git clone git://src.adamsgaard.dk/adamsgaard.dk # fast
git clone https://src.adamsgaard.dk/adamsgaard.dk.git # slow
Log | Files | Refs | README | LICENSE Back to index
commit 87d11309e2cbb1f1442ad5bdc137f78d0e4a816e
parent 926cf1de1f3dba28c26745ecf76bbda256567cc6
Author: Anders Damsgaard <anders@adamsgaard.dk>
Date:   Mon, 24 May 2021 20:51:12 +0200

add seaicemuri post

Diffstat:

Apages/009-seaicemuri.cfg | 7+++++++


Apages/009-seaicemuri.html | 49+++++++++++++++++++++++++++++++++++++++++++++++++


Apages/009-seaicemuri.txt | 42++++++++++++++++++++++++++++++++++++++++++


3 files changed, 98 insertions(+), 0 deletions(-)

diff --git a/pages/009-seaicemuri.cfg b/pages/009-seaicemuri.cfg
@@ -0,0 +1,7 @@
+filename=seaicemuri.html
+title=Sea ice talk: Floe-scale ridging in discrete element models for sea ice
+description=Recorded talk for workshop on granular modeling of sea ice
+id=seaicemuri
+tags=science, sea ice
+created=2021-05-22
+updated=2021-05-22
diff --git a/pages/009-seaicemuri.html b/pages/009-seaicemuri.html
@@ -0,0 +1,49 @@
+<p> Below is my recorded talk for an upcoming workshop on <a
+href="https://seaicemuri.org">modeling the granular nature of sea ice</a>.
+The workshop is online, and will take place in the week of June 7th,
+2021.  Full abstract:</p>
+
+<blockquote>
+<b>Floe-scale ridging in discrete element models for sea ice</b>
+<br><br>
+Anders Damsgaard(1,2), Olga V. Sergienko(1), Alistair Adcroft(1)
+<br><br>
+1: Program in Atmospheric and Oceanic Sciences, Princeton University,
+New Jersey, USA
+<br>
+2: Department of Geoscience, Aarhus University, Aarhus, Denmark
+<br><br>
+Ridging and rafting through compression and shear increase the
+thickness and therefore also the melt resilience of sea-ice packs.
+Present formulations for these mechanisms assume that ice strength
+is solely governed by ice thickness, and generally treat the ice
+pack as a continuum where each cell in the spatial discretization
+includes many individual ice floes.  Particle-based sea ice models
+with granular interactions generally represent the ice on a
+floe-by-floe basis, meaning that new formulations are required for
+including ridging.  We show through small-scale, high-resolution
+Discrete Element Method simulations that floe-floe compression
+encompasses different deformational modes, where elasticity transitions
+to frictional sliding and resultant strain weakening at the onset
+of ridging.  We present a generalized formulation based on elasticity
+and Coulomb friction which is suitable for simulating the contact
+mechanics of ridging in particle-based sea ice models.  On a larger
+scale, this results in ice-pack dynamics prone to stick-slip, strain
+localization, and limited compressional resistance.</blockquote>
+
+<p>Slides and video:</p>
+
+<ul>
+<li><a href="npub/seaicemuri2021-damsgaard.pdf">slides (pdf)</a></li>
+</ul>
+
+<center>
+	<video poster="video/seaicemuri_damsgaard.jpg"
+		controls preload="none" class="mediaframe">
+		<source src="video/seaicemuri_damsgaard.mp4" type="video/mp4">
+		<a href="video/seaicemuri_damsgaard.mp4">Link</a>
+	</video>
+</center>
+
+<p>Several <a href="https://seaicemuri.org/presentations.html">other
+presentations</a> to the workshop are also already available.</p>
diff --git a/pages/009-seaicemuri.txt b/pages/009-seaicemuri.txt
@@ -0,0 +1,42 @@
+Below is my recorded talk for an upcoming workshop on modeling the
+granular nature of sea ice[1] The workshop is online, and will take
+place in the week of June 7th, 2021.  Full abstract:
+
+    Title: Floe-scale ridging in discrete element models for sea ice
+
+    Anders Damsgaard(1,2), Olga V. Sergienko(1), Alistair Adcroft(1)
+
+    1: Program in Atmospheric and Oceanic Sciences, Princeton University,
+    New Jersey, USA
+
+    2: Department of Geoscience, Aarhus University, Aarhus, Denmark
+
+    Ridging and rafting through compression and shear increase the
+    thickness and therefore also the melt resilience of sea-ice packs.
+    Present formulations for these mechanisms assume that ice strength is
+    solely governed by ice thickness, and generally treat the ice pack as
+    a continuum where each cell in the spatial discretization includes
+    many individual ice floes.  Particle-based sea ice models with
+    granular interactions generally represent the ice on a floe-by-floe
+    basis, meaning that new formulations are required for including
+    ridging.  We show through small-scale, high-resolution Discrete
+    Element Method simulations that floe-floe compression encompasses
+    different deformational modes, where elasticity transitions to
+    frictional sliding and resultant strain weakening at the onset of
+    ridging.  We present a generalized formulation based on elasticity
+    and Coulomb friction which is suitable for simulating the contact
+    mechanics of ridging in particle-based sea ice models.  On a larger
+    scale, this results in ice-pack dynamics prone to stick-slip, strain
+    localization, and limited compressional resistance.
+
+Slides and video:
+
+    - slides: gopher://adamsgaard.dk/9/npub/seaicemuri2021-damsgaard.pdf
+    - video: https://adamsgaard.dk/video/seaicemuri_damsgaard.mp4
+
+Several other presentations to the workshop are also already available[2].
+
+
+References:
+[1] https://seaicemuri.org
+[2] https://seaicemuri.org/presentations.html