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1 %{pagebegin}
2 <article>
3 <h1>Research</h1>
4
5 <p>I am interested in understanding mechanical and hydrological processes in the
6 climate system, specifically processes that relate to mechanics of granular
7 materials, sea ice, and ice-sheet flow under past, present, and future scenarios.
8 Investigations of fundamental granular mechanics are important in many
9 geodynamical and geomorphological processes and settings, such as earthquakes,
10 landslides, sediment transport in flowing water, and dam stability.</p>
11
12 <p>I have listed my publications and submitted manuscripts below.
13 If you would like to collaborate on a scientific problem please <a
14 href="contact.html">get in touch</a>.</p>
15
16
17 <h2>Publications</h2>
18
19 <ul>
20
21 <li>
22 M. W. Svendsen, S. M. Kristiansen, V. K. Pedersen, and <strong>A. Damsgaard</strong>
23 2024
24 <a href="https://2dgf.dk/publikationer/geologisk-tidsskrift/geologisk-tidsskrift-2024/#7">
25 "Mit livs dessert: 100-års jubilæet for Ellen Louise Mertz' studie af niveauforandringer i Danmark"</a>
26 (en: “The dessert of my life: the 100-year anniversary of Ellen Louise Mertz' studies of elevation changes in Denmark”)
27 Geologisk Tidsskrift
28 [<a href="papers/Svendsen%20et%20al%202024%20Mit%20livs%20dessert.pdf">PDF</a>]
29 <br>
30 <br>
31 </li>
32
33 <li>
34 J. D. Andersen, L. Bødker, J. Dolby, <strong>A. Damsgaard</strong>, and N. Okkels
35 2024
36 <a href="https://www.geo.dk/bibliotek/#t=article">
37 "Foundation on organic diatomite"</a>
38 Proceedings of the 19th Nordic Geotechnical Meeting
39 [<a href="papers/Andersen%20et%20al%202024%20Foundation%20on%20organic%20diatomite.pdf">PDF</a>]
40 <br>
41 <br>
42 </li>
43
44 <li>
45 I. Kasmalkar, <strong>A. Damsgaard</strong>, L. Goren, and J. Suckale
46 2021
47 <a href="https://doi.org/10.1029/2021JF006460">
48 "Shear variation at the ice-till interface changes the spatial distribution of till porosity and meltwater drainage"</a>
49 Journal of Geophysical Research: Earth Surface, vol. 126
50 [<a href="papers/Kasmalkar%20et%20al%202021%20Shear%20variation%20at%20the%20ice-till%20interface%20changes%20the%20spatial%20distribution%20of%20till%20porosity%20and%20meltwater%20drainage.pdf">PDF</a>]
51 <br>
52 <br>
53 </li>
54
55 <li>
56 <strong>A. Damsgaard</strong>, O. Sergienko, and A. Adcroft
57 2021
58 <a href="https://doi.org/10.1029/2020MS002336">
59 "The effects of ice floe-floe interactions on pressure ridging in sea ice"</a>
60 Journal of Advances in Modeling Earth Systems, vol. 13
61 [<a href="papers/Damsgaard%20et%20al%202021%20The%20effects%20of%20ice%20floe-floe%20interactions%20on%20pressure%20ridging%20in%20sea%20ice.pdf">PDF</a>]
62 <br>
63 <br>
64 </li>
65
66 <li>
67 <strong>A. Damsgaard</strong>, L. Goren, and J. Suckale
68 2020
69 <a href="https://doi.org/10.1038/s43247-020-00074-7">
70 "Water pressure fluctuations control variability in sediment flux and slip dynamics beneath glaciers and ice streams"</a>
71 Communications Earth & Environment, vol. 1(66)
72 [<a href="papers/Damsgaard%20et%20al%202020%20Water%20pressure%20fluctuations%20control%20variability%20in%20sediment%20flux%20and%20slip%20dynamics%20beneath%20glaciers%20and%20ice%20streams.pdf">PDF</a>,
73 <a href="papers/Damsgaard%20et%20al%202020%20Water%20pressure%20fluctuations%20control%20variability%20in%20sediment%20flux%20and%20slip%20dynamics%20beneath%20glaciers%20and%20ice%20streams%20SI.pdf">SI</a>]
74 <br>
75 <br>
76 </li>
77
78 <li>
79 <strong>A. Damsgaard</strong>, A. Adcroft, and O. Sergienko
80 2018
81 <a href="https://doi.org/10.1029/2018MS001299">
82 "Application of discrete-element methods to approximate sea-ice dynamics"</a>
83 Journal of Advances in Modeling Earth Systems, vol. 10, 2228-2244
84 [<a href="papers/Damsgaard%20et%20al%202018%20Application%20of%20discrete-element%20methods%20to%20approximate%20sea-ice%20dynamics.pdf">PDF</a>]
85 <br>
86 <br>
87 </li>
88
89 <li>
90 M.D. Bateman, D.A. Swift, J.A. Piotrowski, E.J. Rhodes, and
91 <strong>A. Damsgaard</strong>
92 2018
93 <a href="https://doi.org/10.1016/j.geomorph.2018.01.017">
94 "Can glacial shearing of sediment reset the signal used for luminescence
95 dating?"</a>
96 Geomorphology, vol. 306, 90-101
97 [<a href="papers/Bateman%20et%20al%202018%20Can%20glacial%20shearing%20of%20sediment%20reset%20the%20signal%20used%20for%20luminescence%20dating.pdf">PDF</a>]
98 <br>
99 <br>
100 </li>
101
102 <li>
103 <strong>A. Damsgaard</strong>, J. Suckale, J.A. Piotrowski, M. Houssais,
104 M.R. Siegfried, and H.A. Fricker
105 2017
106 <a href="https://doi.org/10.1017/jog.2017.71">
107 "Sediment behavior controls equilibrium width of subglacial channels"</a>
108 Journal of Glaciology, vol. 63, 1034-1048
109 [<a href="papers/Damsgaard%20et%20al%202017%20Sediment%20behavior%20controls%20equilibrium%20width%20of%20subglacial%20channels.pdf">PDF</a>]
110 <br>
111 <br>
112 </li>
113 <li>
114 <strong>A. Damsgaard</strong>, A. Cabrales-Vargas, J. Suckale, and L. Goren
115 2017
116 <a href="https://doi.org/10.1061/9780784480779.024">"The coupled dynamics
117 of meltwater percolation and granular deformation in the sediment layer
118 underlying parts of the big ice sheets"</a>
119 Poromechanics VI
120 [<a href="papers/Damsgaard%20et%20al%202017%20The%20coupled%20dynamics%20of%20meltwater%20percolation%20and%20granular%20deformation%20in%20the%20sediment%20layer%20underlying%20parts%20of%20the%20big%20ice%20sheets.pdf">PDF</a>]
121 <br>
122 <br>
123 </li>
124
125 <li>
126 <strong>A. Damsgaard</strong>, D.L. Egholm, L.H. Beem, S. Tulaczyk, N.K.
127 Larsen, J.A. Piotrowski, and M.R. Siegfried
128 2016
129 <a href="https://doi.org/10.1002/2016GL071579">"Ice flow dynamics forced
130 by water pressure variations in subglacial granular beds"</a>
131 Geophysical Research Letters, vol. 43, 12,165-12,173
132 [<a href="papers/Damsgaard%20et%20al%202016%20Ice%20flow%20dynamics%20forced%20by%20water%20pressure%20variations%20in%20subglacial%20granular%20beds.pdf">PDF</a>,
133 <a href="papers/Damsgaard%20et%20al%202016%20Ice%20flow%20dynamics%20forced%20by%20water%20pressure%20variations%20in%20subglacial%20granular%20beds%20SI.pdf">SI</a>]
134 <br>
135 <br>
136 </li>
137
138 <li>
139 <strong>A. Damsgaard</strong>, D.L. Egholm, J.A. Piotrowski, S. Tulaczyk,
140 N.K. Larsen, and C.F. Brædstrup
141 2015
142 <a href="https://doi.org/10.5194/tc-9-2183-2015">
143 "A new methodology to simulate subglacial deformation of water-saturated
144 granular material"</a>
145 The Cryosphere, vol. 9, 2183-2200
146 [<a href="papers/Damsgaard%20et%20al%202015%20A%20new%20methodology%20to%20simulate%20subglacial%20deformation%20of%20water-saturated%20granular%20material.pdf">PDF</a>]
147 <br>
148 <br>
149 </li>
150
151 <li>
152 <strong>A. Damsgaard</strong>
153 2015
154 <a href="https://adamsgaard.dk/pub/ad-phd-thesis.pdf">
155 "Numerical Modeling of Subglacial Sediment Deformation"</a>
156 Ph.D. thesis, Aarhus University, 165 pp.
157 [<a href="pub/ad-phd-thesis.pdf">PDF</a>]
158 <br>
159 <br>
160 </li>
161
162 <li>
163 C.F. Brædstrup, <strong>A. Damsgaard</strong>, and D.L. Egholm
164 2014
165 <a href="https://doi.org/10.1016/j.cageo.2014.07.019">
166 "Ice-sheet modelling accelerated by graphics cards"</a>
167 Computers and Geosciences, vol. 72, 210-220
168 <br>
169 <br>
170 </li>
171
172 <li>
173 <strong>A. Damsgaard</strong>, D.L. Egholm, J.A. Piotrowski, S. Tulaczyk, N.K.
174 Larsen, and K. Tylmann
175 2013
176 <a href="https://doi.org/10.1002/2013JF002830">
177 "Discrete element modeling of subglacial sediment deformation"</a>
178 Journal of Geophysical Research: Earth Surface, vol. 118, 2230-2242
179 [<a href="papers/Damsgaard%20et%20al%202013%20Discrete%20element%20modeling%20of%20subglacial%20sediment%20deformation.pdf">PDF</a>]
180 </li>
181 </ul>