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<img width="220" height="220" align="left" src="figures/tan2.jpg"

alt="譚諤 助研究員" /> 　(中文版 / <a href="index.html" target="_top">English

Version</a>)<br />

<strong>　譚　諤　</strong>副研究員<br />

<br />

　TEL：+886-2-2783-9910 ext. 1503<br />

　FAX：+886-2-2783-9871<br />

　E-mail：<a href="mailto:[email protected]">[email protected]</a><br />

<br />

　研究領域：地球動力學、地球物理學、高速平行計算<br />

<br />

　<a href="research.html" target="_top">研究項目</a> <br />

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<strong>［學　歷］</strong>

<ul>

<li>2006 : 美國加州理工學院 地質及行星科學系 博士</li>

<li>1997 : 國立台灣大學 物理系 學士</li>

</ul>

<br />

<strong>［經　歷］</strong>

<ul>

<li>2020/04 - 現今 : 中央研究院 地球科學研究所, 副研究員</li>

<li>2012/07 - 2020/04 : 中央研究院 地球科學研究所, 助研究員</li>

<li>2012/02 - 2012/03 : 沙烏地阿拉伯阿布杜拉國王科技大學, Earth Science and

Engineering Program, 訪問學者<br />

</li>

<li>2010/02 - 2012/01 : 美國德州大學奧斯汀分校, Institute for Geophysics,

博士後研究<br />

</li>

<li>2006/07 - 2010/01 : 美國加州理工學院, Computational Infrastructure

for Geodynamics, Staff Scientist <br />

</li>

</ul>

<br />

<br />

<strong>［著　作］</strong><br />

<br />

  <strong>期刊論文：<br />

</strong>

<ol>

<li>Ho, A., Shyu, J. B. H., <u>Tan, E.</u>, Ferrier, K. L. (2026). Estimating tectonic coastal uplift requires accounting for sea-level variations caused by rapid sediment redistribution. <em>Communications Earth & Environment</em>. doi:10.1038/s43247-026-03302-8.

(<a href="https://doi.org/10.1038/s43247-026-03302-8)">Link</a>)

<li>Hu, W.-L., <u>Tan, E.</u>, Okuwaki, R., Yagi, Y. (2025). Intraslab stress heterogeneity and continental mantle faulting revealed by the 2006 Pingtung offshore earthquake doublet. <em>Communications Earth & Environment</em>, 6(1), 726. doi:10.1038/s43247-025-02719-x. (<a href="https://doi.org/10.1038/s43247-025-02719-x">Link</a>)

<li>Chen, K.-X., Kuo, B.-Y., Lin, T.-J., Lin, P.-Y. P., Gung, Y., <u>Tan, E.</u>, et al. (2024). Shear-Dominant Continental Rifting in Northern Ryukyu Revealed by Ambient Noise Tomography. <em>J. Geophys. Res.</em>, 129(11), e2024JB029448. doi:10.1029/2024JB029448.

(<a href="https://agupubs.onlinelibrary.wiley.com/doi/10.1029/2024JB029448">Link</a>)

</li>

<li><u>Tan, E.</u>, Y.-H. Lee, J.-B. Chang, M.-J. Zheng, C. J. Shyu (2024)

Mountain building process of the Taiwan orogeny, <em>Sci. Adv.</em>,

10, eadp8056, doi:10.1126/sciadv.adp8056.

(<a href="https://www.science.org/doi/10.1126/sciadv.adp8056">Link</a>)</li>

<li>Lee, F.-Y., <u>Tan, E.</u>, Chang, E. T.-Y. (2024). Escape Mechanism with Shallow Ramp and Décollements in Southwest Taiwan. <em>Geosciences</em>, 13(2), 41. doi:10.3390/geosciences13020041 (<a href="https://www.mdpi.com/2076-3263/13/2/41">Link</a>)<br />

</li>

<li>Shyu, C. J., <u>E. Tan</u>, L. A. Kirstein, F. M. Stuart, Y.-G. Chen (2023). The Exhumation History of the Middle Hsuehshan Range, Taiwan, as Revealed by Zircon Thermochronological Modeling, <em>Tectonophysics</em>, 860, 229907, doi:10.1016/j.tecto.2023.229907. (<a href="https://doi.org/10.1016/j.tecto.2023.229907">Link</a>)<br />

</li>

<li>Kuo, L.-W., Sone, H., Luzin, V., Yeh, E.-C., Hsu, Y.-J., and <u>Tan, E.</u> (2022), Gouge fabrics reset by thermal pressurization record stress on faults after earthquakes, <em>Geology</em>, 50, 1033-1037. doi:10.1130/G50217.1. (<a href="https://pubs.geoscienceworld.org/gsa/geology/article/50/9/1033/614061/Gouge-fabrics-reset-by-thermal-pressurization">Link</a>)<br />

</li>

<li>Peng, C.-C., Kuo, B.-Y., and <u>Tan, E.</u> (2021). Dual structure of poloidal and toroidal flow under the Cocos subduction zone, <em>Earth Planet. Sci. Lett.</em>, 565, 116911. doi:10.1016/j.epsl.2021.116911. (<a href="https://www.sciencedirect.com/science/article/pii/S0012821X21001709">Link</a>)<br />

</li>

<li><u>Tan, E.</u> (2020), Subduction of transitional crust at the

Manila Trench and its geophysical implications, <em>J. Asian Earth Sci.</em>,

187, 104100, doi:10.1016/j.jseaes.2019.104100. (<a href="https://www.sciencedirect.com/science/article/pii/S1367912019304523">Link</a>)<br />

</li>

<li>Citron, R.I., M. Manga, and <u>E. Tan</u> (2018), A hybrid

origin of the Martian crustal dichotomy: Degree-1 convection

antipodal to a giant impact, <em>Earth Planet. Sci. Lett.</em>,

491, 58-86, doi:10.1016/j.epsl.2018.03.031. (<a href="https://www.sciencedirect.com/science/article/pii/S0012821X18301559">Link</a>)<br />

</li>

<li>Persaud, P., <u>E. Tan</u>, J. Contreras, and L. Lavier

(2017), A bottom-driven mechanism for distributed faulting in

the Gulf of California Rift, <em>Tectonophysics, </em>719-720,

51-65, doi:10.1016/j.tecto.2016.11.024. <a href="http://www.pnas.org/content/114/16/4078"></a>(<a

href="http://www.sciencedirect.com/science/article/pii/S004019511630542X">Link</a>)<br />

</li>

<li>Tan, E. (2017), The effects of mantle wedge serpentinization

on slab dips, <em>Terr. Atmos. Oceanic Sci.</em>, 28,

259-269, doi:10.3319/TAO.2016.09.21.01. (<a href="http://tao.cgu.org.tw/index.php/articles/archive/geophysics/item/1502-2016092101t">Link</a>)<br />

</li>

<li>Chang Y.Y., W.P. Hsieh, <u>E. Tan</u>, and J. Chen (2017),

Hydration-reduced lattice thermal conductivity of olivine in

Earth’s upper mantle, Proc. Natl. Acad. Sci. USA, 114,

4078-4081 doi:10.1073/pnas.1616216114. <a href="http://www.pnas.org/content/114/16/4078">(Link</a>)</li>

<li><span class="pb_authors">Logan, L.C., L.L. Lavier,

E. Choi, <u>E. Tan</u>, and G.A.

Catania (2016) Semi-brittle rheology and ice dynamics in

DynEarthSol3D, <em></em></span><em>Cryosphere</em>, 11,

117-132, doi:10.5194/tc-2016-88<span class="pb_toc_link">. (<a

href="http://www.the-cryosphere-discuss.net/tc-2016-88/">LINK</a>)</span></li>

<li>Ta, T., K. Choo, <u>E. Tan</u>, B. Jang, E. Choi (2015),

Accelerating DynEarthSol3D on tightly coupled CPU-GPU

heterogeneous processors, <em>Computers &amp; Geosciences</em>,

79, 27-37, doi:10.1016/j.cageo.2015.03.003. (<a href="http://www.sciencedirect.com/science/article/pii/S0098300415000527">Link</a>)<br />

</li>

<li>Choi, E., <u>E. Tan</u>, L.L. Lavier, and V.M. Calo (2013),

DynEarthSol2D: An efficient unstructured finite element method

to study long-term tectonic deformation, <em>J. Geophys. Res.</em>,

118, doi:10.1002/jgrb.50148. <a href="http://onlinelibrary.wiley.com/doi/10.1002/jgrb.50148/full">(Link</a>)<br />

</li>

<li>Burstedde, C., G. Stadler, A. Alisic, L.C. Wilcox, <u>E.

Tan</u>, M. Gurnis, and O. Ghattas (2013), Large-scale

adaptive mantle convection simulation, <em>Geophys. J. Int.</em>,

192, 889-906, doi:10.1093/gji/ggs070.<a href="http://gji.oxfordjournals.org/content/192/3/889">(Link</a>)

</li>

<li><u>Tan, E.</u>, L.L. Lavier, H.J.A. van Avendonk, and A.

Heuret (2012), The role of frictional strength on plate

coupling at the subduction interface, <em>Geochem. Geophys.

Geosyst., </em>13, Q10006, doi:10.1029/2012GC004214. (<a href="reprints/Tan-2012-The%20role%20of%20frictional%20strength%20on%20plate%20coupling.pdf">PDF</a>)

</li>

<li>DiCaprio, L., M. Gurnis, R.D. Mueller, and <u>E. Tan</u>

(2011), Mantle dynamics of continent-wide Cenozoic subsidence

and tilting of Australia, <em>Lithosphere</em>, 3, 311-316,

doi:10.1130/L140.1. (<a href="reprints/DiCaprio-2011-Mantle%20dynamics%20of%20continentwide%20Cenozoic.pdf">PDF</a>)<br />

</li>

<li><u>Tan, E.</u>, W. Leng, S. Zhong, and M. Gurnis (2011), On

the location of plumes and lateral movement of thermochemical

structures with high bulk modulus in the 3-D compressible

mantle, <em>Geochem. Geophys. Geosyst.</em>, 12, Q07005,

doi:10.1029/2011GC003665. (<a href="reprints/Tan-2011-On%20the%20location%20of%20plumes%20and%20lateral%20movement%20of.pdf">PDF</a>)</li>

<li>King, S.D., C. Lee, P.E. van Keken, W. Leng, S. Zhong, <u>E.

Tan</u>, N. Tosi, and M.C. Kameyama (2010), A Community

Benchmark for 2D Cartesian Compressible Convection in the

Earth’s Mantle, <em>Geophys. J. Int.</em>, 180, 73-87,

doi:10.1111/j.1365-246X.2009.04413.x. (<a href="reprints/King-2010-A%20community%20benchmark%20for%202-D%20Cartesian.pdf">PDF</a>)

</li>

<li>Helmberger, D., D. Sun, L. Liu, <u>E. Tan</u>, and M.

Gurnis (2009), Review of large low shear velocity provinces in

the lower mantle, <em>Geochim. Cosmochim. Ac.</em>, 73, A520.<br />

</li>

<li>Burstedde, C., O. Ghattas, M. Gurnis, G. Stadler, <u>E. Tan</u>,

T. Tu, L. C. Wilcox, and S. Zhong (2008), Scalable adaptive

mantle convection simulation on petascale supercomputers, <em>International

Conference for High Performance Computing, Networking,

Storage, and Analysis</em> (ACM/IEEE Supercomputing 2008),

15 pp, doi:10.1109/sc.2008.5214248. (<a href="reprints/Burstedde-2008-Scalable%20adaptive%20mantle%20convection%20simulation%20on.pdf">PDF</a>)

</li>

<li>Zhong, S., A. McNamara, <u>E. Tan</u>, L. Moresi, and M.

Gurnis (2008), A benchmark study on mantle convection in a 3-D

spherical shell using CitcomS,<em> Geochem., Geophys.,

Geosyst.</em>, 9, Q10017, doi:10.1029/2008GC002048. (<a href="reprints/Zhong-2008-A%20benchmark%20study%20on%20mantle%20convection%20in%20a%203-D.pdf">PDF</a>)

</li>

<li><u>Tan, E.</u>, and M. Gurnis (2007),  Compressible

thermochemical convection and application to lower mantle

structures, <em>J. Geophys. Res.</em>, 112, B06304,

doi:10.1029/2006JB004505. (<a href="reprints/Tan_Gurnis-2007-Compressible%20thermochemical%20convection%20and.pdf">PDF</a>)

</li>

<li><u>Tan, E.</u>, E. Choi, P. Thoutireddy, M. Gurnis, and M.

Aivazis (2006), GeoFramework: coupling multiple models of

mantle convection within a computational framework, <em>Geochem.

Geophys. Geosyst.</em>, 7, Q06001, doi:10.1029/2005GC001155.

(<a href="reprints/Tan-2006-GeoFramework.pdf">PDF</a>) </li>

<li><u>Tan, E.</u>, and M. Gurnis (2005), Metastable superplumes

and mantle compressibility, <em>Geophys. Res. Lett.</em>, 32,

L20307, doi:10.1029/2005GL024190. (<a href="reprints/Tan_Gurnis-2005-Metastable%20superplumes%20and%20mantle%20compressibility.pdf">PDF</a>)

</li>

<li><u>Tan, E.</u>, M. Gurnis, and L. Han (2002), Slabs in the

lower mantle and their modulation of plume formation, <em>Geochem.

Geophys. Geosyst.</em>, 3, 1067, doi:10.1029/2001GC000238. (<a

href="reprints/Tan-2002-Slabs%20in%20the%20lower%20mantle%20and%20their%20modulation%20of.pdf">PDF</a>)

</li>

<li>Ni, S., <u>E. Tan</u>, M. Gurnis, and D. Helmberger (2002),

Sharp sides to the African superplume, <em>Science</em>, 296,

1850-1852, doi:10.1126/science.1070698. (<a href="reprints/Ni-2002-Sharp%20Sides%20to%20the%20African%20Superplume.pdf">PDF</a>)

</li>

</ol>

<strong><br />

 專書及專書論文：</strong>

<ol>

<li>Gurnis, M., W. Landry, <u>E. Tan</u>, L. Armendariz, L.

Strand, and M. Aivazis (2010), Development, verification and

maintenance of computational software in geodynamics, in G. R.

Keller and C. Baru, eds., <em>Geoinformatics:

Cyberinfrastructure for the Solid Earth Sciences</em>,

Cambridge University Press, p49-p67, doi:10.1017/cbo9780511976308.006.<br />

</li>

<li><u>Tan, E.</u>, M. Gurnis, L. Armendariz, L. Strand, and S.

Kientz (2010), CitcomS User Manual, <a href="http://www.geodynamics.org/cig/software/citcoms/citcoms.pdf">http://www.geodynamics.org/cig/software/citcoms/citcoms.pdf</a>,

132 pp..</li>

<li><u>Tan, E.</u> (2006), I. Multi-scale dynamics of mantle

plumes and II. Compressible thermo-chemical convection and the

stability of  mantle superplumes, <em>Ph.D. Thesis</em>,

California Institute of Technology, 180 pp..<br />

</li>

</ol>

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