Publications

[50] Hwang, S.-H.;  Seo, S.-D.;  Yeo, H.; Kim, D.-W., Harnessing reaction kinetics for wet chemical synthesis of Li-Si-Sb-SI quinary Li-argyrodite solid electrolytes. Chemical Engineering Journal 2026, 527, 171835.

[49] Park, Y.;  Shim, Y.;  Lee, J.;  Park, H.;  Seo, S.-D.;  Oh, G.;  Yuk, J. M.;  Lee, C.-W.;  Pin, M.; Nam, K.-W., Impacts of site-selective oxygen introduction on structural stabilization, moisture stability, and battery performance in sulfide-based argyrodite. Energy Storage Materials 2025, 75, 104078.

[48] Park, Y.;  Lee, S. Y.;  Kim, H. Y.;  Jang, M.;  Ko, S.;  Oh, G.;  Seo, S. D.;  You, M. J.;  Kim, H.; Pin, M., Boosting the Power Characteristics of All‐Solid‐State Batteries Through Improved Electrochemical Stability: Site‐Specific Nb Doping in Argyrodite. Carbon Energy 2025, 7 (11), e70058.

[47] Park, Y.;  Jang, M.;  Kim, J.;  Chang, J. H.;  Kim, H.-Y.;  Seo, S.-D.;  Oh, G.;  You, M. J.;  Ko, S.; Kim, J. H., Oxygen-induced lithium inter-cage conduction for enhanced performance in all-solid-state batteries. eScience 2025, 100502.

[46] Kim, D.;  Hwang, S.-H.;  Seo, S.-D.;  Yeo, H.; Kim, D.-W., Size-regulated Li-argyrodite particles via wet-chemical route for enhanced solid-state battery performance. Chemical Engineering Journal 2025, 509, 161415.

[45] Hwang, S.-H.;  Seo, S.-D.;  Kim, D.;  Park, J. B.;  Kim, S.-C.; Kim, D.-W., Expediting solid electrolyte synthesis: Microwave-assisted wet synthesis of halogen-rich Li-argyrodite. Journal of Energy Chemistry 2025, 104, 527-539.

[44] Hwang, S.-H.;  Seo, S.-D.; Kim, D.-W., A Novel Time-Saving Synthesis Approach for Li-Argyrodite Superionic Conductor. Advanced Science 2023, 10 (22), 2301707.

[43] Hwang, S.-H.;  Seo, S.-D.; Kim, D.-W., Metal–organic-framework-derived vanadium (iii) phosphate nanoaggregates for zinc-ion battery cathodes with long-term cycle stability. Journal of Materials Chemistry A 2022, 10 (19), 10638-10650.

[42] Heo, Y. J.;  Seo, S. D.;  Hwang, S. H.;  Choi, S. H.; Kim, D. W., One‐pot aprotic solvent‐enabled synthesis of superionic Li‐argyrodite solid electrolyte. International Journal of Energy Research 2022, 46 (12), 17644-17653.

[41] Lee, D. Y.;  Seo, S. D.;  Song, H. J.; Kim, D. W., Free‐standing molybdenum disulfides on porous carbon cloth for lithium‐ion battery anodes. International Journal of Energy Research 2021, 45 (7), 11329-11337.

[40] Seo, S.-D.;  Choi, C.;  Park, D.;  Lee, D.-Y.;  Park, S.; Kim, D.-W., Metal-organic-framework-derived 3D crumpled carbon nanosheets with self-assembled CoxSy nanocatalysts as an interlayer for lithium-sulfur batteries. Chemical Engineering Journal 2020, 400, 125959.

[39] Seo, S. D.;  Yu, S.;  Park, S.; Kim, D. W., In Situ Conversion of Metal–Organic Frameworks into VO2–V3S4 Heterocatalyst Embedded Layered Porous Carbon as an “All‐in‐One” Host for Lithium–Sulfur Batteries. Small 2020, 16 (47), 2004806.

[38] Seo, S. D.;  Park, D.;  Park, S.; Kim, D. W., “Brain‐coral‐like” mesoporous hollow CoS2@ N‐doped graphitic carbon nanoshells as efficient sulfur reservoirs for lithium–sulfur batteries. Advanced Functional Materials 2019, 29 (38), 1903712.

[37] Lee, J.-W.;  Seo, S.-D.; Kim, D.-W., Comparative study on ternary spinel cathode Zn–Mn–O microspheres for aqueous rechargeable zinc-ion batteries. Journal of Alloys and Compounds 2019, 800, 478-482.

[36] Lee, J. W.;  Seo, S. D.; Kim, D. W., Hierarchical Zn1. 67Mn1. 33O4/graphene nanoaggregates as new anode material for lithium‐ion batteries. International Journal of Energy Research 2019, 43 (5), 1735-1746.

[35] Seo, S.-D.;  Choi, C.;  Kim, B.-K.; Kim, D.-W., Fabrication of highly porous carbon as sulfur hosts using waste green tea bag powder for lithium–sulfur batteries. Ceramics International 2017, 43 (2), 2836-2841.

[34] Yi, Y.;  Shim, H.-W.;  Seo, S.-D.;  Dar, M. A.; Kim, D.-W., Enhanced Li-and Na-storage in Sb-graphene nanocomposite anodes. Materials Research Bulletin 2016, 76, 338-343.

[33] Seo, S.-D.;  Lee, G.-H.; Kim, D.-W., Three-dimensional hybrid tin oxide/carbon nanowire arrays for high-performance Li ion battery electrodes. Journal of Nanoscience and Nanotechnology 2016, 16 (10), 10588-10591.

[32] Seo, S.-D.;  Choi, C.; Kim, D.-W., Fabrication of sulfur-impregnated porous carbon nanostructured electrodes via dual-mode activation for lithium–sulfur batteries. Materials Letters 2016, 172, 116-119.

[31] Choi, C.;  Seo, S.-D.;  Kim, B.-K.; Kim, D.-W., Enhanced lithium storage in hierarchically porous carbon derived from waste tea leaves. Scientific reports 2016, 6 (1), 39099.

[30] Lee, C. W.;  Seo, S.-D.;  Park, H. K.;  Park, S.;  Song, H. J.;  Kim, D.-W.; Hong, K. S., High-areal-capacity lithium storage of the Kirkendall effect-driven hollow hierarchical NiS x nanoarchitecture. Nanoscale 2015, 7 (6), 2790-2796.

[29] Choi, C.;  Seo, S.-D.;  Shim, H.-W.;  Dar, M. A.;  Cho, I. S.; Kim, D.-W., Facile synthesis and electroactivity of 3-D hierarchically superstructured cobalt orthophosphate for lithium-ion batteries. Journal of Alloys and Compounds 2015, 652, 100-105.

[28] Seo, S.-D.;  Lee, G.-H.; Kim, D.-W., Enhanced electroactivity with Li in Fe3O4/MWCNT nanocomposite electrodes. Journal of alloys and compounds 2014, 615, S397-S400.

[27] Seo, S. D.;  Lee, D. H.;  Shim, H. W.;  Lee, S.; Kim, D. W., Enhanced Cycle Stability of Magnetite/Carbon Nanoparticles for Li Ion Battery Electrodes. Journal of the American Ceramic Society 2014, 97 (5), 1413-1420.

[26] Park, S.;  Seo, S.-D.;  Kim, H. J.;  Lee, C. W.;  Song, H. J.;  Shin, S. S.;  Park, H. K.;  Hong, K. S.; Kim, D.-W., Three-dimensional hierarchical Li4Ti5O12 nanoarchitecture by a simple hydrothermal method. Journal of Nanoscience and Nanotechnology 2014, 14 (12), 9307-9312.

[25] Lee, G. H.;  Kim, J. C.;  Lee, D. H.;  Seo, S. D.;  Shim, H. W.; Kim, D. W., Synthesis of Multiphase Cu3Ge/GeOx/CuGeO3 Nanowires for Use as Lithium‐Ion Battery Anodes. ChemElectroChem 2014, 1 (3), 673-678.

[24] Lee, D.-H.;  Seo, S.-D.;  Lee, G.-H.;  Hong, H.-S.; Kim, D.-W., One-pot synthesis of Fe3O4/Fe/MWCNT nanocomposites via electrical wire pulse for Li ion battery electrodes. Journal of alloys and compounds 2014, 606, 204-207.

[23] Shim, H.-W.;  Lim, A.-H.;  Kim, J.-C.;  Jang, E.;  Seo, S.-D.;  Lee, G.-H.;  Kim, T. D.; Kim, D.-W., Scalable one-pot bacteria-templating synthesis route toward hierarchical, porous-Co3O4 superstructures for supercapacitor electrodes. Scientific reports 2013, 3 (1), 2325.

[22] Seo, S.-D.;  Lee, D.-H.;  Kim, J.-C.;  Lee, G.-H.; Kim, D.-W., Room-temperature synthesis of CuO/graphene nanocomposite electrodes for high lithium storage capacity. Ceramics International 2013, 39 (2), 1749-1755.

[21] Park, S.;  Lee, S.;  Seo, S. W.;  Seo, S.-D.;  Lee, C. W.;  Kim, D.;  Kim, D.-W.; Hong, K. S., Tailoring nanobranches in three-dimensional hierarchical rutile heterostructures: a case study of TiO 2–SnO 2. CrystEngComm 2013, 15 (15), 2939-2948.

[20] Park, K.-S.;  Min, K.-M.;  Seo, S.-D.;  Lee, G.-H.;  Shim, H.-W.; Kim, D.-W., Self-supported multi-walled carbon nanotube-embedded silicon nanoparticle films for anodes of Li-ion batteries. Materials Research Bulletin 2013, 48 (4), 1732-1736.

[19] Lee, C. W.;  Seo, S.-D.;  Kim, D. W.;  Park, S.;  Jin, K.;  Kim, D.-W.; Hong, K. S., Heteroepitaxial growth of ZnO nanosheet bands on ZnCo2O4 submicron rods toward high-performance Li ion battery electrodes. Nano Research 2013, 6 (5), 348-355.

[18] Kim, J.-C.;  Hwang, I.-S.;  Seo, S.-D.; Kim, D.-W., Nanocomposite Li-ion battery anodes consisting of multiwalled carbon nanotubes that anchor CoO nanoparticles. Materials Letters 2013, 104, 13-16.

[17] Seo, S.-D.;  Lee, G.-H.;  Lim, A.-H.;  Min, K.-M.;  Kim, J.-C.;  Shim, H.-W.;  Park, K.-S.; Kim, D.-W., Direct assembly of tin–MWCNT 3D-networked anode for rechargeable lithium ion batteries. RSC Advances 2012, 2 (8), 3315-3320.

[16] Seo, S.-D.;  Hwang, I.-S.;  Lee, S.-H.;  Shim, H.-W.; Kim, D.-W., 1D/2D carbon nanotube/graphene nanosheet composite anodes fabricated using electrophoretic assembly. Ceramics International 2012, 38 (4), 3017-3021.

[15] Park, S.;  Seo, S.-D.;  Lee, S.;  Seo, S. W.;  Park, K.-S.;  Lee, C. W.;  Kim, D.-W.; Hong, K. S., Sb: SnO2@ TiO2 heteroepitaxial branched nanoarchitectures for Li ion battery electrodes. The Journal of Physical Chemistry C 2012, 116 (41), 21717-21726.

[14] Park, K.-S.;  Seo, S.-D.;  Shim, H.-W.; Kim, D.-W., Electrochemical performance of Ni x Co1-x MoO4 (0≤ x≤ 1) nanowire anodes for lithium-ion batteries. Nanoscale research letters 2012, 7 (1), 35.

[13] Park, K.-S.;  Min, K.-M.;  Jin, Y.-H.;  Seo, S.-D.;  Lee, G.-H.;  Shim, H.-W.; Kim, D.-W., Enhancement of cyclability of urchin-like rutile TiO 2 submicron spheres by nanopainting with carbon. Journal of Materials Chemistry 2012, 22 (31), 15981-15986.

[12] Lim, A.-H.;  Shim, H.-W.;  Seo, S.-D.;  Lee, G.-H.;  Park, K.-S.; Kim, D.-W., Biomineralized Sn-based multiphasic nanostructures for Li-ion battery electrodes. Nanoscale 2012, 4 (15), 4694-4701.

[11] Lee, S.-H.;  Seo, S.-D.;  Park, K.-S.;  Shim, H.-W.; Kim, D.-W., Synthesis of graphene nanosheets by the electrolytic exfoliation of graphite and their direct assembly for lithium ion battery anodes. Materials Chemistry and Physics 2012, 135 (2-3), 309-316.

[10] Lee, G.-H.;  Seo, S.-D.;  Shim, H.-W.;  Park, K.-S.; Kim, D.-W., Synthesis and Li electroactivity of Fe2P2O7 microspheres composed of self-assembled nanorods. Ceramics International 2012, 38 (8), 6927-6930.

[9] Kim, J.-C.;  Hwang, I.-S.;  Seo, S.-D.;  Lee, G.-H.;  Shim, H.-W.;  Park, K.-S.; Kim, D.-W., Superior long-term cycling stability of SnO2 nanoparticle/multiwalled carbon nanotube heterostructured electrodes for Li-ion rechargeable batteries. Nanotechnology 2012, 23 (46), 465402.

[8] Jin, Y.-H.;  Seo, S.-D.;  Shim, H.-W.;  Park, K.-S.; Kim, D.-W., Synthesis of core/shell spinel ferrite/carbon nanoparticles with enhanced cycling stability for lithium ion battery anodes. Nanotechnology 2012, 23 (12), 125402.

[7] Jin, Y.-H.;  Min, K.-M.;  Shim, H.-W.;  Seo, S.-D.;  Hwang, I.-S.;  Park, K.-S.; Kim, D.-W., Facile synthesis of nano-Li4 Ti5O12 for high-rate Li-ion battery anodes. Nanoscale research letters 2012, 7 (1), 10.

[6] Hwang, I.-S.;  Kim, J.-C.;  Seo, S.-D.;  Lee, S.;  Lee, J.-H.; Kim, D.-W., A binder-free Ge-nanoparticle anode assembled on multiwalled carbon nanotube networks for Li-ion batteries. Chemical communications 2012, 48 (56), 7061-7063.

[5] Shim, H.-W.;  Jin, Y.-H.;  Seo, S.-D.;  Lee, S.-H.; Kim, D.-W., Highly reversible lithium storage in Bacillus subtilis-directed porous Co3O4 nanostructures. ACS nano 2011, 5 (1), 443-449.

[4] Seo, S.-D.;  Jin, Y.-H.;  Lee, S.-H.;  Shim, H.-W.; Kim, D.-W., Low-temperature synthesis of CuO-interlaced nanodiscs for lithium ion battery electrodes. Nanoscale research letters 2011, 6 (1), 397.

[3] Park, K.-S.;  Seo, S.-D.;  Jin, Y.-H.;  Lee, S.-H.;  Shim, H.-W.;  Lee, D.-H.; Kim, D.-W., Synthesis of cuprous oxide nanocomposite electrodes by room-temperature chemical partial reduction. Dalton Transactions 2011, 40 (37), 9498-9503.

[2] Jin, Y.-H.;  Min, K.-M.;  Seo, S.-D.;  Shim, H.-W.; Kim, D.-W., Enhanced Li storage capacity in 3 nm diameter SnO2 nanocrystals firmly anchored on multiwalled carbon nanotubes. The Journal of Physical Chemistry C 2011, 115 (44), 22062-22067.

[1] Lee, S.-H.;  Seo, S.-D.;  Jin, Y.-H.;  Shim, H.-W.; Kim, D.-W., A graphite foil electrode covered with electrochemically exfoliated graphene nanosheets. Electrochemistry communications 2010, 12 (10), 1419-1422.