54 Gao, Y. R., J. Huang, J. Cheng and S. H. Bo (2023). “Correlate phonon modes with ion transport via isotope substitution.” Science China Chemistry. 66: 768-777.
53 Sun, Z. T., J. Zhou, Y. Wu and S. H. Bo (2022). “Mapping and modeling physicochemical fields in solid-state batteries. ” Journal of Physical Chemistry Letter 13: 10816-10822.
52 Wu, Y. and S. H. Bo (2022). “Interfacial behavior of a thio-LISICON solid-state electrolyte under external pressure. ” ACS Applied Energy Materials 5(11): 13571–13579
51 Tang, B., X. Yu, Y. Gao, S. H. Bo and Z. Zhou (2022).  “Positioning solid-state sodium batteries in future transportation and energy storage. ” Science Bulletin 67(21): 2149-2153.
50 Li, P., Z. T. Sun, Y Wang, R Razaq, Y. Gao and S. H. Bo (2022).  “Overpotential-Regulated stable cycling of a thin magnesium metal anode. ” ACS Applied Materials & Interfaces 14(27):31435-31447.
49 Zhou, J., Y. Zhao, H. Liu, X. Tang, S.-L. Chen and S. H. Bo (2022). “Rapid 3D nondestructive imaging technology for batteries: Photoacoustic microscopy.” Journal of Materials Research: 1-14.
48 Gao, Y., T. P. Mishra, S. H. Bo and P. Canepa (2022). “Design and Characterization of host frameworks for facile magnesium transport.” Annual Review of Materials Research 52(1).
47 Hu, J., Z. T. Sun, Y. Gao and S. H. Bo (2022). “3D stress mapping reveals the origin of lithium-deposition heterogeneity in solid-state lithium-metal batteries.” Cell Reports Physical Science 3: 100938.
46 Sun, Z. T. and S. H. Bo (2022). “Understanding electro-mechanical-thermal coupling in solid-state lithium metal batteries via phase-field modeling.” Journal of Materials Research: 1-16.
45 Zhou, J, J. Zhou, W. Wang, S. Liang, L. Jing, S. H. Bo and S. L. Chen (2021). “Miniature non-contact photoacoustic probe based on fiber-optic photoacoustic remote sensing microscopy.” Optical letters 46(22): 5767-5770.
44 Tang, B, Y. Zhao, Z. Wang, S. Chen, Y. Wu, Y. Tseng, L. Li, Y. Guo, Z. Zhou and S. H. Bo (2021). “Ultrathin salt-free polymer-in-ceramic electrolyte for solid-state sodium batteries.” eScience 1(2): 194-202.
43 Zhao, Y, Y. Wu, H. Liu, S.-L. Chen and S. H. Bo (2021). “Accelerated growth of electrically isolated lithium metal during battery cycling.” ACS Applied Materials & Interfaces 13(30): 35750-35758.
42 Gao, Y., N. Li, Y. Wu, W. Yang and S. H. Bo (2021). “Rethinking the design of ionic conductors using Meyer–Neldel–conductivity plot.” Advanced Energy Materials. 11(13).
41 Wu, Y., Z. Xu, Y. Liu, J. Chen, L. Peng, O. J. Borkiewicz, H. Zhu, S. H. Bo and Y. Xia (2021). “Electronic structure of anode material Li2TiSiO5 and its structural evolution during lithiation.” The Journal of Physical Chemistry C 125(7): 3733-3744.
40 Razaq, R., P. Li, Y. Dong, Y. Li, Y. Mao and S. H. Bo (2020). “Practical energy densities, cost, and technical challenges for magnesium-sulfur batteries.” EcoMat 2(4).
39 Tang, B., P. W. Jaschin, X. Li, S. H. Bo and Z. Zhou (2020). “Critical interface between inorganic solid-state electrolyte and sodium metal.” Materials Today 41: 200-218.
38 Wu, Y. F., S. H. Bo and Y. Y. Xia (2020). “Solid-electrolyte interphase formation process on Li2TiSiO5 anode in LiPF6-based carbonate electrolyte.” Journal of Power Sources 467.
37 Mei, X., Y. Wu, Y. Gao, Y. Zhu, S. H. Bo and Y. Guo (2020). “A quantitative correlation between macromolecular crystallinity and ionic conductivity in polymer-ceramic composite solid electrolytes.” Materials Today Communications 24.
36 Kim, J. C., D. H. Kwon, J. H. Yang, H. Kim, S. H. Bo, L. J. Wu, H. Kim, D. H. Seo, T. Shi, J. Y. Wang, Y. M. Zhu and G. Ceder (2020). “Direct observation of alternating octahedral and prismatic sodium layers in O3-Type transition metal oxides.” Advanced Energy Materials 10(31).
35 Gao, Y. R., A. M. Nolan, P. Du, Y. F. Wu, C. Yang, Q. L. Chen, Y. F. Mo and S. H. Bo (2020). “Classical and emerging characterization techniques for investigation of ion transport mechanisms in crystalline fast ionic conductors.” Chemical Reviews 120(13): 5954-6008.
34 Li, P., Y. Zhao, Y. Shen and S. H. Bo (2020) . “Fracture behavior in battery materials.” Journal of Physics: Energy 2(2): 022002
33 Jaschin, P. W., Y. Gao, Y. Li and S. H. Bo (2020). “A materials perspective on magnesium-ion-based solid-state electrolytes.” Journal of Materials Chemistry A 8(6): 2875-2897.
32 Liu, H. H., Y. B. Zhao, J. S. Zhou, P. Li, S. H. Bo and S. L. Chen (2020). “Photoacoustic imaging of lithium metal batteries.” ACS Applied Energy Materials 3(2): 1260-1264.
31 Xiao, Y. H., Y. Wang, S. H. Bo, J. C. Kim, L. J. Miara and G. Ceder (2020). “Understanding interface stability in solid-state batteries.” Nature Reviews Materials 5(2): 105-126.
30 Tian, Y. S., Y. Z. Sun, D. C. Hannah, Y. H. Xiao, H. Liu, K. W. Chapman, S. H. Bo and G. Ceder (2019). “Reactivity-Guided interface design in Na metal solid-state batteries.” Joule 3(4): 1037-1050.
29 Lacivita, V., Y. Wang, S. H. Bo and G. Ceder (2019). “Ab-initio investigation of the stability of electrolyte/electrode interfaces in all-solid-state Na batteries.” Journal of Materials Chemistry A 7(14): 8144-8155.
28 Shi, T., P. H. Xiao, D. H. Kwon, G. S. Gautam, K. Chakarawet, H. Kim, S. H. Bo and G. Ceder (2018). “Shear-Assisted formation of cation-disordered rocksalt NaMO2 (M = Fe or Mn).” Chemistry of Materials 30(24): 8811-8821.
27 Xu, Z. M., S. H. Bo and H. Zhu (2018). “LiCrS2 and LiMnS2 cathodes with extraordinary mixed electron-ion conductivities and favorable interfacial compatibilities with sulfide electrolyte.” ACS Applied Materials & Interfaces 10(43): 36941-36953.
26 Liu, Y., J. Y. Liu, Y. F. Wu, D. Bin, S. H. Bo, Y. G. Wang and Y. Y. Xia (2018). “Na1.68H0.32Ti2O3SiO4 ·1.76H2O as a low-potential anode material for sodium-ion battery.” ACS Applied Energy Materials 1(10): 5151-5157.
25 Kim, H., D. H. Seo, A. Urban, J. Lee, D. H. Kwon, S. H. Bo, T. Shi, J. K. Papp, B. D. McCloskey and G. Ceder (2018). “Stoichiometric layered potassium transition metal oxide for rechargeable potassium batteries.” Chemistry of Materials 30(18): 6532-6539.
24 Canepa, P., G. S. Gautam, D. Broberg, S. H. Bo and G. Ceder (2017). “Role of point defects in spinel Mg chalcogenide conductors.” Chemistry of Materials 29(22): 9657-9667.
23 Canepa, P., S. H. Bo, G. S. Gautam, B. Key, W. D. Richards, T. Shi, Y. S. Tian, Y. Wang, J. C. Li and G. Ceder (2017). “High magnesium mobility in ternary spinel chalcogenides.” Nature Communications 8.
22 Kim, H., D. H. Seo, J. C. Kim, S. H. Bo, L. Liu, T. Shi and G. Ceder (2017). “Investigation of potassium storage in layered P3-Type K0.5MnO2 cathode.” Advanced Materials 29(37).
21 Gautam, G. S., P. Canepa, A. Urban, S. H. Bo and G. Ceder (2017). “Influence of inversion on Mg mobility and electrochemistry in spinels.” Chemistry of Materials 29(18): 7918-7930.
20 Wang, Y., W. D. Richards, S. H. Bo, L. J. Miara and G. Ceder (2017). “Computational prediction and evaluation of solid-state sodium superionic conductors Na7P3X11 (X=0, 5, Se).” Chemistry of Materials 29(17): 7475-7482.
19 Kim, H., J. C. Kim, S. H. Bo, T. Shi, D. H. Kwon and G. Ceder (2017). “K-Ion batteries based on a P2-Type K0.6CoO2 cathode.” Advanced Energy Materials 7(17).
Before joining JI (2017)
18 Liu, J., P. S. Whitfield, M. R. Saccomanno, S. H. Bo, E. Y. Hu, X. Q. Yu, J. M. Bai, C. P. Grey, X. Q. Yang and P. G. Khalifah (2017). “In situ neutron diffraction studies of the ion exchange synthesis mechanism of Li2Mg2P3O9N: evidence for a hidden phase transition.” Journal of the American Chemical Society 139(27): 9192-9202.
17 Glass, H. F. J., Z. Liu, P. M. Bayley, E. Suard, S. H. Bo, P. G. Khalifah, C. P. Grey and S. E. Dutton (2017). “MgxMn2-xB2O5 pyroborates (2/3 <= x <= 4/3): high capacity and high rate cathodes for Li-ion batteries.” Chemistry of Materials 29(7): 3118-3125.
16 Tian, Y. S., T. Shi, W. D. Richards, J. C. Li, J. C. Kim, S. H. Bo and G. Ceder (2017). “Compatibility issues between electrodes and electrolytes in solid-state batteries.” Energy & Environmental Science 10(5): 1150-1166. 
15 Li, X., Y. Wang, D. Wu, L. Liu, S. H. Bo and G. Ceder (2016). “Jahn-Teller assisted Na diffusion for high performance Na ion batteries.” Chemistry of Materials 28(18): 6575-6583.
14 Bo, S. H., X. Li, A. J. Toumar and G. Ceder (2016). “Layered-to-Rock-Salt transformation in desodiated NaxCrO2 (x 0.4).” Chemistry of Materials 28(5): 1419-1429.
13 Bo, S. H., Y. Wang, J. C. Kim, W. D. Richards and G. Ceder (2016). “Computational and experimental investigations of Na-ion conduction in cubic Na3PSe4.” Chemistry of Materials 28(1): 252-258.
12 Bo, S. H., Y. Wang and G. Ceder (2016). “Structural and Na-ion conduction characteristics of Na3PSxSe4-x.” Journal of Materials Chemistry A 4(23): 9044-9053.
11 Liu, L., X. Li, S. H. Bo, Y. Wang, H. L. Chen, N. Twu, D. Wu and G. Ceder (2015). “High-Performance P2-Type Na-2/3(Mn1/2Fe1/4Co1/4)O-2 cathode material with superior rate capability for Na-ion batteries.” Advanced Energy Materials 5(22).
10 Wang, R., X. Li, L. Liu, J. Lee, D. H. Seo, S. H. Bo, A. Urban and G. Ceder (2015). “A disordered rock-salt Li-excess cathode material with high capacity and substantial oxygen redox activity: Li1.25Nb0.25Mn0.5O2.” Electrochemistry Communications 60: 70-73.
9 Bo, S. H., C. P. Grey and P. G. Khalifah (2015). “Defect-Tolerant diffusion channels for Mg2+ ions in Ribbon-type borates: structural insights into potential battery cathodes MgVBO4 and MgxFe2-xB2O5.” Chemistry of Materials 27(13): 4630-4639.
8 Ma, J., S. H. Bo, L. J. Wu, Y. M. Zhu, C. P. Grey and P. G. Khalifah (2015). “Ordered and disordered polymorphs of Na(Ni2/3Sb1/3)O-2: honeycomb-ordered cathodes for Na-ion batteries.” Chemistry of Materials 27(7): 2387-2399.
7 Bo, S. H., G. M. Veith, M. R. Saccomanno, H. F. Huang, P. V. Burmistrova, A. C. Malingowski, R. L. Sacci, K. R. Kittilstved, C. P. Grey and P. G. Khalifah (2014). “Thin-film and bulk investigations of LiCoBO3 as a Li-ion battery cathode.” ACS Applied Materials & Interfaces 6(14): 10840-10848.
6 Kim, J. C., X. Li, C. J. Moore, S. H. Bo, P. G. Khalifah, C. P. Grey and G. Ceder (2014). “Analysis of charged state stability for monoclinic LiMnBO3 cathode.” Chemistry of Materials 26(14): 4200-4206.
5 Bo, S. H., K. W. Nam, O. J. Borkiewicz, Y. Y. Hu, X. Q. Yang, P. J. Chupas, K. W. Chapman, L. J. Wu, L. Zhang, F. Wang, C. P. Grey and P. G. Khalifah (2014). “Structures of delithiated and degraded LiFeBO3, and their distinct changes upon electrochemical cycling.” Inorganic Chemistry 53(13): 6585-6595.
4 Janssen, Y., D. S. Middlemiss, S. H. Bo, C. P. Grey and P. G. Khalifah (2012). “Structural modulation in the high capacity battery cathode material LiFeBO3.” Journal of the American Chemical Society 134(30): 12516-12527.
3 Bo, S. H., F. Wang, Y. Janssen, D. L. Zeng, K. W. Nam, W. Q. Xu, L. S. Du, J. Graetz, X. Q. Yang, Y. M. Zhu, J. B. Parise, C. P. Grey and P. G. Khalifah (2012). “Degradation and (de)lithiation processes in the high capacity battery material LiFeBO.” Journal of Materials Chemistry 22(18): 8799-8809.
2 Xiong, H. M., W. Z. Shen, B. K. Guo, S. H. Bo, W. J. Cui, L. Q. Chen, H. Li and Y. Y. Xia (2011). “Anomalous lithium storage in a novel nanonet composed by SnO2 nanoparticles and poly(ethylene glycol) chains.” Journal of Materials Chemistry 21(9): 2845-2847.
1 Liu, H. J., S. H. Bo, W. J. Cui, F. Li, C. X. Wang and Y. Y. Xia (2008). “Nano-sized cobalt oxide/mesoporous carbon sphere composites as negative electrode material for lithium-ion batteries.” Electrochimica Acta 53(22): 6497-6503.