Publications

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13. Fabrication and growth mechanism of ultra-crystalline C 60 on silicon substrate in vacuum. H Wang, A Rath, SH Yu, MS Tan, SJ Pennycook, DHC Chua Carbon Letters, 1-8

12. Reversible Electrochemical Mirror Devices: A Quasi‐Solid‐State Tristate Reversible Electrochemical Mirror Device with Enhanced Stability. ALS Eh, J Chen, SH Yu, G Thangavel, X Zhou, G Cai, S Li, DHC Chua, Pooi See Lee. Advanced Science 7 (13), 2070073

11. A Quasi‐Solid‐State Tristate Reversible Electrochemical Mirror Device with Enhanced Stability. ALS Eh, J Chen, SH Yu, G Thangavel, X Zhou, G Cai, S Li, DHC Chua, Pooi See Lee. Advanced Science 7 (13), 1903198

10. Graphene-based free-standing bendable films: designs, fabrications, and applications. S Zhao, M Li, X Wu, SH Yu, W Zhang, J Luo, J Wang, Y Geng, Q Gou, K sun. Materials Today Advances 6, 100060

9. Engineering Sulfide-Phosphide Based Double Catalysts on 3D Nickel Phosphides Framework for Electrolytic Hydrogen Evolution: Activating Short-range Crystalline MoS2 with Ni5P4-Ni2P Template. SH Yu (First Author), W Chen, H Wang, D Haiwen, ZQC Ng, H Pan, DHC Chua Journal of The Electrochemical Society 167 (2), 026511

A Quasi‐Solid‐State Tristate Reversible Electrochemical Mirror Device with Enhanced Stability. [11]

Engineering Sulfide-Phosphide Based Double Catalysts on 3D Nickel Phosphides Framework for Electrolytic Hydrogen Evolution: Activating Short-range Crystalline MoS2 with Ni5P4-Ni2P Template [9]


  • 2019
    8. Engineering Hybridized Electrocatalysts for Electrolytic Hydrogen Evolution reaction. Yu Shu Hearn. NUS Thesis

7. In Situ Hybridizing MoS2 Microflowers on VS2 Microflakes in a One-Pot CVD Process for Electrolytic Hydrogen Evolution Reaction. SH Yu (First Author), Z Tang, Y Shao, H Dai, HY Wang, J Yan, H Pan, DHC Chua. ACS Applied Energy Materials 2 (8), 5799-5808

6. Study of unique and highly crystalline MoS2/MoO2 nanostructures for electrochemical applications. J Yan, A Rath, H Wang, SH Yu, SJ Pennycook, DHC Chua. Materials Research Letters 7 (7), 275-281

5. Highly stable tungsten disulfide supported on a self-standing nickel phosphide foam as a hybrid electrocatalyst for efficient electrolytic hydrogen evolution. SH Yu (First Author), W Chen, H Wang, H Pan, DHC Chua. Nano Energy 55, 193-202

In Situ Hybridizing MoS2 Microflowers on VS2 Microflakes in a One-Pot CVD Process for Electrolytic Hydrogen Evolution Reaction [7]

Study of unique and highly crystalline MoS2/MoO2 nanostructures for electrochemical applications. [6]


  • 2018
    4. One-Pot Synthesis of Co-Doped VSe2 Nanosheets for Enhanced Hydrogen Evolution Reaction. Q Zhu, M Shao, SH Yu, X Wang, Z Tang, B Chen, H Cheng, Z Lu, D Chua, Hui Pan. ACS Applied Energy Materials 2 (1), 644-653

3. Temperature-controlled vapor deposition of highly conductive p-type reduced molybdenum oxides by hydrogen reduction. H Dai, A Rath, SH Yu, SJ Pennycook, DHC Chua. The Journal of Physical Chemistry Letters 9 (24), 7185-7191

2. Synergistically Configuring Intrinsic Activity and Fin-Tube-Like Architecture of Mn-Doped MoS2-Based Catalyst for Improved Hydrogen Evolution Reaction. L Zhang, M Li, A Zou, SH Yu, T Xiong, L Wang, J He, Q Fu, DHC Chua, Junmin Xue. ACS Applied Energy Materials 2 (1), 493-502

1. Toward high-performance and low-cost hydrogen evolution reaction electrocatalysts: nanostructuring cobalt phosphide (CoP) particles on carbon fiber paper. SH Yu (First Author), DHC Chua ACS Applied Materials & Interfaces 10 (17), 14777-14785

Toward high-performance and low-cost hydrogen evolution reaction electrocatalysts: nanostructuring cobalt phosphide (CoP) particles on carbon fiber paper. [1]

Synergistically Configuring Intrinsic Activity and Fin-Tube-Like Architecture of Mn-Doped MoS2-Based Catalyst for Improved Hydrogen Evolution Reaction [2].