sj-docx-1-onc-10.1177_11795549221123620 – Supplemental material for Prognostic Values From Integrated Analysis of the Nomogram Based on RNA-Binding Proteins and Clinical Factors in Endometrial Cancer

Supplemental material, sj-docx-1-onc-10.1177_11795549221123620 for Prognostic Values From Integrated Analysis of the Nomogram Based on RNA-Binding Proteins and Clinical Factors in Endometrial Cancer by Shuang Yuan, Xiao Sun and Lihua Wang in Clinical Medicine Insights: Oncology</p

Integrating 3D Flower-Like Hierarchical Cu₂NiSnS₄ with Reduced Graphene Oxide as Advanced Anode Materials for Na-Ion Batteries

Development of an anode material with high performance and low cost is crucial for implementation of next-generation Na-ion batteries (NIBs) electrode, which is proposed to meet the challenges of large scale renewable energy storage. Metal chalcogenides are considered as promising anode materials for NIBs due to their high theoretical capacity, low cost, and abundant sources. Unfortunately, their practical application in NIBs is still hindered because of low conductivity and morphological collapse caused by their volume expansion and shrinkage during Na⁺ intercalation/deintercalation. To solve the daunting challenges, herein, we fabricated novel three-dimensional (3D) Cu₂NiSnS₄ nanoflowers (CNTSNs) as a proof-of-concept experiment using a facile and low-cost method. Furthermore, homogeneous integration with reduced graphene oxide nanosheets (RGNs) endows intrinsically insulated CNTSNs with superior electrochemical performances, including high specific capacity (up to 837 mAh g^–1), good rate capability, and long cycling stability, which could be attributed to the unique 3D hierarchical structure providing fast ion diffusion pathway and high contact area at the electrode/electrolyte interface

Self-Assembled 3D Hierarchical Porous Bi₂MoO₆ Microspheres toward High Capacity and Ultra-Long-Life Anode Material for Li-Ion Batteries

Three-dimensional (3D) hierarchical porous Bi₂MoO₆ microspheres (HPBMs) were successfully prepared and used as the anode material in Li-ion batteries (LIBs) for the first time. The HPBMs showed a high capacity (>830 mAh·g^–1, 734.5 mAh·cm^–2), high rate capability (20 A·g^–1, 177.7 mAh·g^–1), and superior long cycle life (>2700 cycles) in the temperature range 5–55 °C without adding any other conductive carbon materials, such as graphene and carbon nanotubes. This can be reasonably attributed to their substantially high surface area, 3D hierarchical porous structure, and homogeneous conductive matrix composed of metallic nanoparticles. HPBMs surprisingly showed a high reversible discharge capacity of 537.2 mAh·g^–1 (475.4 mAh·cm^–2) and an average discharge voltage >3.0 V even when coupled with LiCoO₂ in a full cell. The results highlight the feasibility of HPBMs as anode material for LIBs