材料科学
钻石
表面改性
纳米技术
微晶
表面能
粘附
Crystal(编程语言)
扫描电子显微镜
复合材料
化学气相沉积
石膏
图层(电子)
电极
纳米尺度
氮气
类金刚石碳
离子
化学工程
密度泛函理论
晶体生长
碳纤维
金刚石材料性能
液氮
陶瓷
电化学
单晶
储能
金刚石立方
聚晶金刚石
作者
Xiang Zhang,Yifan Zhu,Eliezer F. Oliveira,Tymofii S. Pieshkov,Qing Ai,Tianshu Zhai,Michelle T. Chen,Yunrui Yan,Tianyou Xie,RÓBERT VAJTAI,Jun Lou,Pulickel M. Ajayan
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-11-14
标识
DOI:10.1021/acsnano.5c13554
摘要
Mineral scaling, particularly gypsum deposition, remains a costly and persistent problem in industrial systems, lowering efficiency, raising energy demands, and accelerating equipment degradation. Conventional chemical and mechanical mitigation methods are temporary and often introduce secondary environmental or operational concerns, underscoring the need for intrinsically scale-resistant materials. Herein, we report a systematic investigation of polycrystalline diamond (PCD) films with varied surface terminations (oxygen, hydrogen, fluorine, or nitrogen) for their resistance to CaSO4 scaling. Nitrogen-terminated PCD (N-PCD) exhibits an order-of-magnitude reduction in Ca2+ accumulation compared with other terminations. Scanning electron microscopy (SEM) reveals that N-PCD supports only sparse, dendritic gypsum crystallites, in contrast to the dense, continuous scale layers observed on other surfaces. Consistently, adhesion force measurements confirm extremely low adhesion between the CaSO4 crystal and N-PCD. Molecular dynamics and density functional theory simulations show that a strongly bound, ordered water layer forms on N-PCD, creating an energetic barrier that repels CaSO4 ions and suppresses heterogeneous nucleation. Further enhancement is achieved by bulk nitrogen doping, which smooths the surface morphology and suppresses scale formation by up to 6-fold. Finally, applying nitrogen functionalization to commercial boron-doped diamond (BDD) electrodes yields seven times lower scale loading without compromising electrochemical performance. This combined experimental-theoretical study establishes nitrogen-functionalized diamond as a robust, durable platform for antiscaling coatings, with potential applications across water treatment, energy production, and other scaling-prone industries.
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