原子力显微镜
启发式
流离失所(心理学)
运动规划
弹道
纳米尺度
平滑度
表征(材料科学)
曲面(拓扑)
算法
计算机科学
纳米技术
显微镜
路径(计算)
生物系统
材料科学
欧几里德几何
欧几里德距离
比例(比率)
准确度和精密度
比例因子(宇宙学)
纳米计量学
计算机视觉
尺寸
灵敏度(控制系统)
位移映射
曲面重建
路径长度
标准差
作者
Liguo Tian,Yongkun He,Yang Wang,Haiyue Yu,Wen‐Tao Yu,Baichuan Wang,Lanjiao Liu,Wenxiao Zhang,Ying Wang,Xiao Zhang,Cuihua Hu,Wei Ji,Zuobin Wang
出处
期刊:Langmuir
[American Chemical Society]
日期:2025-09-16
卷期号:41 (38): 26342-26353
标识
DOI:10.1021/acs.langmuir.5c03412
摘要
The use of atomic force microscopy (AFM) for nanoscale surface characterization and mechanical property measurement has attracted considerable interest. At the level of single-molecule mechanical measurement, AFM is a powerful tool for both surface morphology analysis and mechanical assessment. However, its effectiveness is limited by dynamic displacement deviation during precise nanoscale positioning of surface target points, an essential factor in accurately determining surface mechanical properties. This study addresses this limitation by proposing an integrated enhanced A-star (A*) framework for contour-aware motion trajectory planning, ensuring nanometer-level target localization accuracy during AFM measurements on complex surface morphologies. The method employs AFM tip repositioning using prior topographic data and enables trajectory path planning on biological cell surfaces with both high and low topographical undulations. Experimental evaluations using Manhattan, Chebyshev, and Euclidean heuristic metrics in AFM grid modeling demonstrated that the Manhattan approach achieved a heuristic accuracy of 96% ± 4%, significantly outperforming Euclidean (70% ± 4%) and Chebyshev (56% ± 8%) methods (p < 0.001). In constrained environments, the Manhattan heuristic reduced target localization errors by 30% by alleviating path cost overestimation and resolved the long-standing trade-off between path smoothness (coefficient of variation, CV = 0.28) and positioning precision through adaptive cost-weighting mechanisms. The proposed approach supports precise nanoscale positioning necessary to capture ultramicroscopic topography and physical characteristics, providing a robust framework for quantitative nanomechanical characterization of heterogeneous materials.
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