- Sumaiya SA, Liu J, Baykara MZ. True atomic-resolution surface imaging and manipulation under ambient conditions via conductive atomic force microscopy. ACS Nano. 2022;16(12):20086-93.
- Korayem MH, Hefzabad RN. Nonlinear modeling of nanoscale interaction forces between atomic force microscope and carbon nanotubes. Int J Non-Linear Mech. 2024;161:104690.
- Chen W, Zhou H, Zhang B, Cao Q, Wang B, Ma X. Recent progress of micro/nanorobots for cell delivery and manipulation. Adv Funct Mater. 2022;32(18):2110625.
- Zhou G, Zhang B, Tang G, Yu XF, Galluzzi M. Cells nanomechanics by atomic force microscopy: focus on interactions at nanoscale. Adv Phys X. 2021;6(1):1866668.
- Yuan S, Liu L, Liu B, Chu T, Zhang C, Wang W. Study of virus infection procedure using atomic force microscope. In: 2019 IEEE Int Conf Robot Biomimetics (ROBIO); 2019 Dec. p. 1526-31.
- Xia F, Youcef-Toumi K. Advanced atomic force microscopy modes for biomedical research. Biosensors. 2022;12(12):1116.
- Korayem MH, Khaksar H. A survey on dynamic modeling of manipulation of nanoparticles based on atomic force microscope and investigation of involved factors. J Nanopart Res. 2020;22(1):27.
- Korayem MH, Habibi Sooha Y, Rastegar Z. Modeling and simulation of viscoelastic biological particles’ 3D manipulation using atomic force microscopy. Appl Phys A. 2018;124:1-13.
- Taheri M. Using spherical contact models in modeling the three-dimensional manipulation of gold nanoparticles using atomic force microscopy to calculate critical force and time. Mech Eng Univ Tabriz. 2018;48(2):175-84. (In persian)
- Taheri M. Investigating the effect of environmental factors on the critical force and time of 3D nanomanipulation using the Sobel statistical sensitivity analysis method. Mech Eng Univ Tabriz. 2019;49(2):159-68.
- Zhou LM, Shi Y, Zhu X, Hu G, Cao G, Hu J, et al. Recent progress on optical micro/nanomanipulations: structured forces, structured particles, and synergetic applications. ACS Nano. 2022;16(9):13264-78.
- Xu R, Guo J, Mi S, Wen H, Pang F, Ji W, et al. Advanced atomic force microscopies and their applications in two-dimensional materials: a review. Mater Futures. 2022;1(3):032302.
- Miranda A, Gómez-Varela AI, Stylianou A, Hirvonen LM, Sánchez H, De Beule PA. How did correlative atomic force microscopy and super-resolution microscopy evolve in the quest for unravelling enigmas in biology? Nanoscale. 2021;13(4):2082-99.
- Xu K, Sun W, Shao Y, Wei F, Zhang X, Wang W, et al. Recent development of PeakForce Tapping mode atomic force microscopy and its applications on nanoscience. Nanotechnol Rev. 2018;7(6):605-21.
- Liu C, Huang Z, Huang S, Zhang Y, Li B, Nan F, et al. Robotic nanomanipulation based on spatiotemporal modulation of optical gradients. ACS Nano. 2024;18(29):19391-400.
- Korayem MH, Zakeri M. Sensitivity analysis of nanoparticles pushing critical conditions in 2-D controlled nanomanipulation based on AFM. The International Journal of Advanced Manufacturing Technology. 2009;41(7):714–726.
- Korayem MH, Omidi E. Robust controlled manipulation of nanoparticles using atomic force microscope. Micro & Nano Letters. 2012;7(9):927–931.
- Daeinabi K, Korayem MH. Indentation analysis of nano-particle using nano-contact mechanics models during nano-manipulation based on atomic force microscopy. Journal of Nanoparticle Research. 2011;13(3):1075–1091.
- Korayem MH, Taheri M, Zakeri M. Sensitivity analysis of nanoparticles manipulation based on different friction models. Appl Surf Sci. 2012;258(18):6713–22.
- Korayem MH, Taheri M, Ghasemi M, Badkoobehhezavh H. Investigating the effective parameters in the Atomic Force Microscope–based dynamic manipulation of rough micro/nanoparticles by using the Sobol sensitivity analysis method. Simulation. 2015;91(12):1068–1080.
- Taheri M. Application of atomic force microscopy in critical force and critical time extraction of 2D manipulation for gastric cancer tissue with different friction models. Nanoscale. 2022;9(1):136–145.
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