TY - BOOK ID - 134343296 TI - Advances in Micro and Nano Manufacturing: Process Modeling and Applications AU - Masato, Davide AU - Lucchetta, Giovanni PY - 2022 PB - Basel MDPI - Multidisciplinary Digital Publishing Institute DB - UniCat KW - Technology: general issues KW - History of engineering & technology KW - modular microfluidic system KW - 3D printing KW - gel microspheres KW - laser-induced periodical surface structures KW - micro-injection molding KW - replication KW - surface wettability KW - micro-groove KW - electrochemical machining KW - porous cathode KW - conductive mask KW - machining localization KW - dimensional uniformity KW - nanogrinding KW - abrasive grains KW - rake angle KW - spacing KW - grinding forces KW - grinding temperature KW - chip formation KW - subsurface damage KW - micro injection molding KW - additive manufacturing KW - stereolithography KW - K9 glass KW - mathematical model KW - grinding force KW - brittle fracture KW - ductile–brittle transition KW - active grains number KW - lithography simulation KW - microelectromechanical system KW - waveguide method KW - microstructure KW - radial ultrasonic rolling electrochemical micromachining (RUR-EMM) KW - material removal amount KW - surface roughness KW - response surface methodology (RSM) KW - turning KW - minimum chip thickness KW - micromachining KW - femtosecond micromachining KW - burst processing KW - intraocular lens KW - hydrophilic acrylic KW - polishing KW - laser assisted turning KW - tungsten carbide KW - diamond turning KW - finite element analysis KW - prostheses KW - ITAP KW - micro topology KW - ANSYS KW - MATLAB KW - additive manufacture KW - n/a KW - ductile-brittle transition UR - https://www.unicat.be/uniCat?func=search&query=sysid:134343296 AB - Micro- and nanomanufacturing technologies have been researched and developed in the industrial environment with the goal of supporting product miniaturization and the integration of new functionalities. The technological development of new materials and processing methods needs to be supported by predictive models which can simulate the interactions between materials, process states, and product properties. In comparison with the conventional manufacturing scale, micro- and nanoscale technologies require the study of different mechanical, thermal, and fluid dynamics, phenomena which need to be assessed and modeled.This Special Issue is dedicated to advances in the modeling of micro- and nanomanufacturing processes. The development of new models, validation of state-of-the-art modeling strategies, and approaches to material model calibration are presented. The goal is to provide state-of-the-art examples of the use of modeling and simulation in micro- and nanomanufacturing processes, promoting the diffusion and development of these technologies. ER -