安德里亚·蒙特梭利，Andrea Montessori, PhD, is a Postdoc researcher in the Department of Engineering at the University of Rome 'Roma Tre' in Italy. He obtained his PhD (cum laude) in Engineering in 2017 from the University of Rome 'Roma Tre' with the thesis 'Lattice Boltzmann approach to complex fluid phenomena across scales'. He has developed the Lattice Boltzmann Model for the simulation of complex fluid dynamics phenomena, including multiphase and multicomponent flows, reactive and nonequilibrium flows, and transport phenomena in 2D nanomaterials. He is involved in the IMASC project as a collaborator and was a visiting scholar at Harvard University in 2015. He has published more than 20 papers on Lattice Boltzmann models for fluid dynamics phenomena across scales of motion.

流体力学是无数科学和技术应用的基础，从最小的物理尺度（纳米流体、细菌运动和多孔介质中的扩散流动）到最大的尺度（从发电厂的能源生产到海洋学和气象学），为了人类的进步、可持续和更有效的未来，必须加深对跨尺度的流体行为的研究。本书共分七章，主要介绍了玻尔兹曼方法应用于科学和技术中复杂流动现象的最新进展，适合高等院校本科、研究生师生以及相关专业的研究者参考阅读。

Preface
Acknowledgments
Author biographies
1 Introduction
2 The lattice Boltzmann equation for complex flows
2.1 Kinetic and lattice kinetic theory: a brief overview
2.2 The lattice Boltzmann equation
References
3 Lattice schemes for multiphase and multicomponent flows
theory and applications
3.1 The pseudopotential approach for multiphase flows
3.2 Discretisation of the non-ideal forcing term on higher-order lattices
3.2.1 Applications to internal combustion engines: simulating a
cavitating injector
3.3 Entropic lattice pseudo-potentials for multiphase flow simulations
3.3.1 The benefits of the entropic formulation
3.4 Applications and results
References
4 Lattice Boltzmann models for fluid-structure interaction
problems
4.1 Fluid-structure interaction--rigid cantilevers
4.1.1 Governing equations
4.1.2 Lattice Boltzann implementation
4.1.3 Force evaluation
4.1.4 Representative flow fields
4.1.5 Extraction of the hydrodynamic function
4.2 Fluid-structure interaction--wedge-shaped bodies
4.2.1 The structure: finite element analysis
4.2.2 Fluid-structure interaction: time discontinuous Galerkin
method and coupling algorithm
4.2.3 Numerical results
4.3 Free surface simulation in water entry problems
4.3.1 Numerical implementation
4.3.2 Numerical results and validation
References
5 Extended lattice Boltzmann model for rarefied
nonequilibrium flows in porous media
5.1 Extended LB approach: higher-order regularization and kineticboundary conditions
5.1.1 Extended lattice Boltzmann versus Grad's generalized hydrodynamics
5.2 Flow across flat plates at increasing Knudsen
5.3 Three-dimensional flow through array of sphere References
6 Lattice Boltzmann approach to reactive flows in nano-porous catalysts
6.1 Relevant non-dimensional numbers in reactive flows
6.2 The reactive boundary condition
6.3 Consistency of reaction time
6.4 Numerical simulations
6.5 Effect of the Damk6hler number
6.6 Effects of the Knudsen number
6.7 Upscaling
References
7 Lattice Boltzmann model for water transport inside sub-nano graphene membranes
7.1 Background
7.2 Experimental details
7.3 Augmented LB for water transport inside GO membranes
7.4 Results
7.5 Inside the flow structure
7.6 Sub-nano tuning of graphene flakes' spacing in GO membrane: effects on permeability
7.7 Some remarks on the slip length in nano-channel flows References
编辑手记