Nonlinear Finite Element Analysis of Composite and Reinforced Concrete Beams presents advanced methods and techniques for the analysis of composite and FRP reinforced concrete beams. The title introduces detailed numerical modeling methods and the modeling of the structural behavior of composite beams, including critical interfacial bond-slip behavior. It covers a new family of composite beam elements developed by the authors. Other sections cover nonlinear finite element analysis procedures and the numerical modeling techniques used in commercial finite element software that will be of particular interest to engineers and researchers executing numerical simulations. - Gives advanced methods and techniques for the analysis of composite and fiber Reinforced Plastic (FRP) and reinforced concrete beams - Presents new composite beam elements developed by the authors - Introduces numerical techniques for the development of effective finite element models using commercial software - Discusses the critical issues encountered in structural analysis - Maintains a clear focus on advanced numerical modeling

Dr Xiaoshan Lin is a Lecturer in Civil and Infrastructure Engineering discipline in the School of Engineering at RMIT University in Australia. Dr Lin received her PhD degree in Civil Engineering from the University of New South Wales (UNSW) in 2012. Before joining RMIT in 2016, she had been working as a Postdoctoral Researcher at UNSW Canberra, University of Liverpool in the UK and Nanyang Technological University in Singapore. Dr Lin's fields of expertise include finite element development for accurate and efficient numerical simulation, high performance reinforced concrete and composite materials, and structural analysis under extreme conditions. As an early-career researcher, Dr Lin has published her research works in more than 40 highly reputed international journals and conferences.

1. Introduction 2. Finite Element Analysis of Beams 3. Finite Element Analysis of Composite Beams 4. Finite Element Analysis of Reinforced Concrete Beams 5. Finite Element Analysis of Reinforced Concrete Beams with Bond-slip 6. Finite Element Analysis of Reinforced Concrete Beams at Elevated Temperatures 7. Finite Element Analysis of FRP-strengthened Reinforced Concrete Beams under Static and Cyclic Loads

Appendix A. List of Notations B. Gaussian Integration C. Temperature-Dependent Material Properties of Concrete D. Temperature-Dependent Material Properties of Steel E. Temperature-Dependent Material Properties of FRP F. Finite Element Code for Composite Beam Element: Linear Analysis G. Finite Element Code for Composite Beam Element: Nonlinear Analysis H. Finite Element Code for Composite Beam Element: Nonlinear Analysis with Bond-slip I. Finite Element Code for Composite Beam Element: Nonlinear Analysis with Temperature Effect J. User Subroutine for Concrete under Cyclic Load K. User Subroutine for Steel under Cyclic Load L. User Subroutine for FRP under Cyclic Load