3D graphene assemblies are proposed as solutions to meet the goal toward efficient utilization of 2D graphene sheets, showing excellent performances in applications such as mechanical support, energy storage, and electrochemical catalysis. However, given the diversity and complexity of possible graphene 3D structures, there does not yet exist a systematic approach that can generate target 3D shapes and also, evaluate their performance. Here high-throughput data generation is combined with artificial intelligence approaches to realize rapid structure formation and property quantification of 3D graphene foams with mathematically controlled topologies, driven by molecular dynamics simulations. More than 4000 different foam structures are creat...
Abstract Developing accurate yet fast computational tools to simulate complex physical phenomena is ...
Atomistic simulations have become a prominent tool in chemistry, physics, and materials science for ...
The possibility of band gap engineering in graphene opens countless new opportunities for applicatio...
In this research study, we employ machine learning algorithms to perform molecular dynamics simulati...
Despite the tremendous capabilities of Molecular dynamics (MD) simulations, they suffer from the lim...
Recently, much attention has been directed to 3D graphene structures due to their potential of retai...
The matrix-reinforcement interface has been studied extensively to enhance the performance of polyme...
In materials science, the first principles modeling, especially density functional theory (DFT), ser...
Understanding fracture is critical to the design of resilient nanomaterials. Molecular dynamics offe...
From AlexNet to Inception, autoencoders to diffusion models, the development of novel and powerful d...
Mixed-dimensional heterostructures composed of two-dimensional (2D) and three-dimensional (3D) mater...
© 2018 American Physical Society. We present an accurate interatomic potential for graphene, constru...
Defects in graphene can profoundly impact its extraordinary properties, ultimately influencing the p...
Notably known for its extraordinary thermal and mechanical properties, graphene is a favorable build...
Two-dimensionally extended amorphous carbon ("amorphous graphene") is a prototype system for disorde...
Abstract Developing accurate yet fast computational tools to simulate complex physical phenomena is ...
Atomistic simulations have become a prominent tool in chemistry, physics, and materials science for ...
The possibility of band gap engineering in graphene opens countless new opportunities for applicatio...
In this research study, we employ machine learning algorithms to perform molecular dynamics simulati...
Despite the tremendous capabilities of Molecular dynamics (MD) simulations, they suffer from the lim...
Recently, much attention has been directed to 3D graphene structures due to their potential of retai...
The matrix-reinforcement interface has been studied extensively to enhance the performance of polyme...
In materials science, the first principles modeling, especially density functional theory (DFT), ser...
Understanding fracture is critical to the design of resilient nanomaterials. Molecular dynamics offe...
From AlexNet to Inception, autoencoders to diffusion models, the development of novel and powerful d...
Mixed-dimensional heterostructures composed of two-dimensional (2D) and three-dimensional (3D) mater...
© 2018 American Physical Society. We present an accurate interatomic potential for graphene, constru...
Defects in graphene can profoundly impact its extraordinary properties, ultimately influencing the p...
Notably known for its extraordinary thermal and mechanical properties, graphene is a favorable build...
Two-dimensionally extended amorphous carbon ("amorphous graphene") is a prototype system for disorde...
Abstract Developing accurate yet fast computational tools to simulate complex physical phenomena is ...
Atomistic simulations have become a prominent tool in chemistry, physics, and materials science for ...
The possibility of band gap engineering in graphene opens countless new opportunities for applicatio...