relation: http://repositorio.unic.co.ao/id/eprint/14949/ canonical: http://repositorio.unic.co.ao/id/eprint/14949/ title: Investigation of structural frustration in symmetric diblock copolymers confined in polar discs through cell dynamic simulation creator: Iqbal, Muhammad Javed creator: Soomro, Inayatullah creator: Razzaq, Mirza Abdur creator: Omar-Martinez, Erislandy creator: Velázquez Martínez, Zaily Leticia creator: Ashraf, Imran subject: Ingeniería description: Nanotechnology has opened new avenues for advanced research in various fields of soft materials. Materials scientists, chemists, physicists, and computational mathematicians have begun to take a keen interest in soft materials due to their potential applications in nanopatterning, membrane separation, drug delivery, nanolithography, advanced storage media, and nanorobotics. The unique properties of soft materials, particularly self-assembly, have made them useful in fields ranging from nanotechnology to biomedicine. The discovery of new morphologies in the diblock copolymer system in curved geometries is a challenging problem for mathematicians and theoretical scientists. Structural frustration under the effects of confinement in the system helps predict new structures. This mathematical study evaluates the effects of confinement and curvature on symmetric diblock copolymer melt using a cell dynamic simulation model. New patterns in lamella morphologies are predicted. The Laplacian involved in the cell dynamic simulation model is approximated by generating a 17-point stencil discretized to a polar grid by the finite difference method. Codes are programmed in FORTRAN to run the simulation, and IBM open DX is used to visualize the results. Comparison of computational results with existing studies validates this study and identifies defects and new patterns. date: 2024-10 type: Artículo type: PeerReviewed format: text language: en rights: cc_by_nc_nd_4 identifier: http://repositorio.unic.co.ao/id/eprint/14949/1/s41598-024-76213-3.pdf identifier: Artículo Materias > Ingeniería Universidad Europea del Atlántico > Investigación > Producción Científica Universidad Internacional Iberoamericana México > Investigación > Producción Científica Universidad Internacional do Cuanza > Investigación > Artículos y libros Universidad de La Romana > Investigación > Producción Científica Abierto Inglés Nanotechnology has opened new avenues for advanced research in various fields of soft materials. Materials scientists, chemists, physicists, and computational mathematicians have begun to take a keen interest in soft materials due to their potential applications in nanopatterning, membrane separation, drug delivery, nanolithography, advanced storage media, and nanorobotics. The unique properties of soft materials, particularly self-assembly, have made them useful in fields ranging from nanotechnology to biomedicine. The discovery of new morphologies in the diblock copolymer system in curved geometries is a challenging problem for mathematicians and theoretical scientists. Structural frustration under the effects of confinement in the system helps predict new structures. This mathematical study evaluates the effects of confinement and curvature on symmetric diblock copolymer melt using a cell dynamic simulation model. New patterns in lamella morphologies are predicted. The Laplacian involved in the cell dynamic simulation model is approximated by generating a 17-point stencil discretized to a polar grid by the finite difference method. Codes are programmed in FORTRAN to run the simulation, and IBM open DX is used to visualize the results. Comparison of computational results with existing studies validates this study and identifies defects and new patterns. metadata Iqbal, Muhammad Javed; Soomro, Inayatullah; Razzaq, Mirza Abdur; Omar-Martinez, Erislandy; Velázquez Martínez, Zaily Leticia y Ashraf, Imran mail SIN ESPECIFICAR, SIN ESPECIFICAR, SIN ESPECIFICAR, SIN ESPECIFICAR, zaily.velazquez@unini.edu.mx, SIN ESPECIFICAR (2024) Investigation of structural frustration in symmetric diblock copolymers confined in polar discs through cell dynamic simulation. Scientific Reports, 14 (1). ISSN 2045-2322 relation: http://doi.org/10.1038/s41598-024-76213-3 relation: doi:10.1038/s41598-024-76213-3 language: en