Your search keyword '"Multiscale modelling"' showing total 1,549 results

1. Multiscale modelling and characterization of bonded repaired sandwich composite facing sheet under static loading.

Author

Quader, Niaz and Muthu, SD Jacob

Subjects

SANDWICH construction (Materials), MULTISCALE modeling, DEAD loads (Mechanics), FRACTURE mechanics, FAILURE analysis

Abstract

Prediction of composite materials failure is a valuable resource for ensuring structural integrity of aerospace structures. For the experimental part of the study, the sandwich specimens were fabricated using two aluminium cores, a Nomex core sandwiched between tool-facing and bag-facing sheets. A damaged slot was introduced and thereafter repaired with filler and repaired plies on the tool-facing sheet. The bonded-repaired sandwich composite facing sheet specimens were tested using a four-point bending setup under static loading conditions. A Multiscale Modelling (MSM) approach was developed to characterize the failure of a bonded-repaired sandwich composite tool-facing sheet. The MSM approach bridged three different length scales such as micro, meso and macro scales. The data processing and information transfer between the scales was facilitated by Visual Basic Applications scripts. Comparisons of micro, meso and micro-scale results were presented for both MSM and experimentation to validate the proposed MSM failure characterization approach. Numerical and fractographical results from MSM and experimentation matched very well for all three scales. In conclusion, the MSM failure characterization approach performed well against the experiment. It presents an opportunity to use an alternative composite materials failure characterization method for future research. [ABSTRACT FROM AUTHOR]

Published

2024

2. Multiscale modelling of precipitation hardening: a review.

Author

Cui, Aiya, Wang, Xiaoming, and Cui, Yinan

Subjects

MULTISCALE modeling, SKID resistance, EMPIRICAL research, ALLOYS, ENGINEERING

Abstract

Precipitation hardening, a cornerstone of alloy strengthening, finds widespread application in engineering materials. Comprehending the underlying mechanisms and formulating models bear crucial significance for engineering applications. While classical macroscopic theoretical models based on the line tension model have historically guided research efforts, their reliance on simplifications, assumptions, and parameter adjustments limits their predictability and expansibility. Moreover, the challenge of understanding the intricate coupling effects among various hardening mechanisms persists. One fundamental question to achieve the transition of material design paradigms from empirical trial-and-error methods to predictive-and-design approaches is to develop more physics-based multiscale modelling methods. This review aims to elucidate the physical mechanisms governing precipitation hardening and establish a tailored bottom-up multiscale modelling framework to steer the design of new alloys. The physical scenarios of precipitation hardening are firstly summarized, including particle shearing, Orowan bypass, and dislocation cross-slip and climb. Afterwards, an in-depth discussion is given regarding the application of macroscopic models and their correlation with the mechanisms and precipitation characteristics. As for the multiscale modelling methods, we categorize them into three main types: slip resistance based approaches, misfit stress field based approaches, and energy based approaches. By integrating multiscale modelling with the physical scenarios, we systematically addressed the key idea of the multiscale coupling framework, and their scale transfer procedure, applicability, advantages, and limitations. Some examples of coupling different types of multiscale methods and considering precipitates with complicated shapes are also presented. This study not only furnishes insightful comprehension of precipitation hardening, but also guides the development of multiscale modelling methodologies for other types of hardening effects in alloys. [ABSTRACT FROM AUTHOR]

Published

2024

3. Modelling Photocatalytic N2 Reduction to Ammonia: Where We Stand and Where We Are Going.

Author

Žibert, Taja, Likozar, Blaž, and Huš, Matej

Subjects

PHOTOREDUCTION, HABER-Bosch process, NITROGEN fixation, STEAM reforming, DENSITY functional theory, PHOTOCATALYSTS, AMMONIA, ATMOSPHERIC ammonia

Abstract

Artificial ammonia synthesis via the Haber‐Bosch process is environmentally problematic due to the high energy consumption and corresponding CO2 ${_2 }$ emissions, produced during the reaction and before hand in hydrogen production upon methane steam reforming. Photocatalytic nitrogen fixation as a greener alternative to the conventional Haber‐Bosch process enables us to perform nitrogen reduction reaction (NRR) under mild conditions, harnessing light as the energy source. Herein, we systematically review first‐principles calculations used to determine the electronic/optical properties of photocatalysts, N2 adsorption and to expound possible NRR mechanisms. The most commonly studied photocatalysts for nitrogen fixation are usually modified with dopants, defects, co‐catalysts and Z‐scheme heterojunctions to prevent charge carrier recombination, improve charge separation efficiency and adjust a band gap to for utilizing a broader light spectrum. Most studies at the atomistic level of modeling are grounded upon density functional theory (DFT) calculations, wholly foregoing excitation effects paramount in photocatalysis. Hence, there is a dire need to consider methods beyond DFT to study the excited state properties more accurately. Furthermore, a few studies have been examined, which include higher level kinetics and macroscale simulations. Ultimately, we show there is still ample room for improvement with regard to first principles calculations and their integration in multiscale models. [ABSTRACT FROM AUTHOR]

Published

2024

4. Multiscale Modelling of Polymer Composites

Author

Gunwant, Dheeraj, Bisht, Neeraj, Thakur, Vijay Kumar, Series Editor, Sethi, Sushanta K., editor, Gupta, Hariome Sharan, editor, and Verma, Akarsh, editor

Published

2024

5. Homogenization of the Perfusion and Contrast Fluid Transport in the Liver Lobules

Author

Rohan, Eduard, Turjanicová, Jana Camprová, Tavares, João Manuel R. S., Series Editor, Jorge, Renato Natal, Series Editor, Cohen, Laurent, Editorial Board Member, Doblare, Manuel, Editorial Board Member, Frangi, Alejandro, Editorial Board Member, Garcia-Aznar, Jose Manuel, Editorial Board Member, Holzapfel, Gerhard A., Editorial Board Member, Hughes, Thomas J.R., Editorial Board Member, Kamm, Roger, Editorial Board Member, Li, Shuo, Editorial Board Member, Löhner, Rainald, Editorial Board Member, Nithiarasu, Perumal, Editorial Board Member, Oñate, Eugenio, Editorial Board Member, Perales, Francisco J., Editorial Board Member, Prendergast, Patrick J., Editorial Board Member, Tamma, Kumar K., Editorial Board Member, Vilas-Boas, Joao Paulo, Editorial Board Member, Weiss, Jeffrey, Editorial Board Member, Zhang, Yongjie Jessica, Editorial Board Member, Skalli, Wafa, editor, Laporte, Sébastien, editor, and Benoit, Aurélie, editor

Published

2024

6. Emergence of a Multiplicity of Time Scales in the Modelling of Climate, Matter, Life, and Economy

Author

Booß-Bavnbek, Bernhelm, Pedersen, Rasmus K., Pedersen, Ulf R., Booß-Bavnbek, Bernhelm, editor, Hesselbjerg Christensen, Jens, editor, Richardson, Katherine, editor, and Vallès Codina, Oriol, editor

Published

2024

7. SGABU Computational Platform as a Tool for Improved Education and Research in Multiscale Modelling

Author

Geroski, Tijana, Živković, Jelena, Hellmich, Christian, Exarchos, Themis, Van Oosterwyck, Hans, Jakovljević, Djordje, Ivanović, Miloš, Filipović, Nenad, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Trajanovic, Miroslav, editor, Filipovic, Nenad, editor, and Zdravkovic, Milan, editor

Published

2024

8. Continuum Modelling of Carbon Nanotube Composites: A Review

Author

Omar, N., Rasid, Z. A., Hassan, M. Z., Awang, Mokhtar, editor, Al-Kayiem, Hussain H., editor, Bor, Ton C., editor, and Emamian, Seyed Sattar, editor

Published

2024

9. Biogas Cleaning via Vacuum Swing Adsorption Using a Calcium Metal–Organic Framework Adsorbent: A Multiscale Simulation Study.

Author

Lasich, Madison, Adeleke, Victoria T., and Tumba, Kaniki

Subjects

METAL-organic frameworks, BIOGAS, MONTE Carlo method, HYDROGEN sulfide, STEAM reforming, OXYGEN

Abstract

Purifying biogas can enhance the performance of distributed smart grid systems while potentially yielding clean feedstock for downstream usage such as steam reforming. Recently, a novel anion-pillared metal–organic framework (MOF) was reported in the literature that shows good capacity to separate acetylene from carbon dioxide. The present study assesses the usefulness of this adsorbent for separating a typical biogas mixture (consisting of methane, nitrogen, oxygen, hydrogen, carbon dioxide, and hydrogen sulphide) using a multiscale approach. This approach couples atomistic Monte Carlo simulations in the grand canonical ensemble with the batch equilibrium modelling of a pressure swing adsorption system. The metal–organic framework displays selectivity at low pressures for carbon dioxide and especially hydrogen sulphide. An analysis of adsorption isotherm models coupled with statistical distributions of surface–gas interaction energies determined that both CH4 and CO2 exhibited Langmuir-type adsorption, while H2S displayed Langmuir-type behaviour at low pressures, with increasing adsorption site heterogeneity at high pressures. Batch equilibrium modelling of a vacuum swing adsorption system to purify a CH4/CO2 feedstock demonstrated that such a system can be incorporated into a solar biogas reforming process since the target purity of 93–94 mol-% methane for incorporation into the process was readily achievable. [ABSTRACT FROM AUTHOR]

Published

2024

10. Modelling non-local cell-cell adhesion: a multiscale approach.

Author

Zhigun, Anna and Rajendran, Mabel Lizzy

Abstract

Cell-cell adhesion plays a vital role in the development and maintenance of multicellular organisms. One of its functions is regulation of cell migration, such as occurs, e.g. during embryogenesis or in cancer. In this work, we develop a versatile multiscale approach to modelling a moving self-adhesive cell population that combines a careful microscopic description of a deterministic adhesion-driven motion component with an efficient mesoscopic representation of a stochastic velocity-jump process. This approach gives rise to mesoscopic models in the form of kinetic transport equations featuring multiple non-localities. Subsequent parabolic and hyperbolic scalings produce general classes of equations with non-local adhesion and myopic diffusion, a special case being the classical macroscopic model proposed in Armstrong et al. (J Theoret Biol 243(1): 98–113, 2006). Our simulations show how the combination of the two motion effects can unfold. Cell-cell adhesion relies on the subcellular cell adhesion molecule binding. Our approach lends itself conveniently to capturing this microscopic effect. On the macroscale, this results in an additional non-linear integral equation of a novel type that is coupled to the cell density equation. [ABSTRACT FROM AUTHOR]

Published

2024

11. A discrete-to-continuum model for the human cornea with application to keratoconus

Author

J. Köry, P. S. Stewart, N. A. Hill, X. Y. Luo, and A. Pandolfi

Subjects

multiscale modelling, discrete-to-continuum asymptotics, corneal mechanics, keratoconus, collagen lamellae, proteoglycan matrix, Science

Abstract

We introduce a discrete mathematical model for the mechanical behaviour of a planar slice of human corneal tissue, in equilibrium under the action of physiological intraocular pressure (IOP). The model considers a regular (two-dimensional) network of structural elements mimicking a discrete number of parallel collagen lamellae connected by proteoglycan-based chemical bonds (crosslinks). Since the thickness of each collagen lamella is small compared to the overall corneal thickness, we upscale the discrete force balance into a continuum system of partial differential equations and deduce the corresponding macroscopic stress tensor and strain energy function for the micro-structured corneal tissue. We demonstrate that, for physiological values of the IOP, the predictions of the discrete model converge to those of the continuum model. We use the continuum model to simulate the progression of the degenerative disease known as keratoconus, characterized by a localized bulging of the corneal shell. We assign a spatial distribution of damage (i.e. reduction of the stiffness) to the mechanical properties of the structural elements and predict the resulting macroscopic shape of the cornea, showing that a large reduction in the element stiffness results in substantial corneal thinning and a significant increase in the curvature of both the anterior and posterior surfaces.

Published

2024

12. Multiscale modelling and characterisation of fused filament fabricated neat and graphene nanoplatelet reinforced G-polymers

Author

Parnian, Pooyan, Shojaee, Mohammad, Weeger, Oliver, and D’Amore, Alberto

Published

2024

13. Enhancing energy absorption in rubber–sand (Ru–San) composite blocks against ballistic impact: a multi-objective optimisation approach

Author

Doddamani, Saleemsab, Kulkarni, Satyabodh M., Joladarashi, Sharnappa, Mohan Kumar, T. S., and Gurjar, Ashish Kumar

Published

2024

14. Role of intra-lamellar collagen and hyaluronan nanostructures in annulus fibrosus on lumbar spine biomechanics: insights from molecular mechanics-finite element–based multiscale analyses

Author

Bhattacharya, Shambo and Dubey, Devendra K.

Published

2024

15. Multiscale modelling of biomolecular corona formation on metallic surfaces

Author

Parinaz Mosaddeghi Amini, Ian Rouse, Julia Subbotina, and Vladimir Lobaskin

Subjects

all atomistic, aluminum, bionano interface, coarse grained model, lactose, milk protein, multiscale modelling, protein corona, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

In the realm of food industry, the choice of non-consumable materials used plays a crucial role in ensuring consumer safety and product quality. Aluminum is widely used in food packaging and food processing applications, including dairy products. However, the interaction between aluminum and milk content requires further investigation to understand its implications. In this work, we present the results of multiscale modelling of the interaction between various surfaces, that is (100), (110), and (111), of fcc aluminum with the most abundant milk proteins and lactose. Our approach combines atomistic molecular dynamics, a coarse-grained model of protein adsorption, and kinetic Monte Carlo simulations to predict the protein corona composition in the deposited milk layer on aluminum surfaces. We consider a simplified model of milk, which is composed of the six most abundant milk proteins found in natural cow milk and lactose, which is the most abundant sugar found in dairy. Through our study, we ranked selected proteins and lactose adsorption affinities based on their corresponding interaction strength with aluminum surfaces and predicted the content of the naturally forming biomolecular corona. Our comprehensive investigation sheds light on the implications of aluminum in food processing and packaging, particularly concerning its interaction with the most abundant milk proteins and lactose. By employing a multiscale modelling approach, we simulated the interaction between metallic aluminum surfaces and the proteins and lactose, considering different crystallographic orientations. The results of our study provide valuable insights into the mechanisms of lactose and protein deposition on aluminum surfaces, which can aid in the general understanding of protein corona formation.

Published

2024

16. Mechanical behaviour of carbon nanotube composites: A review of various modelling techniques.

Author

Sahu, Renuka, Harursampath, Dineshkumar, and Ponnusami, Sathiskumar A

Subjects

*CARBON nanotubes, *CARBON composites, *EVIDENCE gaps, *MULTISCALE modeling, *STRUCTURAL mechanics, *COMPOSITE structures

Abstract

This study aims to review and highlight the important modelling methodologies used for studying carbon nanotubes (CNTs) and their composites. Understanding appropriate modelling methods for specific applications is crucial as CNTs become integral in achieving lighter, multifunctional composite structures. This paper explores a range of techniques, including finite element modelling (FEM), Molecular Dynamics (MD), Molecular Structural Mechanics (MSM), as well as nonlocal models, and the Cauchy-Born (CB) rule. Emphasis is placed on factors such as interphase effects between CNTs and the matrix, bonding interactions, non-bonded van der Waals (vdW) forces, and dynamic behaviour. Multiscale modelling is extensively discussed as a pivotal approach for efficiently addressing various length scales in nanocomposites. Modelling of failure, damage and its propagation, delamination, and instabilities such as buckling and fracture have been highlighted, and research gaps have been pointed out. [ABSTRACT FROM AUTHOR]

Published

2024

17. Infectious Disease in the Workplace: Quantifying Uncertainty in Transmission.

Author

Hamley, Jonathan I. D., Beldi, Guido, and Sánchez-Taltavull, Daniel

Abstract

Understanding disease transmission in the workplace is essential for protecting workers. To model disease outbreaks, the small populations in many workplaces require that stochastic effects are considered, which results in higher uncertainty. The aim of this study was to quantify and interpret the uncertainty inherent in such circumstances. We assessed how uncertainty of an outbreak in workplaces depends on i) the infection dynamics in the community, ii) the workforce size, iii) spatial structure in the workplace, iv) heterogeneity in susceptibility of workers, and v) heterogeneity in infectiousness of workers. To address these questions, we developed a multiscale model: A deterministic model to predict community transmission, and a stochastic model to predict workplace transmission. We extended this basic workplace model to allow for spatial structure, and heterogeneity in susceptibility and infectiousness in workers. We found a non-monotonic relationship between the workplace transmission rate and the coefficient of variation (CV), which we use as a measure of uncertainty. Increasing community transmission, workforce size and heterogeneity in susceptibility decreased the CV. Conversely, increasing the level of spatial structure and heterogeneity in infectiousness increased the CV. However, when the model predicts bimodal distributions, for example when community transmission is low and workplace transmission is high, the CV fails to capture this uncertainty. Overall, our work informs modellers and policy makers on how model complexity impacts outbreak uncertainty. In particular: workforce size, community and workplace transmission, spatial structure and individual heterogeneity contribute in a specific and individual manner to the predicted workplace outbreak size distribution. [ABSTRACT FROM AUTHOR]

Published

2024

18. Multiscale modelling of fluid transport in vascular tumours subjected to electrophoresis anticancer therapies.

Author

Fülöp, Zita Borbála, Ramírez-Torres, Ariel, and Penta, Raimondo

Subjects

*MULTISCALE modeling, *ELECTRIC field effects, *POTENTIAL flow, *ELECTRIC potential, *ELECTROPHORESIS, *ELECTROPORATION

Abstract

Electrophoresis facilitated cancer treatment has demonstrated experimental efficacy in enhancing drug delivery within vascularised tumours. However, the lack of realistic mathematical models with direct measurements in the context of electrochemotherapy poses a challenge. We investigate the impact of an applied electric potential on the flow of Darcian-type fluid occurring in two distinct phases: the tumour and healthy regions. We employ the asymptotic homogenisation technique, assuming that the macroscale of the tumour domain is larger than the microscale characterised by vessel heterogeneities. We retain information about the microstructure by encoding information in the homogenised coefficients. We take into account both vascularisation and the microscale variations of the leading order and fine scale electric potential. The resulting effective differential problem reads as a Darcy-type system of PDEs, where the flow is driven by an effective source. The novel model can be used to predict the effect of an applied electric field on cancerous biological tissues, paving a new way of improving current electrochemotherapy protocols. [ABSTRACT FROM AUTHOR]

Published

2024

19. A new model for evaluating pressure-induced vascular tone in small cerebral arteries.

Author

Coccarelli, Alberto, Pant, Sanjay, Polydoros, Ioannis, and Harraz, Osama F.

Subjects

*DRUG therapy, *SMOOTH muscle, *MUSCLE cells, *CEREBRAL circulation, *MULTISCALE modeling

Abstract

The capacity of small cerebral arteries (SCAs) to adapt to pressure fluctuations has a fundamental physiological role and appears to be relevant in different pathological conditions. Here, we present a new computational model for quantifying the link, and its contributors, between luminal pressure and vascular tone generation in SCAs. This is assembled by combining a chemical sub-model, representing pressure-induced smooth muscle cell (SMC) signalling, with a mechanical sub-model for the tone generation and its transduction at tissue level. The devised model can accurately reproduce the impact of luminal pressure on different cytoplasmic components involved in myogenic signalling, both in the control case and when combined with some specific pharmacological interventions. Furthermore, the model is also able to capture and predict experimentally recorded pressure-outer diameter relationships obtained for vessels under control conditions, both in a Ca 2 + -free bath and under drug inhibition. The modularity of the proposed framework allows the integration of new components for the study of a broad range of processes involved in the vascular function. [ABSTRACT FROM AUTHOR]

Published

2024

20. Complex deformations of biological soft tissue : tendons and ligaments

Author

Gregory, James, Hazel, Andrew, and Shearer, Tom

Subjects

Multiscale modelling, Biomechanics, Ligaments, Damage, Non-linear solid mechanics, Soft tissue mechanics, Tendons

Abstract

Tendons and ligaments are fibrous soft tissues which are vital for the structural and mechanical integrity of the human body. They possess a unique hierarchical microstructure, starting at the smallest scale with collagen molecules which aggregate to form collagen fibrils -- the most important mechanical component of tendons and ligaments, whose crimped geometry gives rise to complex non-linear stress-strain behaviour at the macroscale. Achieving a complete understanding of the relationship between the micro- and macroscale mechanics of these tissues is of interest to research groups spanning the fields of mathematics, material science, biology, and engineering. Accurate and reliable mathematical models of tendons and ligaments can be applied to predict internal stress distributions in vivo, a feat not possible through direct experimentation alone, providing valuable information to clinicians in instances of tissue damage and rupture. When researchers mathematically model tendons and ligaments, simplifying assumptions -- such as incompressibility and transverse isotropy -- have to be made. In the first part of this thesis, we analyse common assumptions by conducting finite element modelling of tendons and ligaments in idealised geometries. We show that if the direction of the collagen fibres is not carefully considered, unrealistic stress concentrations can form around the edge of the narrowest part of the tendon. We also evaluate the use of the isotropic von Mises yield criterion as an indicator of failure in soft tissue by comparing it with the anisotropic Hill yield criterion. We show that these two criteria produce different failure behaviour, adding to the emerging narrative that isotropic failure criteria are not suitable for biological soft tissues. In the second part of this thesis, we look more closely at failure in tendons and ligaments. We present a new microstructural model, based on the distribution of collagen fibril failure properties, which can produce the full range of stress-strain behaviour observed experimentally. Our model can account for certain features that existing models cannot capture, such as stress plateaus and step-like failure, whilst only including parameters that could, in principle, be measured experimentally. We fit our model to stress-strain data obtained from failure tests of mouse tail tendon fascicles and find good agreement. Most importantly, the parameter values found through fitting align with experimentally-obtained values within the literature.

Published

2022

21. Electro-Mechanical Finite Element Analysis of CNT Based Piezoresistive Composites: A Multiscale Approach

Author

Lone, Altaf Ahmad, Sheikh, Nazir Ahmad, and Butt, Mohammad Mursaleen

Published

2024

22. The impact of vascular volume fraction and compressibility of the interstitial matrix on vascularised poroelastic tissues.

Author

Mascheroni, Pietro, Penta, Raimondo, and Merodio, José

Subjects

*COMPRESSIBILITY, *POROELASTICITY, *DENSITY matrices, *PERMEABILITY, *ASYMPTOTIC homogenization, *TISSUES

Abstract

In this work we address the role of the microstructural properties of a vascularised poroelastic material, characterised by the coupling between a poroelastic matrix and a viscous fluid vessels network, on its overall response in terms of pressures, velocities and stress maps. We embrace the recently developed model (Penta and Merodio in Meccanica 52(14):3321–3343, 2017) as a theoretical starting point and present the results obtained by solving the full interplay between the microscale, represented by the intervessels' distance, and the macroscale, representing the size of the overall tissue. We encode the influence of the vessels' density and the poroelastic matrix compressibility in the poroelastic coefficients of the model, which are obtained by solving appropriate periodic cell problem at the microscale. The double-poroelastic model (Penta and Merodio 2017) is then solved at the macroscale in the context of vascular tumours, for different values of vessels' walls permeability. The results clearly indicate that improving the compressibility of the matrix and decreasing the vessels' density enhances the transvascular pressure difference and hence transport of fluid and drug within a tumour mass after a transient time. Our results suggest to combine vessel and interstitial normalization in tumours to allow for better drug delivery into the lesions. [ABSTRACT FROM AUTHOR]

Published

2023

23. Averaging for slow–fast piecewise deterministic Markov processes with an attractive boundary.

Author

Génadot, Alexandre

Subjects

MARKOV processes, DETERMINISTIC processes, SINGULAR perturbations, MULTISCALE modeling, NUMBER theory

Abstract

In this paper we consider the problem of averaging for a class of piecewise deterministic Markov processes (PDMPs) whose dynamic is constrained by the presence of a boundary. On reaching the boundary, the process is forced to jump away from it. We assume that this boundary is attractive for the process in question in the sense that its averaged flow is not tangent to it. Our averaging result relies strongly on the existence of densities for the process, allowing us to study the average number of crossings of a smooth hypersurface by an unconstrained PDMP and to deduce from this study averaging results for constrained PDMPs. [ABSTRACT FROM AUTHOR]

Published

2023

24. Computational homogenization of histological microstructures in human prostate tissue: Heterogeneity, anisotropy and tension‐compression asymmetry.

Author

Anderson, Calum, Ntala, Chara, Ozel, Ali, Reuben, Robert L., and Chen, Yuhang

Subjects

*TISSUE mechanics, *BENIGN prostatic hyperplasia, *CEREBRAL dominance, *ANISOTROPY, *TISSUES, *PROSTATE, *HETEROGENEITY

Abstract

Human prostatic tissue exhibits complex mechanical behaviour due to its multiphasic, heterogeneous nature, with hierarchical microstructures involving epithelial compartments, acinar lumens and stromal tissue all interconnected in complex networks. This study aims to establish a computational homogenization framework for quantifying the mechanical behaviour of prostate tissue, considering its multiphasic heterogeneous microstructures and the mechanical characteristics of tissue constituents. Representative tissue microstructure models were reconstructed from high‐resolution histology images. Parametric studies on the mechanical properties of the tissue constituents, particularly the fibre‐reinforced hyper‐elasticity of the stromal tissue, were carried out to investigate their effects on the apparent tissue properties. These were then benchmarked against the experimental data reported in literature. Results showed significant anisotropy, both structural and mechanical, and tension‐compression asymmetry of the apparent behaviours of the prostatic tissue. Strong correlation with the key microstructural indices such as area fractions of tissue constituents and the tissue fabric tensor was also observed. The correlation between the stromal tissue orientation and the principal directions of the apparent properties suggested an essential role of stromal tissue in determining the directions of anisotropy and the compression‐tension asymmetry characteristics in normal human prostatic tissue. This work presented a homogenization and histology‐based computational approach to characterize the apparent mechanical behaviours of human prostatic or other similar glandular tissues, with the ultimate aim of assessing how pathological conditions (e.g., prostate cancer and benign prostatic hyperplasia) could affect the tissue mechanical properties in a future study. [ABSTRACT FROM AUTHOR]

Published

2023

25. A dynamic multiscale model of cerebral blood flow and autoregulation in the microvasculature.

Author

Daher, Ali and Payne, Stephen

Subjects

*MULTISCALE modeling, *CEREBRAL circulation, *BLOOD flow, *DYNAMIC models, *PRESSURE drop (Fluid dynamics), *PATHOLOGICAL physiology, *CEREBROVASCULAR disease

Abstract

• Present a novel multiscale model to capture the dynamic blood flow and autoregulation in the brain vasculature. • Dynamic behaviour due to the fluid-wall interactions affects blood flow. • Important to achieve accurate, scale-invariant and computationally feasible coupling at the vessel-capillary interface. • The myogenic response might be insufficient by itself to restore blood flow following a drop in blood pressure. • Parameter space analysis gives insight into the range and influence of the model parameters prior to data extraction. Models of the micro-circulatory blood flow in the brain can play a key role in understanding the variety of cerebrovascular diseases that occur in the microvasculature. These conditions are often linked to structural modifications in the vessel network, alterations in the blood flow patterns, as well as impairment in the autoregulatory response, all of which are pathological changes that the model should be able to address if it were to have any clinical value. Furthermore, if the model results were to be validated against clinical MRI data, the model simulations need to be computationally feasible when used on networks on the scale of an MRI voxel. This requires some form of an upscaling approach that bypasses the need for an explicit architectural representation of the whole network while maintaining the relevant anatomical connections. To this end, we developed a hybrid multiscale model of blood flow and autoregulation that traces the dynamic changes in blood flow, volume, and pressure in the cortical microvasculature, where the discrete topology of the penetrating vessels is preserved, and these are then appropriately coupled to the homogenised capillary bed by a spatially distributing support function in the terminal endings. In contrast to the other multiscale models, the model developed here accounts for the dynamic physiological phenomena of the blood flow and the autoregulation processes in the microvessels. We show how the adaptive meshing scheme for the capillary bed developed in this study can be employed to ensure a scale-invariant coupling formulation and numerically accurate simulations, all without compromising the computational feasibility of the model. A statistically accurate cortical network on the scale of an MRI voxel is generated, and the model parameter values are calibrated using a Monte Carlo Filtering analysis to ensure that the model results are physiologically informed. The model is found to be able to capture the steep pressure gradients that have been reported to occur at coupling interfaces. Furthermore, in response to an upstream pressure drop, the network is found to be able to recover cerebral blood flow while exhibiting the characteristic autoregulatory behaviour in terms of changes in vessel calibre and the biphasic flow response. Overall, the model developed here offers a high-quality characterisation of dynamic flow and autoregulation in the microvasculature at improved computational efficiency and lays the ground for whole-brain dynamic simulations. [ABSTRACT FROM AUTHOR]

Published

2023

26. Homogenised governing equations for pre-stressed poroelastic composites.

Author

Miller, Laura, Di Stefano, Salvatore, Grillo, Alfio, and Penta, Raimondo

Subjects

*POROELASTICITY, *PARTIAL differential equations, *COMPOSITE materials, *FLUID flow, *EQUATIONS

Abstract

We propose the governing equations for a pre-stressed poroelastic composite material. The structure that we investigate possesses a porous elastic matrix with embedded elastic subphases with an incompressible Newtonian fluid flowing in the pores. Both the matrix and individual subphases are assumed to be linear elastic and pre-stressed. We are able to apply the asymptotic homogenisation technique by exploiting the length-scale separation that exists between the porescale and the overall size of the material (the macroscale). We derive the novel macroscale model which describes a poroelastic composite material where the elastic phases possess a pre-stress. We extend the current literature for poroelastic composites by addressing the role of the pre-stresses in the functional form of the new system of derived partial differential equations and its coefficients. The latter are computed by solving appropriate periodic cell differential problems which encode the specific contribution related to the pre-stresses. The model in the first instance is derived in the most general scenario and then specified for a variety of particular cases which are associated with different macroscale behaviour of materials. [ABSTRACT FROM AUTHOR]

Published

2023

27. Compressive stress improves mechanical properties of mineralized collagen by dynamically regulating its mineralization - a closed-loop regulation mechanism

Author

Yumiao Niu, Jiawen Chen, Ziyao Geng, Wei Wu, Hefang Cai, Chenxin Liu, Peng Cao, Yanping Zhang, Youjun Liu, Aike Qiao, and Tianming Du

Subjects

Biomineralization, Mechano-regulatory, Multiscale modelling, Multi-morphology, Mechanical property, Stress distribution, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Mineralized collagen scaffold is one of the best choices for bone defects treatment, but weak mechanical strength is the main factor restricting its development. Recent studies demonstrated that despite being a fundamental form of mechanical stimulation in human activities, the impact of cyclic compressive stress on collagen mineralization remains unclear, with even less known about the dynamic mechanical mechanism. This study employed cyclic compressive stress to investigate its effect on collagen mineralization. The findings revealed that cyclic compressive strain promotes collagen mineralization by facilitating increased mineral penetration into the collagen and altering mineral morphology on the collagen surface. As the mineral volume fraction of mineralized collagen rises, its elastic modulus also increases. Additionally, the finite element simulation results proved that cyclic compressive stress can impact mineral distribution by affecting their transport and deposition, consequently influencing the stress distribution and regulating mechanical properties of mineralized collagen. Alterations in mechanical properties provide feedback on internal stress distribution, subsequently impacting mineral mineralization. This study achieves a closed-loop study on the mechanical regulated collagen mineralization, offers insight into the mechanism of collagen mineralization, paving the way for further exploration of biomineralization mechanisms and potentially inspiring novel approaches for the fabrication of mineralized collagen scaffolds.

Published

2024

28. Epistemic and Aleatoric Uncertainty Quantification and Surrogate Modelling in High-Performance Multiscale Plasma Physics Simulations

Author

Yudin, Yehor, Coster, David, von Toussaint, Udo, Jenko, Frank, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Mikyška, Jiří, editor, de Mulatier, Clélia, editor, Paszynski, Maciej, editor, Krzhizhanovskaya, Valeria V., editor, Dongarra, Jack J., editor, and Sloot, Peter M.A., editor

Published

2023

29. Multi-scale Modelling of Natural Composites Using Thermodynamics-Based Artificial Neural Networks and Dimensionality Reduction Techniques

Author

Piunno, Giovanni, Stefanou, Ioannis, Jommi, Cristina, Wu, Wei, Series Editor, Ferrari, Alessio, editor, Rosone, Marco, editor, Ziccarelli, Maurizio, editor, and Gottardi, Guido, editor

Published

2023

30. Multiscale Modelling of Bio-composites: Towards Prediction of Their Thermal Conductivity Based on Adequate Knowledge of Their Constituents

Author

Rosa Latapie, S., Lagouin, M., Douk, N., Sabathier, V., Abou-Chakra, A., Amziane, Sofiane, editor, Merta, Ildiko, editor, and Page, Jonathan, editor

Published

2023

31. Temperature-Dependent Behavior of Mature Cement Paste: Creep Testing and Multiscale Modeling

Author

Binder, Eva, Königsberger, Markus, Flores, Rodrigo Díaz, Mang, Herbert A., Hellmich, Christian, Pichler, Bernhard L. A., Jędrzejewska, Agnieszka, editor, Kanavaris, Fragkoulis, editor, Azenha, Miguel, editor, Benboudjema, Farid, editor, and Schlicke, Dirk, editor

Published

2023

32. A Comparison of Multiscale Methods for the Modelling of Carbon-Reinforced Concrete Structures

Author

Mester, Leonie, Klempt, Verena, Wagner, Franz, Scheerer, Silke, Klarmann, Simon, Vakaliuk, Iurii, Curbach, Manfred, Maas, Hans-Gerd, Löhnert, Stefan, Klinkel, Sven, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Ilki, Alper, editor, Çavunt, Derya, editor, and Çavunt, Yavuz Selim, editor

Published

2023

33. Biogas Cleaning via Vacuum Swing Adsorption Using a Calcium Metal–Organic Framework Adsorbent: A Multiscale Simulation Study

Author

Madison Lasich, Victoria T. Adeleke, and Kaniki Tumba

Subjects

vacuum swing adsorption, multiscale modelling, biogas, metal–organic frameworks, steam reforming, Chemistry, QD1-999

Abstract

Purifying biogas can enhance the performance of distributed smart grid systems while potentially yielding clean feedstock for downstream usage such as steam reforming. Recently, a novel anion-pillared metal–organic framework (MOF) was reported in the literature that shows good capacity to separate acetylene from carbon dioxide. The present study assesses the usefulness of this adsorbent for separating a typical biogas mixture (consisting of methane, nitrogen, oxygen, hydrogen, carbon dioxide, and hydrogen sulphide) using a multiscale approach. This approach couples atomistic Monte Carlo simulations in the grand canonical ensemble with the batch equilibrium modelling of a pressure swing adsorption system. The metal–organic framework displays selectivity at low pressures for carbon dioxide and especially hydrogen sulphide. An analysis of adsorption isotherm models coupled with statistical distributions of surface–gas interaction energies determined that both CH4 and CO2 exhibited Langmuir-type adsorption, while H2S displayed Langmuir-type behaviour at low pressures, with increasing adsorption site heterogeneity at high pressures. Batch equilibrium modelling of a vacuum swing adsorption system to purify a CH4/CO2 feedstock demonstrated that such a system can be incorporated into a solar biogas reforming process since the target purity of 93–94 mol-% methane for incorporation into the process was readily achievable.

Published

2024

34. Cauliflowers or how the perseverance of a plant to make flowers produces an amazing fractal structure

Author

Azpeitia, Eugenio, Parcy, François, and Godin, Christophe

Subjects

Biological fractals, Plant development, Multiscale modelling, Cauliflower curds, Flower, Meristems, Plant shapes, Biology (General), QH301-705.5

Abstract

Biological organisms have an immense diversity of forms. Some of them exhibit conspicuous and fascinating fractal structures that present self-similar patterns at all scales. How such structures are produced by biological processes is intriguing. In a recent publication, we used a multi-scale modelling approach to understand how gene activity can produce macroscopic cauliflower curds. Our work provides a plausible explanation for the appearance of fractal-like structures in plants, linking gene activity with development.

Published

2023

35. Big Data in multiscale modelling: from medical image processing to personalized models

Author

Tijana Geroski, Djordje Jakovljević, and Nenad Filipović

Subjects

Big Data, Multiscale modelling, Medical image processing, 3D reconstruction, Computer engineering. Computer hardware, TK7885-7895, Information technology, T58.5-58.64, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract The healthcare industry is different from other industries–patient data are sensitive, their storage needs to be handled with care and in compliance with regulative, while prediction accuracy needs to be high. This fast expansion in medical image modalities and data collection leads to generation of so called “Big Data” which is time-consuming to be analyzed by medical experts. This paper provides an insight into the Big Data from the aspect of its role in multiscale modelling. Special attention is paid to the workflow, starting from medical image processing all the way to creation of personalized models and their analysis. A review of literature regarding Big Data in healthcare is provided and two proposed solutions are described–carotid artery ultrasound image processing and 3D reconstruction, and drug testing on personalized heart models. Related to the carotid artery ultrasound image processing, the starting point is ultrasound images, which are segmented using convolutional neural network U-net, while segmented masks were further used in 3D reconstruction of geometry. Related to the drug testing on personalized heart model, similar approach was proposed, images were used in creation of personalized 3D geometrical model that is used in computational modelling to determine pressure in the left ventricle before and after drug testing. All the aforementioned methodologies are complex, include Big Data analysis and should be performed using servers or high-performance computing. Future development of Big Data applications in healthcare domains offers a lot of potential due to new data standards, rapid development of research and technology, as well as strong government incentives.

Published

2023

36. Multiscale Modelling Methodologies of Lithium-Ion Battery Aging: A Review of Most Recent Developments.

Author

Ali, Mir A., Da Silva, Carlos M., and Amon, Cristina H.

Subjects

MULTISCALE modeling, LITHIUM-ion batteries, ENERGY industries, ENERGY storage

Abstract

Lithium-ion batteries (LIBs) are leading the energy storage market. Significant efforts are being made to widely adopt LIBs due to their inherent performance benefits and reduced environmental impact for transportation electrification. However, achieving this widespread adoption still requires overcoming critical technological constraints impacting battery aging and safety. Battery aging, an inevitable consequence of battery function, might lead to premature performance losses and exacerbated safety concerns if effective thermo-electrical battery management strategies are not implemented. Battery aging effects must be better understood and mitigated, leveraging the predictive power of aging modelling methods. This review paper presents a comprehensive overview of the most recent aging modelling methods. Furthermore, a multiscale approach is adopted, reviewing these methods at the particle, cell, and battery pack scales, along with corresponding opportunities for future research in LIB aging modelling across these scales. Battery testing strategies are also reviewed to illustrate how current numerical aging models are validated, thereby providing a holistic aging modelling strategy. Finally, this paper proposes a combined multiphysics- and data-based modelling framework to achieve accurate and computationally efficient LIB aging simulations. [ABSTRACT FROM AUTHOR]

Published

2023

37. Comparison of neural closure models for discretised PDEs.

Author

Melchers, Hugo, Crommelin, Daan, Koren, Barry, Menkovski, Vlado, and Sanderse, Benjamin

Subjects

*SMALL scale system, *ORDINARY differential equations, *PARTIAL differential equations

Abstract

Neural closure models have recently been proposed as a method for efficiently approximating small scales in multiscale systems with neural networks. The choice of loss function and associated training procedure has a large effect on the accuracy and stability of the resulting neural closure model. In this work, we systematically compare three distinct procedures: "derivative fitting", "trajectory fitting" with discretise-then-optimise, and "trajectory fitting" with optimise-then-discretise. Derivative fitting is conceptually the simplest and computationally the most efficient approach and is found to perform reasonably well on one of the test problems (Kuramoto-Sivashinsky) but poorly on the other (Burgers). Trajectory fitting is computationally more expensive but is more robust and is therefore the preferred approach. Of the two trajectory fitting procedures, the discretise-then-optimise approach produces more accurate models than the optimise-then-discretise approach. While the optimise-then-discretise approach can still produce accurate models, care must be taken in choosing the length of the trajectories used for training, in order to train the models on long-term behaviour while still producing reasonably accurate gradients during training. Two existing theorems are interpreted in a novel way that gives insight into the long-term accuracy of a neural closure model based on how accurate it is in the short term. • Analysis of neural closure models with "derivative fitting" and "trajectory fitting". • Trajectory fitting with discretise-then-optimise gives the best results. • Theoretical support is given by two theorems that bound the long-term error. • Two test problems are investigated: Burgers' and Kuramoto-Sivashinsky equations. [ABSTRACT FROM AUTHOR]

Published

2023

38. Bottom-up multiscale modelling of guard cell walls reveals molecular mechanisms of stomatal biomechanics.

Author

Hojae Yi and Anderson, Charles T.

Subjects

*PLANT cell walls, *ARABIDOPSIS thaliana, *STOMATA, *PLANT morphology, *FINITE element method

Published

2023

39. Stochastic differential equation modelling of cancer cell migration and tissue invasion.

Author

Katsaounis, Dimitrios, Chaplain, Mark A. J., and Sfakianakis, Nikolaos

Abstract

Invasion of the surrounding tissue is a key aspect of cancer growth and spread involving a coordinated effort between cell migration and matrix degradation, and has been the subject of mathematical modelling for almost 30 years. In this current paper we address a long-standing question in the field of cancer cell migration modelling. Namely, identify the migratory pattern and spread of individual cancer cells, or small clusters of cancer cells, when the macroscopic evolution of the cancer cell colony is dictated by a specific partial differential equation (PDE). We show that the usual heuristic understanding of the diffusion and advection terms of the PDE being one-to-one responsible for the random and biased motion of the solitary cancer cells, respectively, is not precise. On the contrary, we show that the drift term of the correct stochastic differential equation scheme that dictates the individual cancer cell migration, should account also for the divergence of the diffusion of the PDE. We support our claims with a number of numerical experiments and computational simulations. [ABSTRACT FROM AUTHOR]

Published

2023

40. Multiscale modelling of irradiation damage behavior in high entropy alloys.

Author

Fusheng Tan, Li Li, Jia Li, Bin Liu, Liaw, Peter K., and Qihong Fang

Subjects

IRRADIATION, NUCLEAR density, MICROSTRUCTURE, ALLOYS, CONTINUUM damage mechanics

Abstract

The increasingly harsh environment of the nuclear reactors and the insurmountable flaws of in-service materials have created an urgent need for the development of the brand-new alloys. For last decade, the high-entropy alloys (HEAs), a novel composition-design strategy, have received much attention due to their promise for the nuclear fields. The application of the multiscale modelling is to explore the irradiation performance and underlying mechanisms of HEAs. Abundant results and data deepen the understanding of the irradiation response, and accelerate the development of advanced irradiation-resistant HEAs. This review introduces the state-of-art multiscale modelling used for studying the irradiated properties of HEAs. Representative irradiation-induced microstructures and properties, as well as damage, are summarized. By strengthening the application of multiscale modelling, a rational design of high irradiation-resistant HEAs is expected. [ABSTRACT FROM AUTHOR]

Published

2023

41. A Genuinely Hybrid, Multiscale 3D Cancer Invasion and Metastasis Modelling Framework

Author

Katsaounis, Dimitrios, Harbour, Nicholas, Williams, Thomas, Chaplain, Mark AJ, and Sfakianakis, Nikolaos

Published

2024

42. Multiscale modelling of woven and knitted fabric membranes

Author

Herath Mudiyanselage, Sumudu and Cirak, Fehmi

Subjects

677, computational homogenisation, multiscale modelling, knitted fabrics, woven fabrics

Abstract

Light-weight fabric membranes have gained increasing popularity over the past years due to their tailorable structural and material performances. These tailorable properties include stretch forming and deep drawing formability that exhibits excellent stretchability and drapeability properties of textiles and textile composites. Since the inception of computerised numerical control for three-dimensional textile-manufacturing machines, technical textiles paved their way to numerous applications, certainly not limited to; aerospace, biomedical, civil engineering, defence, marine and medical industries. Digital interlooping and digital interlacing technology in additive manufacturing greatly advanced the manufacturing processes of textiles. In this work, we consider two branches of technical fabrics, namely plain-woven and weft-knitted. Multiscale modelling is the tool of choice for homogenising periodic structures and has been used extensively to model and analyse the mechanical behaviour of woven and knitted fabrics. But there is a plethora of literature discussing the demerits of such conventional multiscale modelling. These demerits include higher computational costs, rigid numerical models, ineffcient algorithmic computations and inability to incorporate geometric nonlinearities. We propose a data-driven nonlinear multiscale modelling technique to analyse the complex mechanical behaviour of plain-woven and weft-knitted fabrics with a neat extension to fabric material designing. We show how the integration of statistical learning techniques mitigates the weaknesses of conventional multiscale modelling. Moreover, we discuss the avenues that will open in many potential fields with regard to material modelling, structural engineering and textile industries. In the proposed data-driven nonlinear computational homogenisation technique, we effi ciently integrate the microscale and macroscale using Gaussian Process Regression (GPR) statistical learning technique. In the microscale, representative volume elements (RVEs) are modelled using nite deformable isogeometric spatial rods and deformation is homogenised using periodic boundary conditions. This nite deformable rod is profi cient in handling large deformations, rod-to-rod contacts, arbitrary cross-section de finitions and follower loads. Respecting the principle of separation of scales, we construct response databases by applying different homogenised strain states to the RVEs and recording the respective incremental volume-averaged energy values. We use GPR to learn a model using a 5-fold cross-validation technique by optimising the log marginal likelihood. In the macroscale, textiles are modelled as nonlinear orthotropic membranes for which the stresses and material constitutive relations are predicted by the trained GPR model. This coupling between GPR and membrane models is achieved through a systematic and seamless nite element integration using C++ and Python environments. A neat extension to material designing is also discussed with potentials to extend the work into other related fi elds.

Published

2020

43. Dimensionless unified modelling of macroscale electric properties of conductive fibre networks in different regimes

Author

Tim Najuch, Claas Bierwisch, and Takeshi Yamauchi

Subjects

Carbon nanotubes, Nano composites, Electrical properties, Multiscale modelling, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

The electric properties of conductive fibre networks, which can be representative of carbon nanotube networks, are investigated by means of numerical simulations and a dimensionless unified macroscale model is developed. Fibres are represented as rigid chains of discrete element method particles and we compress systems of fibres in a representative volume element periodic in three dimensions. In the used electric resistor network method, the particles are used as discretisation points to construct a system of linear equations linking the particle conductivities to their local electric potentials and in turn allowing for predictions on the electric macroscale properties of the fibre system. A carried out dimensional analysis suggests suitable scaling laws to unify different macroscale fibre systems in two different regimes - a percolating and a conductive regime. The dimensionless macroscale conductance is found to depend on the percolation threshold and percolation probability. It is moreover found that the critical solid volume fraction for rigid fibres is not only dependent on the fibre aspect ratio, but can also depend on the compression height of the system. Additionally, correlations between transmittance and solid volume fractions are found allowing for possibly simple solid volume fraction estimations in experiments.

Published

2023

44. Static analysis and vibration characteristics of some noncarbon nanotubes through atomistic continuum coupled modelling.

Author

Singh, Sandeep, Raj, B. M. Ravi, Mali, Kiran D., and Joshi, Ravindra

Subjects

*INTERRACIAL couples, *NANOTUBES, *FINITE element method, *MULTISCALE modeling, *ATOMIC interactions, *MOLECULAR dynamics

Abstract

A computationally efficient mixed atomistic-continuum coupled modelling is employed to investigate the vibrational characteristics and large deformation static response of some nitride and phosphide-based nanotubes. The atomic entities bond lengths/angles and continuum entities strains/curvature tensors are coupled through the kinematics of quadratic-type Cauchy–Born rule considering curvature effects on the atomic entities. The finite element model is formulated in a cylindrical coordinate system considering geometric nonlinearity through nonlinear strain–displacement relations and material nonlinearity through interatomic potential. The present study is carried out using a four nodded membrane consistent element wherein smoothened interpolation functions derived through least square minimization are used to interpolate the circumferential strain to avoid membrane locking. The atomic interactions are modelled using Tersoff–Brenner type interatomic potential with recently reported new empirical parameters. The effects of length and diameter, boundary conditions and length-to-diameter ratio on the natural frequency of the different nanotubes are also reported. The results obtained through multiscale modelling are also compared with those obtained through molecular dynamics (MD) simulation. The effect of material nonlinearity on the fundamental frequency of the nanotubes under applied pressure is also reported. [ABSTRACT FROM AUTHOR]

Published

2023

45. Big Data in multiscale modelling: from medical image processing to personalized models.

Author

Geroski, Tijana, Jakovljević, Djordje, and Filipović, Nenad

Subjects

BIG data, MULTISCALE modeling, CONVOLUTIONAL neural networks, CAROTID artery ultrasonography, DIAGNOSTIC imaging, LITERATURE reviews, CAROTID intima-media thickness, IMAGE processing

Abstract

The healthcare industry is different from other industries–patient data are sensitive, their storage needs to be handled with care and in compliance with regulative, while prediction accuracy needs to be high. This fast expansion in medical image modalities and data collection leads to generation of so called "Big Data" which is time-consuming to be analyzed by medical experts. This paper provides an insight into the Big Data from the aspect of its role in multiscale modelling. Special attention is paid to the workflow, starting from medical image processing all the way to creation of personalized models and their analysis. A review of literature regarding Big Data in healthcare is provided and two proposed solutions are described–carotid artery ultrasound image processing and 3D reconstruction, and drug testing on personalized heart models. Related to the carotid artery ultrasound image processing, the starting point is ultrasound images, which are segmented using convolutional neural network U-net, while segmented masks were further used in 3D reconstruction of geometry. Related to the drug testing on personalized heart model, similar approach was proposed, images were used in creation of personalized 3D geometrical model that is used in computational modelling to determine pressure in the left ventricle before and after drug testing. All the aforementioned methodologies are complex, include Big Data analysis and should be performed using servers or high-performance computing. Future development of Big Data applications in healthcare domains offers a lot of potential due to new data standards, rapid development of research and technology, as well as strong government incentives. [ABSTRACT FROM AUTHOR]

Published

2023

46. Do specific ion effects influence the physical chemistry of aqueous graphene-based supercapacitors? Perspectives from multiscale QMMD simulations.

Author

Elliott, Joshua D., Chiricotto, Mara, Troisi, Alessandro, and Carbone, Paola

Subjects

*PHYSICAL & theoretical chemistry, *SUPERCAPACITORS, *QUANTUM mechanics, *ION channels, *SUPERCAPACITOR electrodes, *MOLECULAR dynamics, *ION mobility

Abstract

Whether or not specific ion effects determine the charge storage properties of aqueous graphene and graphite-based supercapacitors remains a highly debated topic. In this work we present a multiscale quantum mechanics – classical molecular dynamics (QMMD) investigation of aqueous mono- and divalent salt electrolytes in contact with fully polarizable charged graphene sheets. By computing both the electrochemical double layer (EDL) and quantum capacitance we observe a constant electrode specific capacitance with cationic radii and charge. Counterintuitively, we determine that a switch in the cation adsorption mechanism from inner to outer Helmholtz layers leads to negligible changes to the EDL capacitance, this appears to be due to the robust electronic structure of the graphene electrodes. However, the ability of ions (such as K+) with a relatively low hydration free energy to penetrate the inner Helmholtz plane and adsorb directly on the electrode surface is found to slow their diffusion parallel to the interface. Ions in the outer Helmholtz layer are found to have higher diffusivity at the surface due to their position in ion channels between water layers. Our results show that surface effects such as the surface polarization and the partial dehydration and local structuring of ions on the surface underpin the behaviour of cations at the interface and add a vital new perspective on trends in ion mobilities seen under confinement. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

47. Application of deep neural network learning in composites design

Author

Yinli Wang, Constantinos Soutis, Daisuke Ando, Yuji Sutou, and Fumio Narita

Subjects

material design, topology optimization, mapping, neural networks, material databases, damage analysis, multiscale modelling, material property prediction, industrial internet of things, industry 4.0, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

A timely review is presented on artificial intelligence (AI) and, more specifically, deep learning, which is a subfield of machine learning (ML), applied to the design and behaviour of modern composite materials systems. The use of composites is increasing due to their high specific strength and stiffness, which make them comparable to metals, and their tunable properties that can be altered to produce lightweight materials with efficient structural configurations. Recent studies are examined and discussed, wherein computational tools have been developed that mimic human brain activity to answer questions and solve challenging problems toward characterizing materials behaviour and improving the performance of materials with less effort and cost. The attractiveness of AI comes from its self-learning capability, the faster computer processing time of large datasets, and the potential to yield highly accurate results. However, as a data-driven method, the quantity and quality of data largely affect the accuracy of ML in addition to the need for well-designed AI algorithms and virtual reality models, hence the need to continue the research efforts in this area.

Published

2022

48. Multi-scale analysis of the influence of particle shape on the mechanical response of granular materials

Author

Soltanbeigi, Behzad, Papanicolopulos, Stefanos, and Ooi, Jin

Subjects

DEM, shape, multisphere, superquadric, multiscale modelling, flow, shear, packing, rolling resistance

Abstract

Particle-scale characteristics govern the behaviour of particulate materials at the macroscale. An important factor that dominates the interaction of individual particles is shape, which generates particle interlocking. The resulting geometric interlocking affects the contact force network and the particle motion which lead to change in rheology, as well as stress distribution in the granular system. Accordingly, both numerical, by means of Discrete Element Modelling (DEM) simulations, and experimental, by use of direct shear and silo discharge tests, approaches are considered to determine the influence of particle shape on the mechanical response of granular assemblies at the micro- and macro-scales. The Discrete Element Modelling (DEM) has been utilized to track the interaction of particles and obtain particle-scale information. In DEM simulations, shape factor is addressed through multiple approaches, but most of the studies use spherical particles due to the simplicity of contact detection algorithm resulting in faster simulation times. However, the lack of interlocking in spheres necessitates the need to better capture the shape effect. This is usually done by applying a rotational constraint at contacts, which is referred to as a rolling resistance model. The first part of this study investigates the influence of such implementations, through considering two different rolling resistance models, on the flow characteristics of spherical particles in a silo. Using a coarse-graining technique, the particle-scale DEM data was converted to continuum fields, which allowed a better understanding of stress and density distribution. It is seen that the flow profiles, packing density and stress distribution are highly dependent on the applied rolling resistance. Morevover, the possibility of obtaining comparable bulk response through both models is investigated. Accordingly, a procedure has been suggested to compensate for the differences in the calculation of torque for the two models using a proposed dimensionless parameter. Meanwhile, there exist other approaches which try to simulate the most representative shape by allowing to adjust surface or edge properties and also aspect ratio of a particle. Two of the most widely used approaches, namely 'Multi-spheres' and 'Superquadrics', are employed here and the influence of changing particle surface and edge complexities on the micro- and macro- scale response is assessed for the two cases: direct shear test and silo flow. For direct shear test, the density of the sample determines the level of change in bulk response due to the shape factor. In the case of silo flow, beyond a certain level of shape complexity, the edge and surface properties show no significant influence on the material flow. The comparison between the two methods of shape description provides useful insights into the particle shape effect during shearing and flow. Additionally, it is not yet fully known whether introducing a rolling resistance in spherical particle contacts can adequately capture the granular friction in non-spherical particles. In this respect, the response of spherical particles with restricted rotational freedom is compared to the particles simulated using the multi-sphere and superquadric approaches. The results indicate that certain characteristics of the particles with complex shapes can be replicated with spherical particles, such as: angle of repose (AoR), dilative behaviour and shear strength (only with the Elastic-Plastic Spring-Dashpot model). Lastly, in order to validate the numerical observations, experiments were performed including angle of repose, Jenike shear and silo discharge (at 1g and also different accelerations with flat-bottom and wedge shape hopper). Additionally, the validity of Beverloo's assumption for predicting the mass flow rate and velocity profiles inside the silo (at higher accelerations) is analysed in detail (Beverloo suggests that the mass flow rate at increased acceleration is proportional to the square root of the gravity). The results from AoR, Jenike and 1g silo discharge showed a great dependency on the particle shape factor. Comparing the mass flow rate at 1g with those of at different gravitational accelerations (in normalized form) suggest the validity of Beverloo's approach only in case of spherical particles. Additionally, analysis of the normalized velocity of the particles shows that while the mass flow region for the spherical particles follows Beverloo's assumption, the region near the outlet diverges to some extent. Furthermore, particles with shape irregularity show different flow profiles in presence of high gravitational forces compared to those of the 1g case. In summary, this thesis presents an extensive investigation of the particle shape parameter on DEM simulation of granular assemblies. On the numerical side, the influence of different rolling resistance models on the interaction of the spherical particles is clarified. Moreover, the effect of the particle surface and edge characteristics of multi-sphere and superquadrics shapes is quantified at both micro and macroscales. The comparison of the three shape descriptors suggests that spherical particles together with rolling resistance can mimic several key mechanical properties of complex shape particles. Finally, the experimental observations have provided further insights into the particle flow at different gravitational stress states. Results suggest that it is yet challenging to predict the flow profiles of the discharging granular material with complex shapes, at different gravitational levels.

Published

2019

49. Advances in computational engineering for sustainable energy generation

Author

Hewitt, Sam, Revell, Alistair, Afgan, Imran, and Margetts, Lee

Subjects

621.042, Fluid-structure interaction, High performance computing, Multiphysics, Multiscale modelling

Abstract

Over the past decades, the scientific and engineering communities have spent a lot of time on the development of sustainable energy solutions, to combat the adverse effects that non-renewable energy sources are having on the climate. Computational modelling has played a significant role in the advancement and evolution of novel technologies to capture energy from renewable sources. The capabilities of computational models to simulate complex physics is growing with improved numerical modelling techniques and increasing levels of computing power. The purpose of this work is to develop the predictive modelling capabilities of computational simulation tools for sustainable energy applications. This is achieved through the development of a multiphysics tool to solve the coupled interaction of a fluid and a structure. The numerical tool is used to study the fundamental fluid dynamics processes that occur when a fluid interacts with a flexible structure. Further to this, an advanced structural model, capable of predicting damage in dynamically loaded structures was developed and evaluated. Testing and evaluation of the numerical tools developed, highlighted their capability to effectively use high performance computing services to model complex coupled physics problems. Numerical studies of a flexible structure highlighted a number of phenomena. Including, the emergence of a periodic deflection of the structure and the destabilising effects of the structures motion on the flow field. This work will be of interest to researchers and scientists interested in the current capabilities of academic computer aided engineering software for extreme scale computers.

Published

2019

50. Effects of the graphene on the mechanical properties of fibre reinforced polymer : a numerical and experimental study

Author

Pawlik, Marzena, Lu, Yiling, and Dean, Angela

Subjects

620.1, mechanical properites, fibre reinforced polymer, multiscale modelling, graphene nanoplatelets, Finite element analysis, interphase, flexural properties, fracture toughness, inverse problem, parameters identification, optimisation

Abstract

Mechanical properties of carbon fibre reinforced polymer (CFRP) are greatly affected by interphase between fibre and matrix. Coating fibre with nanofillers, i.e. graphene nanoplatelets (GNPs) or carbon nanotubes (CNTs) has suggested improving the interphase properties. Although the interphase is of small thickness, it plays an important role. Quantitative characterisation of the interphase region using an experimental technique such as nanoindentation, dynamic mechanical mapping remains challenging. More recently, computational modelling has become an alternative way to study the effects of interphase on CFRP properties. Simulation work of CFRP reinforced with nanofillers mainly focuses on CNTs grown on the fibre surface called fuzzy fibre reinforced polymers. Modelling work on the effects of GNPs on CFRP properties is rather limited. This project aims to study numerically and experimentally the effects of the nano-reinforced interphase on mechanical properties of CFRP. A multiscale model was developed to study the effects of the GNPs reinforced interphase on the elastic properties of CFRP laminate. The effective material properties of the reinforced interphase were determined by considering transversely isotropic features of GNPs and various orientation. The presence of GNPs in the interphase enhances the elastic properties of CFRP lamina, and the enhancement depends on its volume fraction. The incorporation of randomly orientated GNPs in the interphase increased longitudinal and transverse lamina moduli by 5 and 12 % respectively. While aligned GNPs in the interphase yielded less improvement. The present multiscale modelling was able to reproduce experimental measurements for GNPs reinforced CFRP laminates well. The multiscale model was also proven successful in predicting fuzzy fibre reinforced polymer. Moreover, the interphase properties were inversely quantified by combining with the multiscale model with some standard material testing. A two-step optimisation process was proposed, which involved the microscale and macroscale modelling. Based on the experimental data on flexural modulus, the lamina properties were derived at macroscale modelling, which were later used to determine the interphase properties from the optimisation at the microscale. The GNPs reinforced interphase modulus was 129.1 GPa which is significantly higher than epoxy coated carbon fibre of 60.51 GPa. In the experiment, a simple spraying technique was proposed to introduce GNPs and CNTs into the CFRP. Carbon fibre prepreg was sprayed with a nanofillers-ethanol solution using an airbrush. The extremely low volume fraction of nanofillers introduced between prepreg plies caused a noticeable improvement in mechanical properties, i.e. 7% increase in strain energy release. For the first time, the GNPs-ethanol-epoxy solution was sprayed directly on the carbon fibre fabric. Resultant nano-reinforced interphase created on fibre surface showed moderate improvement in samples flexural properties. In conclusion, a multiscale modelling framework was developed and tested. The GNPs reinforced interphase improved the mechanical properties of CFRP. This enhancement depended on the orientation and volume fraction of GNPs in the interphase. Spraying was a cost-effective method to introduce nanofillers in CFRP and showed huge potential for the scale-up manufacturing process. In a combination of multiscale framework and optimisation process, the nanofillers reinforced interphase was for the first time determined. This framework could be used to optimise the development process of new fibre-reinforced composites.

Published

2019