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47 results on '"Zhang, Ruochun"'

1. Chrono DEM-Engine: A Discrete Element Method dual-GPU simulator with customizable contact forces and element shape

Author

Zhang, Ruochun, Tagliafierro, Bonaventura, Heuvel, Colin Vanden, Sabarwal, Shlok, Bakke, Luning, Yue, Yulong, Wei, Xin, Serban, Radu, and Negrut, Dan

Subjects
Computer Science - Computational Engineering, Finance, and Science, Computer Science - Software Engineering, Mathematics - Numerical Analysis, J.2
Abstract

This paper introduces DEM-Engine, a new submodule of Project Chrono, that is designed to carry out Discrete Element Method (DEM) simulations. Based on spherical primitive shapes, DEM-Engine can simulate polydisperse granular materials and handle complex shapes generated as assemblies of primitives, referred to as clumps. DEM-Engine has a multi-tier parallelized structure that is optimized to operate simultaneously on two GPUs. The code uses custom-defined data types to reduce memory footprint and increase bandwidth. A novel "delayed contact detection" algorithm allows the decoupling of the contact detection and force computation, thus splitting the workload into two asynchronous GPU streams. DEM-Engine uses just-in-time compilation to support user-defined contact force models. This paper discusses its C++ and Python interfaces and presents a variety of numerical tests, in which impact forces, complex-shaped particle flows, and a custom force model are validated considering well-known benchmark cases. Additionally, the full potential of the simulator is demonstrated for the investigation of extraterrestrial rover mobility on granular terrain. The chosen case study demonstrates that large-scale co-simulations (comprising 11 million elements) spanning 15 seconds, in conjunction with an external multi-body dynamics system, can be efficiently executed within a day. Lastly, a performance test suggests that DEM-Engine displays linear scaling up to 150 million elements on two NVIDIA A100 GPUs., Comment: 38 pages, 30 figures, 9 tables. This preprint is submitted to Computer Physics Communications

Published
2023

3. A GPU-accelerated simulator for the DEM analysis of granular systems composed of clump-shaped elements

Author

Zhang, Ruochun, Heuvel, Colin Vanden, Schepelmann, Alexander, Rogg, Arno, Apostolopoulos, Dimitrios, Chandler, Samuel, Serban, Radu, and Negrut, Dan

Subjects
Computer Science - Computational Engineering, Finance, and Science, J.2
Abstract

We discuss the use of the Discrete Element Method (DEM) to simulate the dynamics of granular systems made up of elements with nontrivial geometries. The DEM simulator is GPU accelerated and can handle elements whose shape is defined as the union with overlap of diverse sets of spheres with user-specified radii. The simulator can also handle complex materials since each sphere in an element can have its own Young's modulus $E$, Poisson ratio $\nu$, friction coefficient $\mu$, and coefficient of restitution CoR. To demonstrate the simulator, we produce a "digital simulant" (DS), a replica of the GRC-1 lunar simulant. The DS follows an element size distribution similar but not identical to that of GRC-1. We validate the predictive attributes of the simulator via several numerical experiments: repose angle, cone penetration, drawbar pull, and rover incline-climbing tests. Subsequently, we carry out a sensitivity analysis to gauge how the slope vs. slip curves change when the element shape, element size, and friction coefficient change. The paper concludes with a VIPER rover simulation that confirms a recently proposed granular scaling law. The simulation involves more than 11 million elements composed of more than 34 million spheres of different radii. The simulator works in the Chrono framework and utilizes two GPUs concurrently. The GPU code for the simulator and all numerical experiments discussed are open-source and available on GitHub for reproducibility studies and unfettered use and distribution., Comment: Main text 28 pages, including 27 figures. Submitted to Engineering with Computers

Published
2023

4. Using a Bayesian-Inference Approach to Calibrating Models for Simulation in Robotics

Author

Unjhawala, Huzaifa Mustafa, Zhang, Ruochun, Hu, Wei, Wu, Jinlong, Serban, Radu, and Negrut, Dan

Subjects
Computer Science - Robotics, I.6.5
Abstract

In robotics, simulation has the potential to reduce design time and costs, and lead to a more robust engineered solution and a safer development process. However, the use of simulators is predicated on the availability of good models. This contribution is concerned with improving the quality of these models via calibration, which is cast herein in a Bayesian framework. First, we discuss the Bayesian machinery involved in model calibration. Then, we demonstrate it in one example: calibration of a vehicle dynamics model that has low degree of freedom count and can be used for state estimation, model predictive control, or path planning. A high fidelity simulator is used to emulate the ``experiments'' and generate the data for the calibration. The merit of this work is not tied to a new Bayesian methodology for calibration, but to the demonstration of how the Bayesian machinery can establish connections among models in computational dynamics, even when the data in use is noisy. The software used to generate the results reported herein is available in a public repository for unfettered use and distribution., Comment: 19 pages, 42 figures

Published
2023
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22. Molecular and optical signatures of photochemical transformation of dissolved organic matter: Nonnegligible role of suspended particulate matter in urban river

Author

Hou, Jingyi, Zhang, Ruochun, Ge, Jinfeng, Ma, Chao, Yi, Yuanbi, Qi, Yulin, Li, Si-Liang, Hou, Jingyi, Zhang, Ruochun, Ge, Jinfeng, Ma, Chao, Yi, Yuanbi, Qi, Yulin, and Li, Si-Liang

Abstract

Natural dissolved organic matter (DOM) is one of the Earth's dynamic carbon pools and a key intermediate in the global carbon cycle. Photochemical processes potentially affect DOM composition and activity in surface water. Suspended particulate matter (SPM) is the integral component of slow-moving rivers, and holds the potential for photochemical reactivity. To further investigate the influence of SPM on DOM photochemical transformation, this study conducted experiments comparing samples with and without SPM irradiated under simulated sunlight. Surface water samples from slow-moving urban rivers were collected. DOM optical characteristics and molecular features obtained by Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS) were investigated. Photolabile DOM was enriched in unsaturated and highly aromatic terrestrial substances. Photoproduced DOM had low aromaticity and was dominated by saturated aliphatics, protein-like substances, and carbohydrates. Study results indicated that the presence of SPM had a nonnegligible impact on the molecular traits of DOM, such as composition, molecular diversity, photolability, and bioavailability during photochemical reactions. In the environment affected by SPM, molecules containing heteroatoms exhibit higher photosensitivity. SPM promotes the photochemical transformation of a wider range of chemical types of photolabile DOM, particularly nitrogen-containing compounds. This study provides an essential insight into the more precise simulation of photochemical reactions of DOM influenced by SPM occurring in natural rivers, contributing to our understanding of the global carbon cycle from new theoretical perspectives.

Published
2023

31. Characterization of Lignin Compounds at the Molecular Level

Author

Zhang, Ruochun, Qi, Yulin, Ma, Chao, Ge, Jinfeng, Hu, Qiaozhuan, Yue, Fu-Jun, Li, Si-Liang, and Volmer, Dietrich

Subjects
540 Chemie und zugeordnete Wissenschaften, structural information, ddc:540, ionization, technology, industry, and agriculture, food and beverages, lignin, macromolecular substances, complex mixtures, data processing, mass spectrometry
Abstract

Lignin is the second most abundant natural biopolymer, which is a potential alternative to conventional fossil fuels. It is also a promising material for the recovery of valuable chemicals such as aromatic compounds as well as an important biomarker for terrestrial organic matter. Lignin is currently produced in large quantities as a by-product of chemical pulping and cellulosic ethanol processes. Consequently, analytical methods are required to assess the content of valuable chemicals contained in these complex lignin wastes. This review is devoted to the application of mass spectrometry, including data analysis strategies, for the elemental and structural elucidation of lignin products. We describe and critically evaluate how these methods have contributed to progress and trends in the utilization of lignin in chemical synthesis, materials, energy, and geochemistry.

Published
2021

45. On the Use of Half-Implicit Numerical Integration in Multibody Dynamics

Author

Fang, Luning, Kissel, Alexandra, Zhang, Ruochun, and Negrut, Dan

Abstract

This work highlights the use of half-implicit numerical integration in the context of the index three differential algebraic equations (DAEs) of multibody dynamics. Although half-implicit numerical integration is well established for ordinary differential equations problems, to the best of our knowledge, no formal discussion covers its use in the context of index three DAEs of multibody dynamics. We wish to address this since when compared to fully implicit methods, half-implicit integration has two attractive features: (i) the solution method does not require the computation of the Jacobian associated with the constraint, friction, contact, or user-defined applied forces; and (ii) the solution is simpler to implement. Moreover, for nonstiff problems, half-implicit numerical integration yields a faster solution. Herein, we outline the numerical method and demonstrate it in conjunction with three mechanisms. We report on convergence order behavior and solution speed. The Python software developed to generate the results reported is available as open in a public repository for reproducibility studies.

Published
2023
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46. Prediction of second-order rate constants between carbonate radical and organics by deep neural network combined with molecular fingerprints

Author

Sun, Peizhe, Ma, Huixin, Li, Shangyu, Yao, Hong, and Zhang, Ruochun

Abstract

Carbonate radical is among the most important environmental relevant reactive species which govern the transformation and fate of pharmaceutical contaminants (PCs). However, reaction rate constants between carbonate radical and most of the PCs have not been experimentally determined, and quantitative structural-activity relationships (QSARs) have not been established for rate estimation. This study applied MaxMin data processing method and used molecular fingerprints (MF) as the input of a deep neural network (DNN) to predict the rate constants between carbonate radical and organic compounds. MF parameters and the hyper-structure of the DNN were adjusted to yield satisfactory accuracy of rate prediction. The vector length of 512 bits with radius of 1 for MF and 5 hidden layers gave the best performance. The optimized MaxMin-MF-DNN model was compared with some of the most commonly used QSARs and machine learning methods, including random data splitting, molecular descriptors, supporting vector machine, decision tree, etc. Results showed that the MF-DNN model out-performed the other methods by more than 10% increase in prediction accuracy. Applying this MF-DNN model, we estimated reaction rates between carbonate radical and pharmaceuticals used in human medicine (1576) and veterinary practice (390). Among them, 46 drugs were identified as fast-reacting compounds, suggesting the important relations of their environmental fate with carbonate radical.

Published
2021
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47. Degradation of Organic Micropollutants in UV/NH 2 Cl Advanced Oxidation Process.

Author

Sun P, Meng T, Wang Z, Zhang R, Yao H, Yang Y, and Zhao L

Subjects
Hydrogen Peroxide, Oxidation-Reduction, Photolysis, Retrospective Studies, Ultraviolet Rays, Water Pollutants, Chemical, Water Purification
Abstract

Monochloramine (NH 2 Cl) can be irradiated by UV to create an advanced oxidation condition (i.e., UV/NH 2 Cl) for the elimination of organic micropollutants (OMPs) from source water. However, information in retrospective studies was scarce on how UV/NH 2 Cl performance would be affected by the water matrix and OMP molecular structures. In this study, the degradation of five representative OMPs, including triclosan, carbamazepine, sulfamethoxazole, estradiol (E2), and ethinylestradiol (EE2), was examined in different water matrices. All OMPs were rapidly removed by UV/NH 2 Cl but exhibited different degradation mechanisms. Although •OH, •Cl, and direct photolysis mainly contributed to the overall degradation of OMPs in buffered nanopure water, the contribution of reactive nitrogen species (RNS) generated from the photolysis of NH 2 Cl was not negligible in the degradation of E2 and EE2. A phenolic group was identified as the moiety reactive toward RNS. Based on quantitative analysis of the impact on OMP degradation from cosolutes (including Cl - , HCO 3 - , NOM) as well as pH and NH 2 Cl doses, we developed a kinetic model for the prediction of OMP degradation in complex water matrices. In environmental water matrices, the performance and radical contributions in UV/NH 2 Cl and UV/H 2 O 2 systems were taken into comparison, which showed faster degradation of OMPs and a more significant contribution of CO 3 •- in the UV/NH 2 Cl process.

Published
2019
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