Upper-Year Materials Chemistry Computational Modeling Module for Organic Display Technologies

WebMO is a web‐based interface for all major quantum chemistry programs. WebMO uses a server–client architecture that installs on a single server or cluster computer and provides access to state‐of‐the‐art computational chemistry programs from a standard web browser. The web interface provides a 3‐D molecular editor, pre‐defined calculations types, job submission and monitoring, visualization of results, and user management tools. Barriers to using state‐of‐the‐art computational chemistry in teaching and research are minimized through WebMO's universal accessibility, its intuitive and uniform interface to all programs, no software to install on client computers, and support for multiple users with a single instance. Applications of WebMO throughout the undergraduate curriculum are provided. The extensible open‐architecture design allows for collaboration among educators, researchers, quantum chemistry program developers, and the WebMO interface developers. This article is categorized under: Computer and Information Science > Visualization Electronic Structure Theory > Ab Initio Electronic Structure Methods Software > Quantum Chemistry

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“…WebMO can be used to model nanotubes, 2‐D materials, and organic semi‐conductors (Figure 17) 101–103 :…”

Section: Education Across the Undergraduate Curriculummentioning

confidence: 99%

WebMO: Web‐based computational chemistry calculations in education and research

Polik

Schmidt

2021

WIREs Comput Mol Sci

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“…In the classroom, computational methods are usually applied for chemical system simulations, such as DFT calculations or molecular dynamics simulations to predict or interpret experimental results, or for data analysis from experimental results. Experiences like these have been published in previous issues of this journal. − There are also two remarkable courses for teaching computational skills to chemistry students by Weiss , and Menke . Both of them cover topics such as an introduction to programming with Python, performing simple simulations, and analyzing data from tables, spectra, and images.…”

Section: Introductionmentioning

confidence: 99%

A Gentle Introduction to Machine Learning for Chemists: An Undergraduate Workshop Using Python Notebooks for Visualization, Data Processing, Analysis, and Modeling

et al. 2021

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Machine learning, a subdomain of artificial intelligence, is a widespread technology that is molding how chemists interact with data. Therefore, it is a relevant skill to incorporate into the toolbox of any chemistry student. This work presents a workshop that introduces machine learning for chemistry students based on a set of Python notebooks and assignments. Python, one of the most popular programming languages, is open source, free to use, and has plenty of learning resources. The workshop is designed for students without previous experience in programming, and it aims for a deeper understanding of the complexity of concepts in programming and machine learning. The examples used correspond to real data from physicochemical characterizations of wine, a content that is of interest for students. The contents of the workshop are introduction to Python, basic statistics, data visualization, and dimension reduction, classification, and regression.

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“…[3][4][5] Although some of the aforementioned aspects can in principle be studied even with simpler methodologies such as classical force fields, quantum chemical calculations with state-of-the-art software packages allow students to get hands-on experience on more advanced topics such as molecular orbitals, chemical bonding, energetics, 6 thermodynamics, 7,8 reaction mechanisms, 9 and various spectroscopies. [10][11][12][13][14] The ability to interpret and understand chemical phenonema with the help of quantum chemical calculations is a valuable skill in every chemists' professional life. Quantum chemical research methods have been used extensively in the chemical industry for decades already.…”

Section: Introductionmentioning

confidence: 99%

Free and Open Source Software for Computational Chemistry Education

Lehtola

Karttunen

2021

Preprint

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Long in the making, computational chemistry for the masses [J. Chem. Educ. 1996, 73, 104] is finally here. We point out the existence of a variety of free and open source software (FOSS) packages for computational chemistry that offer a wide range of functionality all the way from approximate semiempirical calculations with tight-binding density functional theory to sophisticated ab initio wave function methods such as coupled-cluster theory, both for molecular and for solid-state systems. By their very definition, FOSS packages allow usage for whatever purpose by anyone, meaning they can also be used in industrial applications without limitation. Also, FOSS software has no limitations to redistribution in source or binary form, allowing their easy distribution and installation by third parties. Many FOSS scientific software packages are available as part of popular Linux distributions, and other package managers such as pip and conda. Combined with the remarkable increase in the power of personal devices—which rival that of the fastest supercomputers in the world of the 1990s—a decentralized model for teaching computational chemistry is now possible, enabling students to perform reasonable modeling on their own computing devices, in the bring your own device (BYOD) scheme. In addition to the programs’ use for various applications, open access to the programs’ source code also enables comprehensive teaching strategies, as actual algorithms’ implementations can be used in teaching. We discuss the availability and use of various FOSS quantum chemistry packages and demonstrate what kinds of calculations are feasible with these programs, assuming only extremely modest computational resources. Our examples confirm that FOSS software enables decentralized approaches to computational chemistry education within the BYOD scheme, affording a democratization of the science of computational chemistry as well.

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Upper-Year Materials Chemistry Computational Modeling Module for Organic Display Technologies

Cited by 14 publications

References 47 publications

WebMO: Web‐based computational chemistry calculations in education and research

WebMO: Web‐based computational chemistry calculations in education and research

A Gentle Introduction to Machine Learning for Chemists: An Undergraduate Workshop Using Python Notebooks for Visualization, Data Processing, Analysis, and Modeling

Free and Open Source Software for Computational Chemistry Education

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