Iterative Supervised Principal Component Analysis-Driven Ligand Design for Regioselective Ti-Catalyzed Pyrrole Synthesis

See, Xin Yi; Reiner, Benjamin C.; Wen, Xuelan; Wheeler, T. Alexander; Klein, Channing; Goodpaster, Jason D.; Tonks, Ian A.

doi:10.26434/chemrxiv.12284378

Cited by 10 publications

(10 citation statements)

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“…490 When points are distant in a feature space but similar in property, they also provide evidence that shallow, transparent models (e.g., MLR or KRR) would struggle to use these features to obtain a suitable prediction of properties. Thus, selection of optimal features by PCA has been carried out 491 as a feature selection technique, including in an iterative fashion, 492 for ML model training on data sets, as discussed further in section 4.4.…”

Section: Unsupervised Learningmentioning

confidence: 99%

Computational Discovery of Transition-metal Complexes: From High-throughput Screening to Machine Learning

et al. 2021

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Transition-metal complexes are attractive targets for the design of catalysts and functional materials. The behavior of the metal−organic bond, while very tunable for achieving target properties, is challenging to predict and necessitates searching a wide and complex space to identify needles in haystacks for target applications. This review will focus on the techniques that make high-throughput search of transition-metal chemical space feasible for the discovery of complexes with desirable properties. The review will cover the development, promise, and limitations of "traditional" computational chemistry (i.e., force field, semiempirical, and density functional theory methods) as it pertains to data generation for inorganic molecular discovery. The review will also discuss the opportunities and limitations in leveraging experimental data sources. We will focus on how advances in statistical modeling, artificial intelligence, multiobjective optimization, and automation accelerate discovery of lead compounds and design rules. The overall objective of this review is to showcase how bringing together advances from diverse areas of computational chemistry and computer science have enabled the rapid uncovering of structure−property relationships in transition-metal chemistry. We aim to highlight how unique considerations in motifs of metal−organic bonding (e.g., variable spin and oxidation state, and bonding strength/nature) set them and their discovery apart from more commonly considered organic molecules. We will also highlight how uncertainty and relative data scarcity in transition-metal chemistry motivate specific developments in machine learning representations, model training, and in computational chemistry. Finally, we will conclude with an outlook of areas of opportunity for the accelerated discovery of transition-metal complexes.

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Section: Unsupervised Learningmentioning

confidence: 99%

Computational Discovery of Transition-metal Complexes: From High-throughput Screening to Machine Learning

et al. 2021

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“…The functional groups involved in the initial screen included boronic acid pinacol ester ( Initial reaction conditions were based off from previously successful conditions for TMS-substituted alkyne substrates, 13 using chloride-based Ti catalysts that are typically most robust for [2 + 2 + 1] reactions. 22,23 All new heteroatom-substituted reactions resulted in signicantly lower yields than the corresponding TMS-substituted alkyne reactions, highlighting the challenges of conserving a reactive transmetallating agent through another organometallic transformation.…”

Section: Resultsmentioning

confidence: 99%

Synthesis of pentasubstituted 2-aryl pyrroles from boryl and stannyl alkynes via one-pot sequential Ti-catalyzed [2 + 2 + 1] pyrrole synthesis/cross coupling reactions

2020

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“…In the past decade, homogeneous catalysis experienced a rise in new optimization strategies, such as data-driven modeling of both reactivity and selectivity with descriptors [17,18], and the systematic application of ML is becoming more common (Box 2) [19]. Specifically, the use of multivariate linear regression combined with the development of descriptors allowed the rapid design of catalysts to improve yields, reaction rates, and (enantio)selectivities, as demonstrated by several experimental applications [20][21][22]. These approaches can be utilized more readily in homogeneous catalysis as computing of parameter sets is more straightforward when good models of the active catalysts exist.…”

Section: Box 1 An Overview Of Homogeneous Catalysismentioning

confidence: 99%

Navigating through the Maze of Homogeneous Catalyst Design with Machine Learning

Gomes

Pollice

Aspuru‐Guzik

2021

Trends in Chemistry

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Microkinetic models of homogeneous catalytic reactions are constructed using ab initio simulations to gain insight into mechanisms, rationalize catalyst performance, and inspire catalyst design.Using a data-driven approach, the classical linear free-energy relationships are extended to multiple linear regression to study both reactivity and selectivity of homogeneous catalysts and build models to rationalize important interactions.Volcano plots are demonstrated as a general analysis framework when comparing potential energy surfaces of related catalytic reactions to extract decisive parameters and visualize breaks in mechanisms.Nonlinear regression models including random forests, support-vector machines, Gaussian processes, and artificial neural networks are applied to predict reaction yields, enantioselectivity, and activation energies of catalytic reactions based on both experimental and computational data.

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Iterative Supervised Principal Component Analysis-Driven Ligand Design for Regioselective Ti-Catalyzed Pyrrole Synthesis

Cited by 10 publications

References 0 publications

Computational Discovery of Transition-metal Complexes: From High-throughput Screening to Machine Learning

Computational Discovery of Transition-metal Complexes: From High-throughput Screening to Machine Learning

Synthesis of pentasubstituted 2-aryl pyrroles from boryl and stannyl alkynes via one-pot sequential Ti-catalyzed [2 + 2 + 1] pyrrole synthesis/cross coupling reactions

Navigating through the Maze of Homogeneous Catalyst Design with Machine Learning

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