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Machine Learning For Chemists: Practical Applications - AD-TEAM - 11-17-2025
![[Image: cb9ab7c81ea40d2a9d93226f9dc24cfe.jpg]](https://i126.fastpic.org/big/2025/1117/fe/cb9ab7c81ea40d2a9d93226f9dc24cfe.jpg)
Machine Learning For Chemists: Practical Applications
Published 9/2025
MP4 | Video: h264, 1920x1080 | Audio: AAC, 44.1 KHz
Language: English | Size: 2.39 GB | Duration: 3h 58m
Use Data Science to solve chemistry problems: predict molecular properties, classify compounds, and resolve spectra
[b]What you'll learn[/b]
Understand the fundamentals of machine learning and how they apply to chemical problems. Confidently handle real-world chemical datasets for ML applications.
Select and implement supervised and unsupervised learning algorithms for chemistry. Apply regression, classification, and clustering methods to chemical data.
Interpret model performance using evaluation metrics relevant to chemical research. Visualize chemical datasets and model predictions effectively
Use Python libraries (scikit-learn, pandas, numpy) for ML tasks in chemistry, Apply ML to predict molecular properties such as Solubility, HOMO-LUMO gap
Gain practical skills to integrate ML into chemistry. Use ML-driven insights to support research publications and projects.
Separate the spectra (infra-red spectra) of each compound from a mixture of spectra using Machine learning approaches
Requirements
This course is designed for chemists and researchers who want to apply machine learning to chemical problems. To follow along smoothly, some basic knowledge of Python-such as variables, loops, functions, and working with libraries like NumPy or pandas is highly valuable. No advanced coding skills are required, but a beginner-level familiarity with Python will help you focus on the chemistry and machine learning concepts without getting stuck on programming basics. In case you are absolute beginner, i have added some videos by the end of the course where you can get bsic idea. Alternatively, i have a couple of courses on python for chemists which will guide you thoroughly on how to use python in chemistry
[b]Description[/b]
Machine Learning is transforming the way chemists analyze data, predict properties, and accelerate discoveries in various sub-disciplines of Chemistry. This course is designed to give you the practical skills and confidence to apply machine learning directly to chemical problems.Starting from the basics, you will learn how to preprocess chemical datasets, explore molecular descriptors, and choose the right algorithms for prediction and classification. Step by step, you will apply regression, classification, and clustering methods to real-world chemical examples. You will gain hands-on experience with Python libraries such as NumPy, pandas, matplotlib, and scikit-learn-without being overwhelmed by unnecessary theory.Throughout the course, we'll connect machine learning concepts to chemistry applications: predicting molecular properties (solubility) , analyzing spectra, classifying compounds, resolving complex spectra of mixture to individual spectra and grouping similar molecules. By the end, you will not only understand how these algorithms work but also know how to implement them for your own research and projects.This is not just a programming course-it's a transformation in how you approach chemistry. You will leave with a solid foundation in applying ML to chemical data and the ability to contribute to modern, data-driven research.Note: Basic knowledge of Python is recommended for this course
Overview
Section 1: Introduction
Lecture 1 Introduction
Lecture 2 Machine Learning (Theory Lecture)
Lecture 3 Key Concepts of Machine Learning (Target, model training)
Lecture 4 Machine Learning Types, a graphical presentation
Section 2: Supervised Learning: Predicitn boiling points of alcohols through Machine Learni
Lecture 5 Regression method of supervised learning (Theory)
Lecture 6 Linear Regression example of Boiling Pont of alcohols explained
Lecture 7 Linear Regression Model equation
Lecture 8 Analyzing dataset of boiling points of alcohols in NotePad
Lecture 9 Placing the dataset file in Google Drive and opening Google Drive
Lecture 10 Setting up Google Colab Environment
Lecture 11 Mounting Google Drive in Colab
Lecture 12 Reading dataset of boiling point through Pandas and reading head.
Lecture 13 Deta Preprocessing approaches
Lecture 14 Cleaning the dataset before ML
Lecture 15 Feature Engineering
Lecture 16 Feature Selection
Lecture 17 plotting boiling point against possible features (no ML)
Lecture 18 Importing libraries for supervised machine learning
Lecture 19 Defining features and Target
Lecture 20 Completing the code for predicting boiling points
Lecture 21 Model evaluation Metrices (Theory)
Lecture 22 Evaluating the model and plotting the results
Lecture 23 Effect of test size on the performance of ML Model
Lecture 24 Graph of predicted vs actual boiling points
Lecture 25 Residual Plot
Lecture 26 Predicting bp of an unkonw alcohol
Lecture 27 Model II of Regression (Ridge Model): with standard Scalar for boiling Point
Lecture 28 Robust Scalar for Ridge Model and coefficients
Lecture 29 Outliers and How to handle them
Lecture 30 Model III: Lasso Model of Regression for predicing Boiling Points of Alchohols
Lecture 31 Cross Validation (Theory)
Lecture 32 K-fold Cross Validation In Machine Learning
Lecture 33 Scalars (minmax, standard and Robust) and effect on coefficients of features
Section 3: Predicting solubliity of compounds using Random Forest model of supervised ML
Lecture 34 Installing RdKit library in Google Colab
Lecture 35 Importing Libraries required for the problem
Lecture 36 Extracting features as descriptors for molecules using smiles in RdKit
Lecture 37 Loading dataset and preprocessing the data
Lecture 38 Grid search and the best grid values for the problem
Lecture 39 Model evaluation and the performance
Lecture 40 Plotting the results (feature importance, residual frequency, etc)
Section 4: Supervised Machine Learning for Classification of Compounds
Lecture 41 Supervised Learning Classification (Theory) I
Lecture 42 Supervised Learning Classification (Theory) II
Lecture 43 Classification of compounds example explained
Lecture 44 Predicting the classification of compounds (importing Libraries)
Lecture 45 Evaluation of the model throgh Confusion Matrix
Section 5: Unsupervised Learning: Part 1: Clustering of samples from Wine data
Lecture 46 Dimensionality Reduction (Principal component analysis PCA)
Lecture 47 Clustering example explained in theory
Lecture 48 Analyzing Wine data
Lecture 49 Unsupervised learning Clustering import libraries
Lecture 50 Clustering, Plotting PCA1 against PCA2
Lecture 51 Silhoutte Score
Lecture 52 DBSCAN Approach for clustering
Section 6: Unsupervised Learning for blind signal separation
Lecture 53 Blind Signal Separation example explanation
Lecture 54 FAST ICA 1: importing libraries and data of mixture spectrum in python
Lecture 55 FAST ICA II: Completing the code for independent component analysis
Lecture 56 Plotting two extracted spectrum from the mixture spectrum in parallel
Lecture 57 Plotting all extracted spectra from the mixture spectrum
Lecture 58 Identifying cyclohexane by comparing the extracted spectrum with the reference
Lecture 59 Identifying all components of the mixture by comparison with the reference spect
Lecture 60 Plotting all four spectra in one figure
Lecture 61 Plotting all four spectra in one figure (2nd approach)
Graduate students and researchers in chemistry or chemical engineering,Data scientists and ML engineers interested in scientific applications,Academic researchers wanting to integrate machine learning into chemical research,Computational chemistry professionals seeking to expand their ML toolkit,Laboratory managers implementing data-driven approaches to experimental design
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