Digitalisation Of Chemistry Is An Innovative Approach To Further Understand And Explore The Complexities Of The Chemical World. This Involves The Use Of Digital Technology, Such As Computers, Software, And Robotics, To Either Complement Or Replace Certain Laboratory Techniques. It Is Allowing Chemists To Build Intricate 3D Models, Calculate Intricate Molecular Structures, Simulate Different Chemical Reactions, And Study Earth’s Ancient Systems. Digitalisation Of Chemistry Is Resulting In New And Improved Ways Of Performing Research. By Leveraging High-Performance Computing, Chemists Are Able To Run Simulations Of Various Chemical Reactions Much Faster And More Accurately Than Experiments Alone. In Addition, Chemists Can Now Create Realistic 3D Models Of Molecular Structures Aided By Advanced Computing Algorithms, Making It Easier To Visualise And Interpret Data. Digitalisation Of Chemistry Has Extended Beyond The Laboratory, Becoming An Essential Part Of Large-Scale Production Processes. Optimised Robotic Automated Synthesis Systems Allow For More Efficient Production Of Chemicals, Such As Pharmaceutical Intermediates, And Help To Reduce The Cost Of These Materials. In The Future, Digital Chemistry Will Help To Reduce The Environmental Impact Of Synthetic Chemistry Processes, Through The Development Of Methods That Involve Fewer Waste Products And Are More Energy-Efficient. Furthermore, It Will Enable Chemists To Continue Pushing The Boundaries Of Research By Combining Experiments And Simulations To Design New Materials With Desirable Physical And Chemical Properties. Ultimately, This Could Revolutionise Advanced Materials Applications, Such As Medical Devices, Electronics, And Insulation. By Embracing Digitalisation Of Chemistry, Chemists Around The World Can Continue To Push The Limits Of What Can Be Done With Chemical Research. By Using High-Performance Computing, They Can Increase The Speed And Accuracy Of Simulations And Develop More Advanced 3D Models. This Will Enable Them To Find Solutions To Complex Chemical Problems, Resulting In A Multitude Of Innovative Materials And Products.
Title : Rational design of battery cathode materials
Kyeongjae Cho, University of Texas at Dallas, United States
Title : Pharmaceutical chemistry studies of novel biologics and drugs for chronic obstructive pulmonary disease
Yong Xiao Wang, Albany Medical College, United States
Title : Theoretical modeling in organic nanophotonics: Processes and devices
Alexander Bagaturyants, Retired, Israel
Title : Hot atom chemistry - Past, present and future
Shree Niwas Chaturvedi, Centre for Aptitude Analysis and Talent Search, India
Title : Chemical engineering of vanadium, titanium or chromium zeolites for application in environmental catalysis
Stanislaw Dzwigaj, Sorbonne Université, France
Title : Distal functionalization via transition metal catalysis
Haibo Ge, Texas Tech University, United States