This Perspective outlines the author's vision for electric-field-aided chemistry by 2050. It discusses the application of oriented-external electric fields (OEEFs) in chemical reactions, experimental validations, and methods to generate OEEFs, such as pH-switchable charges, ionic additives, and water droplets. A key principle is the "reaction-axis rule," which defines the optimal direction for OEEF application to enhance reaction rates. The article also highlights the use of OEEFs in continuous-flow systems, which could scale to molar concentrations. The author envisions that by 2050, OEEF usage will transform chemical education and the art of molecule synthesis. The Perspective covers theoretical predictions, experimental tests, and practical applications of OEEFs in various reactions, including Diels-Alder, S_N2, and others. It emphasizes the potential of OEEFs to control reactivity, selectivity, and spin-state transitions. The author also discusses the scalability of OEEF techniques, such as continuous-flow systems and water droplets, which could revolutionize chemical synthesis. The article concludes with a vision of OEEFs shaping the future of chemistry, influencing education, and enabling new synthetic methods. The author also addresses potential pitfalls in experimental setups and recommends quantum chemical calculations to validate OEEF effects. Overall, the Perspective presents a comprehensive view of the future of electric-field-aided chemistry by 2050.This Perspective outlines the author's vision for electric-field-aided chemistry by 2050. It discusses the application of oriented-external electric fields (OEEFs) in chemical reactions, experimental validations, and methods to generate OEEFs, such as pH-switchable charges, ionic additives, and water droplets. A key principle is the "reaction-axis rule," which defines the optimal direction for OEEF application to enhance reaction rates. The article also highlights the use of OEEFs in continuous-flow systems, which could scale to molar concentrations. The author envisions that by 2050, OEEF usage will transform chemical education and the art of molecule synthesis. The Perspective covers theoretical predictions, experimental tests, and practical applications of OEEFs in various reactions, including Diels-Alder, S_N2, and others. It emphasizes the potential of OEEFs to control reactivity, selectivity, and spin-state transitions. The author also discusses the scalability of OEEF techniques, such as continuous-flow systems and water droplets, which could revolutionize chemical synthesis. The article concludes with a vision of OEEFs shaping the future of chemistry, influencing education, and enabling new synthetic methods. The author also addresses potential pitfalls in experimental setups and recommends quantum chemical calculations to validate OEEF effects. Overall, the Perspective presents a comprehensive view of the future of electric-field-aided chemistry by 2050.