Your search keyword '"Morse, Peter"' showing total 3 results

1. Towards More Efficient, Greener Syntheses through Flow Chemistry.

Author

Lummiss, Justin A.M., Morse, Peter D., Beingessner, Rachel L., and Jamison, Timothy F.

Subjects

*FLOW chemistry, *PHOTOCHEMISTRY, *CHEMICAL amplification, *SUSTAINABLE chemistry, *ENVIRONMENTAL chemistry

Abstract

Technological advances have an important role in the design of greener synthetic processes. In this Personal Account, we describe a wide range of thermal, photochemical, catalytic, and biphasic chemical transformations examined by our group. Each of these demonstrate how the merits of a continuous flow synthesis platform can align with some of the goals put forth by the Twelve Principles of Green Chemistry. In particular, we illustrate the potential for improved reaction efficiency in terms of atom economy, product yield and reaction rates, the ability to design synthetic process with chemical and solvent waste reduction in mind as well as highlight the benefits of the real-time monitoring capabilities in flow for highly controlled synthetic output. [ABSTRACT FROM AUTHOR]

Published

2017

2. Enhanced Reaction Efficiency in Continuous Flow.

Author

Morse, Peter D., Beingessner, Rachel L., and Jamison, Timothy F.

Subjects

*CONTINUOUS flow reactors, *CHEMICAL reactions, *PHOTOCHEMISTRY, *INTERMEDIATES (Chemistry), *FLOW chemistry

Abstract

Continuous flow reactors are enabling tools that can significantly benefit chemical reactions, especially those that are path length dependent (e.g., photochemical), mixing or transport dependent (e.g., gas-liquid), exothermic, or utilize hazardous or unstable intermediates. In this review, it is demonstrated how the nearly instantaneous mixing, exceptionally fast mass transfer, safe access to high temperatures and pressures, and high surface area to volume ratio can be leveraged to improve product yield, reaction rates and/or selectivity. By showcasing five synthetic methodologies examined by our group, it is hoped that the reader will gain an appreciation of the accessible and transformative nature of flow chemistry for improving existing transformations, enabling rapid optimization, and for developing new methodologies that depend on precise parameter controls. [ABSTRACT FROM AUTHOR]

Published

2017

3. Towards More Efficient, Greener Syntheses through Flow Chemistry

Author

Peter D Morse, Justin A. M. Lummiss, Rachel L. Beingessner, Timothy F. Jamison, Massachusetts Institute of Technology. Department of Chemistry, Jamison, Timothy F, Morse, Peter D, Lummiss, Justin A.m., and Beingessner, Rachel L

Subjects

Green chemistry, Personal account, 010405 organic chemistry, Continuous flow, Process (engineering), Chemistry, General Chemical Engineering, General Chemistry, Flow chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, 0104 chemical sciences, Reaction rate, Yield (chemistry), Atom economy, Materials Chemistry, Organic chemistry, Biochemical engineering

Abstract

Technological advances have an important role in the design of greener synthetic processes. In this Personal Account, we describe a wide range of thermal, photochemical, catalytic, and biphasic chemical transformations examined by our group. Each of these demonstrate how the merits of a continuous flow synthesis platform can align with some of the goals put forth by the Twelve Principles of Green Chemistry. In particular, we illustrate the potential for improved reaction efficiency in terms of atom economy, product yield and reaction rates, the ability to design synthetic process with chemical and solvent waste reduction in mind as well as highlight the benefits of the real-time monitoring capabilities in flow for highly controlled synthetic output.

Published

2017