Abstract
Exploring across the current frontiers of chemical sciences there is vast uncharted territory to experience the joy of discovery. Far beyond Nature’s design, the creative power of synthetic chemistry provides unlimited opportunities to realize our own molecular world as we experience every day with products ranging from drugs to displays that sustain modern society. In their practice of the art of building small, chemists have shown amazing success in the past decades. Moving from molecules to dynamic molecular systems the fundamental challenge is how to control and exploit motion at the nanoscale.
Among the major challenges ahead in the design of complex artificial molecular systems is the control over dynamic functions and responsive far-from-equilibrium behaviour. A major goal is to gain control over translational and rotary motion. In this presentation the focus is on my journey in the world of molecular switches and motors, the process of discovery and my personal experiences through my scientific career. In particular, I will address how fundamental questions and molecular beauty have guided me on this journey.
Biography
Ben L. Feringa obtained his PhD degree at the University of Groningen in the Netherlands under the guidance of Professor Hans Wynberg. After working as a research scientist at Shell in the Netherlands and the UK, he was appointed lecturer and in 1988 full professor at the University of Groningen and named the Jacobus H. van 't Hoff Distinguished Professor of Molecular Sciences in 2004. He was elected Foreign Honorary member of the American Academy of Arts and Sciences. He is a member of the Royal Netherlands Academy of Sciences as well as a member of the Council of the Royal Society of Chemistry. In 2008 he was appointed Academy Professor and he was knighted by Her Majesty the Queen of the Netherlands. Feringa’s research has been recognized with numerous awards including the Körber European Science Award (2003), the Spinoza Award (2004), the Prelog gold medal (2005), the Norrish Award of the ACS (2007), the Paracelsus medal (2008), the Chirality medal (2009), the RSC Organic Stereochemistry Award (2011), the Humboldt award (2012), the Nagoya gold medal (2013), the ACS Cope Scholar Award (2015), the Chemistry for the Future Solvay Prize (2015), the August-Wilhelm-von-Hoffman Medal (2016), The 2016 Nobel prize in Chemistry and the Tetrahedron Prize (2017).
Feringa’s research interest includes stereochemistry, organic synthesis, asymmetric catalysis, molecular switches and motors, self-assembly, molecular nanosystems and photopharmacology.
About the Schrödinger Lecture
The Erwin Schrödinger Lecture is an annual event named after the noted Austrian scientist. Schrödinger was a theoretical physicist and a significant contributor to the wave theory of matter, a form of quantum physics. He mathematically devised an equation of wave mechanics that bears his name. He was a co-recipient of the 1933 Nobel Prize for physics. Today he is popularly known for the paradox of Schrödinger’s cat.
The lecture will be followed by a reception and an opportunity to talk to some of Imperial's researchers. This event is free to attend.
Lecture, Great Hall, Sherfield Building: 17.30 - 18.30
Reception, Queen's Tower Rooms, Sherfield Building: 18.30 - 20.00
Exploring across the current frontiers of chemical sciences there is vast uncharted territory to experience the joy of discovery. Far beyond Nature’s design, the creative power of synthetic chemistry provides unlimited opportunities to realize our own molecular world as we experience every day with products ranging from drugs to displays that sustain modern society. In their practice of the art of building small, chemists have shown amazing success in the past decades. Moving from molecules to dynamic molecular systems the fundamental challenge is how to control and exploit motion at the nanoscale.
Among the major challenges ahead in the design of complex artificial molecular systems is the control over dynamic functions and responsive far-from-equilibrium behaviour. A major goal is to gain control over translational and rotary motion. In this presentation the focus is on my journey in the world of molecular switches and motors, the process of discovery and my personal experiences through my scientific career. In particular, I will address how fundamental questions and molecular beauty have guided me on this journey.
Biography
Ben L. Feringa obtained his PhD degree at the University of Groningen in the Netherlands under the guidance of Professor Hans Wynberg. After working as a research scientist at Shell in the Netherlands and the UK, he was appointed lecturer and in 1988 full professor at the University of Groningen and named the Jacobus H. van 't Hoff Distinguished Professor of Molecular Sciences in 2004. He was elected Foreign Honorary member of the American Academy of Arts and Sciences. He is a member of the Royal Netherlands Academy of Sciences as well as a member of the Council of the Royal Society of Chemistry. In 2008 he was appointed Academy Professor and he was knighted by Her Majesty the Queen of the Netherlands. Feringa’s research has been recognized with numerous awards including the Körber European Science Award (2003), the Spinoza Award (2004), the Prelog gold medal (2005), the Norrish Award of the ACS (2007), the Paracelsus medal (2008), the Chirality medal (2009), the RSC Organic Stereochemistry Award (2011), the Humboldt award (2012), the Nagoya gold medal (2013), the ACS Cope Scholar Award (2015), the Chemistry for the Future Solvay Prize (2015), the August-Wilhelm-von-Hoffman Medal (2016), The 2016 Nobel prize in Chemistry and the Tetrahedron Prize (2017).
Feringa’s research interest includes stereochemistry, organic synthesis, asymmetric catalysis, molecular switches and motors, self-assembly, molecular nanosystems and photopharmacology.
About the Schrödinger Lecture
The Erwin Schrödinger Lecture is an annual event named after the noted Austrian scientist. Schrödinger was a theoretical physicist and a significant contributor to the wave theory of matter, a form of quantum physics. He mathematically devised an equation of wave mechanics that bears his name. He was a co-recipient of the 1933 Nobel Prize for physics. Today he is popularly known for the paradox of Schrödinger’s cat.
The lecture will be followed by a reception and an opportunity to talk to some of Imperial's researchers. This event is free to attend.
Lecture, Great Hall, Sherfield Building: 17.30 - 18.30
Reception, Queen's Tower Rooms, Sherfield Building: 18.30 - 20.00