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Ben Feringa

Bernard Lucas "Ben" Feringa (born 18 May 1951) is a organic chemist specializing in and , best known for his pioneering design and synthesis of , including the first light-driven rotary in 1999, work that earned him the 2016 shared with Jean-Pierre Sauvage and J. Fraser Stoddart. Born in Barger-Compascuum, a small village in the northeastern , Feringa grew up as the second of ten children on his family's farm, an environment that instilled in him a deep appreciation for nature and exploration. He attended elementary and high school at the Katholiek Drents College before enrolling at the in 1969 to study , where he earned his in 1978 under the supervision of Hans Wynberg, focusing on . Following his doctorate, Feringa worked as a research scientist at in the and the from 1979 to 1984, where he contributed to advancements in . In 1984, he joined the faculty at the as an assistant professor, becoming a full professor of in 1988 and succeeding Wynberg as chair of the department. He was appointed Jacobus H. van 't Hoff of Molecular Sciences in 2004 and later served as an Academy Professor for the Royal Academy of Arts and Sciences. His research has centered on , asymmetric , and the creation of responsive molecular systems, including chiral overcrowded alkenes in 1976 and chiral phosphoramidites for in 1996, leading to breakthroughs in light-activated molecular switches and motors with potential applications in , sensors, and . Feringa's contributions have been widely recognized beyond the Nobel Prize, including the in 2004, the Koerber European Science Award in 2003, the ACS Arthur C. Cope Scholar Award in 2015, being knighted by in 2008, an honorary doctorate from in 2024, the FIAS Senior Fellow Laureatus in 2025, and the Evonik Friedrich Bergius Lecture Award in 2025; he was elected a in 2020. Married to Betty Feringa with three daughters, he has described his scientific pursuits as an "adventure into the unknown," emphasizing the joy of discovery in designing novel chemical systems.

Early Life and Education

Personal Background

Bernard Lucas "Ben" Feringa was born on May 18, 1951, in Barger-Compascuum, a small village in the province of the near the border. He was the second of ten children born to Geert Feringa, a farmer, and Elizabeth (Lies) Hake, both from poor Roman Catholic families; his parents had married in 1949. Feringa grew up on the in a self-sufficient rural community, where he spent his early years helping his father with daily tasks such as tending chickens, working in the garden, and cutting , which instilled practical problem-solving skills and a deep appreciation for natural processes. His fascination with the complexities of —observing animal behaviors, growing tall sunflowers, and pondering the origins of —sparked an early desire for knowledge that shaped his intellectual curiosity. This rural environment, combined with high school exposure to chemistry under an inspiring teacher, fueled his interest in scientific experimentation and led him to pursue formal studies at the . Feringa is married to Betty Feringa, whom he wed in 1977 while both were in ; she worked for many years in a management role at the University Medical Center before retiring. Together, they have raised three daughters and currently reside in Paterswolde, a village near in the .

Academic Training

Ben Feringa enrolled at the in 1969 to study , where he developed an early fascination with molecular structure and during his undergraduate years. He completed his in in 1974 with distinction, conducting his thesis research under the supervision of Professor Hans Wynberg on asymmetric coupling of using iron analogs of chiral camphor-based diketonate ligands, a project rooted in techniques. Feringa then pursued his at the same under Wynberg's guidance, earning the degree in 1978 with a dissertation titled "Asymmetric Oxidation of : Atropisomerism and Optical Activity," which explored stereochemical phenomena including the design of chiral overcrowded alkenes and their antipodal effects, contributing foundational insights to asymmetric synthesis in . Throughout his studies, Feringa gained hands-on exposure to laboratory techniques in photochemistry, particularly through investigations of photoisomerization in overcrowded alkenes, which laid the groundwork for his future innovations in light-driven molecular systems.

Professional Career

Industry Experience

Following his PhD in stereochemistry from the University of Groningen in 1978, Ben Feringa began his industry career at Royal Dutch Shell's Shell Laboratories in Amsterdam as a research chemist, focusing on organic synthesis, oxidation processes, and photochemistry from 1979 to 1982. In 1982–1983, he transferred to Shell Biosciences Laboratories in Sittingbourne, UK, where he worked as a research chemist in bioorganic chemistry, contributing to projects on herbicide development through total synthesis and chemical biology approaches. He returned to Amsterdam in 1983–1984 as project leader for homogeneous catalysis at Shell Research Laboratories, overseeing efforts in catalytic oxidations, novel ligand and catalyst design, and photo-redox catalysis. During this period, Feringa's research emphasized practical applications of in and . These projects bridged fundamental chemistry with commercial viability, particularly in . Feringa holds over 30 patents in total, many centered on applied . These inventions highlighted his expertise in designing functional molecules for real-world scalability. This industry experience equipped Feringa with profound insights into scalable synthesis and process chemistry, motivating his transition back to academia in 1984 to pursue fundamental research while retaining a focus on practical impacts. The skills gained at Shell profoundly influenced his later academic endeavors, enabling collaborations with industry partners like DSM and Philips.

Academic Positions

In 1984, Ben Feringa joined the University of Groningen as a lecturer in organic chemistry, marking his return to academia after industry experience. He was promoted to full professor in 1988, succeeding Professor Hans Wynberg as chair of organic chemistry. In this role, Feringa established a prominent research laboratory focused on synthetic organic chemistry, which evolved into interdisciplinary efforts through the founding of the Center for Systems Chemistry at the University of Groningen. He also served as director of the Stratingh Institute for Chemistry from 2003 to 2011, overseeing its development into a key hub for chemical research. In 2003, Feringa was appointed Jacobus H. van 't Hoff Distinguished Professor of Molecular Sciences, a position he continues to hold as of 2025, recognizing his leadership in advancing molecular-level innovations. Under his guidance, the laboratory secured major funding, including two (ERC) Advanced Grants in 2008 and 2016, which supported the assembly of multidisciplinary teams exploring complex chemical systems. These resources enabled the supervision of over 100 students, fostering a legacy of mentorship in and . Feringa's academic output includes over 800 peer-reviewed publications, reflecting the sustained impact of his Groningen-based research program. His work has garnered an h-index of 164 (as of 2025), underscoring the broad influence of his contributions to the field.

Research Contributions

Molecular Switches and Motors

Ben Feringa's pioneering work on molecular switches and motors began with the development of light-driven systems capable of unidirectional rotary motion, marking a breakthrough in synthetic molecular machines. In 1999, his group reported the first artificial light-driven unidirectional molecular rotary motor based on chiral overcrowded alkenes, a class of molecules featuring sterically congested double bonds that induce helical twisting. These motors operate through a four-step rotary cycle that achieves complete 360° rotation without reversing direction, powered solely by visible light. This innovation demonstrated that synthetic molecules could mimic the directional motion of biological motors like ATP synthase, opening the door to programmable nanomachines. The mechanism of the 1999 motor relies on alternating photochemical and thermal steps. The cycle starts with the stable (P)-trans isomer, which undergoes photoisomerization upon irradiation with UV (λ ≈ 365 nm) to form the unstable (M)-cis isomer, twisting the helical due to steric . This is followed by a thermal helix inversion, where the relaxes to the more stable (P)-cis isomer, overcoming an barrier (ΔG‡ ≈ 95 kJ/mol at ). A second photoisomerization with UV (λ > 280 nm) produces the (M)-trans isomer, and another thermal helix inversion (ΔG‡ ≈ 102 kJ/mol) completes the , returning to the initial state while advancing 360° unidirectionally. The overcrowded core, typically consisting of two fluorenyl-like aromatic units connected by a central , ensures and prevents bidirectional rotation. This design exploits the input from to bias against , with each full rotation confirmed via showing sequential depletion and reformation of isomers. Subsequent advancements refined these motors for greater autonomy and functionality. In 2011, Feringa's team developed autonomous multicomponent systems, such as a four-wheeled propelled by four integrated rotary motors via , which exhibited directed motion on surfaces. Building on this, 2014 efforts introduced molecular walkers capable of linear translational motion, inspired by proteins, where rotary motor units drive stepwise displacement along a track through sequential photo- and thermal steps, with energy barriers tuned to ~90 kJ/mol for efficient inversion under ambient conditions (e.g., ΔG‡ = RT ln(k), where k is the rate constant for inversion). These second-generation motors featured optimized overcrowded scaffolds with lower, more uniform thermal barriers ( ~5.7 ms for inversion), enabling faster rotation rates exceeding 1 MHz at elevated temperatures. Feringa's contributions to were recognized with the 2016 , shared with Jean-Pierre Sauvage and , specifically for the " and synthesis of molecular machines." The award highlighted the 1999 rotary motor as a seminal achievement, emphasizing its role in establishing light as a clean, controllable energy source for nanoscale mechanics.

Nanotechnology Applications

Feringa's research extended the principles of unidirectional rotary motors, first demonstrated in 1999, to practical by constructing the world's first in 2011. This molecule features four wheels, each composed of a light-driven rotary based on overcrowded alkenes, enabling autonomous directional motion across a surface when propelled by from a tip. The nanocar's allows for controlled at the single-molecule level, covering distances up to 12 nanometers in defined paths, highlighting the potential for surface-bound molecular in nanoscale devices. In applications, Feringa's group integrated synthetic rotary molecular motors into block copolymer assemblies to create responsive polymersomes for targeted release. These systems encapsulate therapeutic agents and release them upon activation by , with the motor's disrupting the vesicle to enable delivery in a controlled manner. This light-responsive approach offers spatiotemporal precision, suitable for applications such as where localized activation minimizes off-target effects. Feringa's chiral molecular switches and motors have enhanced catalysis in by providing dynamic control over . In a seminal example, a light-driven motor was incorporated into a catalyst for the asymmetric conjugate addition of diethylzinc to , allowing reversible switching between (P)- and (M)- configurations that inverted the enantioselectivity from 38% to -92% . These atropisomer-based systems, leveraging restricted in overcrowded alkenes, improve efficiency in asymmetric reactions by modulating the chiral environment on demand, with applications in synthesizing enantiopure . Recent advancements up to 2025 include the integration of Feringa's molecular motors with DNA nanostructures to fabricate hybrid nanomachines. For instance, a photoswitchable DNA hairpin incorporating a rotary motor as the bridgehead enables reversible control of DNA hybridization through light-induced conformational changes, facilitating the assembly and disassembly of DNA-based scaffolds. This hybrid approach supports the development of dynamic DNA origami platforms for complex nanomachinery, with ongoing exploration of self-assembling systems for advanced functionalities. In 2024, formylation of overcrowded alkene motors boosted rotation speed and efficiency, enabling MHz-range operation at room temperature and broadening applications in responsive materials. Additionally, all-visible-light-driven first-generation motors based on salicylidene Schiff bases were developed, operating solely with wavelengths >400 nm without UV.

Awards and Honors

Nobel Prize and Major Awards

In 2016, Bernard L. Feringa was awarded the , shared with Jean-Pierre Sauvage and Sir J. Fraser Stoddart, "for the design and synthesis of ." Feringa's contribution focused on the development of a light-driven rotary , enabling controlled unidirectional rotation at the molecular scale, which advanced the field of artificial . The Nobel ceremony took place on December 10, 2016, in , where Feringa delivered his prize lecture titled "Molecular Machines and Motors: Towards Synthetic Life," highlighting the potential of these systems for applications. In 2003, Feringa received the Körber European Science Award for his innovative research in and . Earlier, in 2004, Feringa received the , the ' most prestigious scientific award, granted by the Organisation for Scientific Research () for his groundbreaking work in synthetic , particularly in molecular switches and . The prize, often called the "Dutch Nobel," included €1.5 million to support further research and recognized Feringa's overall contributions to and dynamic molecular systems. In 2005, Feringa was honored with the Prelog Medal from , awarded for outstanding achievements in , reflecting his pioneering synthesis of chiral molecules and light-responsive systems. This medal, named after Nobel laureate , underscored Feringa's impact on asymmetric and molecular design. Feringa earned the Arthur C. Cope Late Career Scholars Award from the in 2015, one of the society's highest honors in , for his innovative contributions to and . The award highlighted his development of switchable catalysts and motors, with a held at the ACS national meeting in . In 2017, Feringa received the Centenary Prize from the Royal Society of Chemistry, recognizing his exceptional creativity and impact in chemistry over the society's first century, specifically for advancing molecular switches and motors. This prestigious award included a £5,000 prize and a medal, presented at the RSC Awards Ceremony in , emphasizing the global influence of his work on dynamic molecular systems. In 2025, Feringa was awarded the Evonik Friedrich Bergius Lecture Award for advancing sustainable chemistry through molecular design.

Other Recognitions

In recognition of his contributions to molecular sciences, Ben Feringa was knighted in the in 2008 by Queen . Following the announcement of his , he was elevated to Commander in the same order in 2016. Feringa has held prominent memberships in several prestigious academies. He was elected to the Royal Netherlands Academy of Arts and Sciences in 2006 and served as its vice-president from 2011 to 2016. In 2020, he became a Foreign Member of the , acknowledging his international impact in chemistry. He is also a Foreign Honorary Member of the American Academy of Arts and Sciences. In 2024, he was elected a member of the . Feringa has received multiple honorary degrees from leading universities. These include doctorates from the in 2019, the in 2019, in in 2023, and The in 2024, each honoring his pioneering work in and . In 2025, Feringa received the FIAS Senior Fellow Laureatus Award from the Institute for Advanced Studies.

Professional Activities

Editorial and Advisory Roles

Ben Feringa has held significant leadership positions in scientific publishing, particularly with the Royal Society of Chemistry (RSC). He serves as Chair of the Editorial Board for Chemistry World, the flagship magazine of the RSC, where he oversees content direction and promotes advancements in chemical sciences. Additionally, Feringa was the Founding Scientific Editor for Organic & Biomolecular Chemistry, an RSC journal focused on synthetic and related fields, from 2002 to 2006, helping establish its scope and editorial standards. Feringa has served on several prestigious editorial advisory boards, influencing processes in top-tier chemistry journals. These have included the Journal of the American Chemical Society (), advising on and submissions, and Angewandte Chemie International Edition (), contributing to evaluations in synthetic and areas. He has also been a member of the Editorial Advisory Board of Chemical Communications (RSC), supporting rigorous standards for rapid communications in chemical research, including and molecular systems. Through these roles, Feringa has helped shape practices, emphasizing innovation and interdisciplinary approaches in and related disciplines. In addition to editorial roles, Feringa holds several current advisory positions. Since 2021, he has been a member of the Board of Governors at the Okinawa Institute of Science and Technology Graduate University (OIST). He serves on the Scientific Advisory Board of the Institute of Science and Technology (ISTA). Feringa is also a Supervisory Board Member of the Center Oncode. Extending his mentorship beyond academia, Feringa has chaired key international conferences, fostering global collaboration on and . Notable examples include the European Symposium on (ESOC-12) in 2001, the Burgenstock Conference in 2009, and the ArmChemFront Conference in 2013, where he organized symposia highlighting light-driven s and their applications. These events in the 2010s drew leading researchers and advanced discussions on dynamic molecular systems, drawing on his expertise in molecular motor research. No major chaired roles post-2020 are documented in available records.

Industry and Collaborative Ventures

Ben Feringa co-founded the contract research company Selact in the 2000s, focusing on services for the , leveraging his expertise in asymmetric and chiral synthesis to develop selectors for enantiomerically pure compounds essential in . Selact was later integrated into Kiadis Pharma, a firm specializing in cell-based therapies, which was acquired by in 2021 for approximately €308 million to advance its natural killer cell platform. Feringa has been actively involved in , holding over 30 that translate his into practical applications, particularly in light-responsive materials for and . Notable examples include on redox-switchable materials that respond to for controlled molecular states, with potential uses in optical devices and systems. Another key filing covers catalysts for , enabling efficient production of chiral pharmaceuticals, which supports industrial-scale synthesis in the chemical and biotech sectors. In terms of international collaborations, Feringa was appointed Honorary Professor at in 2017, fostering joint research initiatives in and sustainable chemistry; he continued engaging with the institution, including a visit in December 2024 to discuss advancements in photoresponsive systems. He has also participated in EU-funded consortia through multiple (ERC) Advanced Grants since 2008, supporting collaborative projects on dynamic and their nanotech applications, such as autonomous rotary motors for and .

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