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Physics and Astronomy

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Prof Frank Vollmer

Professor, FInstP

 (Streatham) 4771

 01392 724771

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Professor in BiophysicsMolecular & Quantum Sensors and Systems

Living Systems Institute,

Department of Physics & Astronomy, University of Exeter

Frank Vollmer is Professor in Biophysics at the University of Exeter, UK. He obtained his PhD in `Physics & Biology' from the Rockefeller University in NYC, USA, in 2004. He was Rowland Fellow at Harvard University from 2004 to 2009, Scholar-in-Residence at the Wyss Institute at Harvard in 2010, Group Leader (untenured Associate Professor) at the Max Planck Institute for the Science of Light in Germany from 2011-2016 and Instructor in Medicine at Brigham and Women’s Hospital/Harvard Medical School where he directed a satellite laboratory from 2011-2016. Since 2016 he is Professor in Biophysics at the School of Physics, University of Exeter, UK. He received the Royal Society Wolfson Research Merit Award in 2017 and in 2021 the Rosalind Franklin Medal and Prize from the Institute of Physics (IoP). Since 2021 he is Fellow of the IoP.

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Lab web site:


2017- 2020    Associate Director (International and Development), Living Systems Institute, Exeter

2016-             Professor, University of Exeter, UK

2010-­2016      Associate Professor/Group Leader (W2), Max Planck Institute for the Science of Light, Germany

2011-­2016      Instructor in Medicine, Brigham & Women’s Hospital, Harvard Medical School, USA

2013--2016     Privatdozent (Lecturer), Friedrich-Alexander University Erlangen-Nuremberg, Germany

2009-­2010      Scholar-in-Residence, Wyss Institute, Harvard University, Boston, USA

2004-­2009      Fellow, Rowland Institute at Harvard University, Boston, USA


2013                Venia Legendi (Habilitation) in Physics, Friedrich-Alexander University
2004                PhD, Physics & Biology, Rockefeller University
                         New York City, USA
1998                MSc, Biophysical Chemistry, Leibnitz University
                         Hannover, Germany
1995                BSc, Biochemistry, University of Bayreuth

Honors and Awards

2021                Fellow Institute of Physics, FInstP, IoP

2021                Rosalind Franklin Medal and Prize, IoP

2018                EPSRC Established Career Fellow

2017                Royal Society Wolfson Research Merit Award

2011                R01 Grant Award, National Institutes of Health, NIGMS, USA

2010                Max Planck Research Group Award (MPRG)

2004                Rowland Fellowship, Harvard University (

2000                PhD Fellowship, Boehringer Ingelheim Fonds (

Professional Activities and Work Experience

2011--2017      Associate Editor, Optics Express

2013--2014      Organizer “Micro-cavity Biosensing” Conference in Bad Honnef, Germany

2005--2009      Micro- & Nanofabrication, Center for Nanoscale Systems, Harvard, USA

1992--1993      Medical-Technical Assistant, Katharinen-Hospital Suttgart, Germany

Referee (selected): Science, Nature Photonics, Nature Nanotechnology, Nature Biotechnology, Nature Materials, Physical Review Letters, Optics Letters, Applied Physics Letters, ACS Nano, Biophysical Journal, Lab on a Chip, Optics Express, Humboldt, DFG, ERC, ISERD

Recent Grant Funding

Research Current Awards

Awarded Date

Project Description

Total Award Value

19 Jan 2021

CoA Physics of Life Molecular Mechanics of Enzymes


14 Oct 2020

EPSRC Core Equipment Award 2020 - Sub Award - Exeter Biomaterials Optical Characterisation Suite


9 Oct 2020

EPSRC - Exeter Biomaterials Optical Characterisation Suite - EBOC  Core Equipment Award 2020/21 - Additional Award


8 Oct 2020

EPSRC - Exeter Biomaterials Optical Characterisation Suite - EBOC  Core Equipment Award 2020/21


24 Jul 2020



15 Apr 2019

Physics of Life - Mechanobiology of Enzymes


9 Sep 2018

A Optical Single Molecule Scanner of Protein Motion


24 Nov 2016

Exploring Nanoscale Dynamics Of Proteins


16 Nov 2016

ULTRACHIRAL / H2020 / FET open 2016 / Vollmer



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Copyright Notice: Any articles made available for download are for personal use only. Any other use requires prior permission of the author and the copyright holder.

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  • Roy S, Prasad M, Topolancik J, Vollmer F. (2010) All-Optical Arithmetic and Combinatorial Logic Circuits with High-Q Bacteriorhodopsin Coated Microcavities. [PDF]
  • Roy S, Prasad M, Topolancik J, Vollmer F. (2010) All-optical computing circuits based on bacteriorhodopsin protein coated microcavity switches, Optics InfoBase Conference Papers.
  • Roy S, Prasad M, Topolancik J, Vollmer F. (2010) All-Optical Computing Circuits based on Bacteriorhodopsin Protein Coated Microcavity Switches, 2010 CONFERENCE ON LASERS AND ELECTRO-OPTICS (CLEO) AND QUANTUM ELECTRONICS AND LASER SCIENCE CONFERENCE (QELS). [PDF]
  • Roy S, Prasad M, Topolancik J, Vollmer F. (2010) All-optical switching with bacteriorhodopsin protein coated microcavities and its application to low power computing circuits, Journal of Applied Physics, volume 107, no. 5, DOI:10.1063/1.3310385. [PDF]








  • Vollmer F, Arnold S, Libchaber A. (2002) Novel, fiber-optic biosensor based on morphology dependent resonances in dielectric micro-spheres, BIOPHYSICAL JOURNAL, volume 82, no. 1, pages 161A-162A. [PDF]
  • Vollmer F, Braun D, Libchaber A, Khoshsima M, Teraoka I, Arnold S. (2002) Protein detection by optical shift of a resonant microcavity, Applied Physics Letters, volume 80, no. 21, pages 4057-4059, DOI:10.1063/1.1482797. [PDF]


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Further information

Personal Homepage

Molecular, Nano- and Quantum Sensors and Systems

"My laboratory pioneers techniques to detect and visualise processes at the nanoscale. We do this optically, in a specific and sensitive manner, down to the level of single molecules and single atomic ions. Our sensors and spectrometers have important applications in health, nanotechnology, metrology, environment, security, and astronomy."

Medicine as well as biology increasingly rely on the use of cutting‐edge physics and engineering, in order to pursue the next generation nanomedical applications and to address fundamental questions in the life sciences. Central to this task is the study of micro- and nano systems, focusing on how engineered “intelligent” systems combined with natural ones can advance sensing, medicine, and our understanding of how biological systems work. My research addresses these important questions with state‐of‐the‐art biosensor technologies, capable of detecting single molecules and their dynamics; and resolving the kinetics of complex molecular systems on timescales ranging from few nanoseconds to several hours. 

In summary, we are interested in the physics of biosensing:

biosensing, next generation biosensors
silicon photonics, biophotonics, nanophotonics, plasmonics
optofluidics, optical trapping
Anderson Localization
molecular interactions at a biosensor interface
novel materials for biosensing
novel physics for biosensing

PhD studentships and postdoc positions are available in the Vollmer Lab:

Postdoctoral positions

The project will develop chemical control at the nanoscale for single molecule sensing of molecular machines:

we are also looking for a theorist, advert on nature careers

more PhD/postdoc job posting for mygroup on on nature careers, physics today, researchgate and exeter jobs!

Twitter: @FrankVollmerLAB


  • Frontispeace




I am pursuing a multi-disciplinary research initiative in Molecular, Nano- and Quantum Sensors and Systems that is unique in the UK (and the world) and that brings together the research streams of nanophotonics, nanoplasmonics, quantum optics, molecular mechanics (molecular machines, synthetic bio) and in the future, also molecular electronics and neuroscience. This new pan-disciplinary area, I believe, will be a very large and upcoming research playground at the cross-roads of cutting edge experimental and theoretical sciences; there will be applications in health, nanotechnology, metrology, environment, security, and astronomy; it touches on core subjects in physics, quantum optics, optics, biophysics, engineering, molecular mechanics and biochemistry.

Vollmerlab web page:

Review: Whispering-Gallery-Mode Sensors in Physical and Biological Sensing

PhD studentships and postdoc positions are available in the Vollmer Lab:

Postdoctoral positions

The project will develop chemical control at the nanoscale for single molecule sensing of molecular machines:

we are also looking for a theorist, advert on nature careers

more PhD/postdoc job posting for mygroup on on nature careers, physics today, researchgate and exeter jobs!

Observing the Motions of Nano-Machines

Have you ever wondered about how our bodies might work at the nanoscale, a scale at which we are composed of individual biomolecules? Where individual biomolecules such as enzymes take on the role of molecular machines, and where parts of a protein move like the pistons of an engine? How can one observe and analyse such intricate systems?

My research aims to address these questions. My laboratory develops optical techniques to directly visualise living machinery. We are interested in looking at biological nanomachines, such as motor proteins and enzymes, as they function and while disturbing them as little as possible.

Our micro-optical devices and spectrometers have important applications in health, environment, security, and astronomy.

With our optical sensors, processes at the nanoscale can be studied with great precision. The observation of single atomic ions is just a first step towards exploring the ultimate limits of detection. By implementing advanced metrology and techniques from laser interferometry and atomic optics, further breakthroughs in nanoscale precision measurements are anticipated. Techniques from quantum optics combined with novel materials may enable yet unexplored sensing strategies. 

Taking Single-Molecule Detection to the Limit

In 2014, we built the world’s most sensitive optical device capable of detecting single-molecules without chemical alteration (1). The platform is based on optical microcavities, approximately 100 um diameter glass microspheres that are used as optical sensors. Optical resonances, so-called Whispering gallery modes (WGMs), were excited in the microspheres for the label-free detection of biomolecules(2, 3). These microsphere sensors were used to detect single DNA molecules and their interaction kinetics(1).

In 2015-2016, we further advanced these optical sensors, improved upon the detection limit and time resolution. Advanced experimental capabilities of these sensors led to the publication of seminal works, on the sensing of single atomic ions in solution(4), the detection of various single-molecule surface reactions from low to high affinity(5), and on unprecedented nanosecond time resolution for label-free single-molecule studies(6). These demonstrations consolidate our optical technique as one of the most sensitive tools for label-free single molecule studies. They establish a biosensor technology that can detect and analyse the intricate dynamics of single biomolecules. In most recent works we demonstrate such capability, with the first label-free optical technique capable of observing enzymatic interactions and associated conformational changes on the single molecule level(7).

The future of our micro-optical sensors is outlined in a recent roadmap(8). To summarize, our optical sensors can help us understand how our bodies work at the nanoscale, where individual biomolecules such as enzymes take on the role of nano-machines, and where parts of a protein move similar to the pistons of an engine. Without the need of a label, our sensors will provide a universal tool for the unabated exploration of structural dynamics and shape-changes in individual proteins. Our optical devices can furthermore harness the extreme speed, selectivity and specificity of the biological nanoworld. With further technological advances already in the pipeline, our sensors will benchmark nanoscale metrology. Those with ultimate sensitivity will provide a tool for uncovering novel physical phenoma at the nanoscale.

In a second line of experiments, we have established experiments with two-dimensional photonic crystal structures. These structures can provide optical sensing devices that are highly suitable for on-chip biosensing applications. In photonic crystals, light is confined in engineered defect cavities or by means of Anderson Localization - as we have uncovered in our previous research. Recently, we have focused on establishing a photonic crystal biosensing platform by leveraging Anderson Localization and free-space coupling with polarization-tailored beams. With such a platform, we realise various on-chip single-molecule biosensing applications.

The following sections highlight the individual research projects.

Single-Ion Sensing

Plasmonic nanoparticles (NPs) have been used for a wide range of applications, such as spectroscopy, high-resolution imaging, medical therapy, nonlinear optics and photocatalysis. Such widespread utility is attributable to the diverse range of NP shapes and sizes available and the corresponding tunability of their optical properties. The highly localized fields near the surface of such particles, in addition to their small mode volumes, make them especially suitable for sensing or even capable of label-free single-molecule detection. 

In 2016, we have shown that the sensing capability based on plasmonic effects in nanpoarticles can be boosted with optical microcavities for detecting even the smallest chemical species in aqueous solution, single atomic ions(4), see Figure 1.We achieved single-molecule sensitivity by resonantly coupling nanorods (NRs) to optical microcavities.

This is a landmark-breakthrough in the area of optical sensing technology as the observation of single atomic species has thus far been restricted to investigations in vacuum, typically using atom traps. Our interferometric technique based on plasmon-enhanced whispering gallery mode sensors brings these investigations to the solution phase at room temperature. Our study lays the foundation for future all optical investigations of atomic processes at nanoparticle sensor surfaces in the liquid phase, such as investigation of the optical interaction of plasmons with diffusing and bonded ions, analysis of the physical chemistry of atomic processes at nanoparticle surfaces, investigations of surface potentials with single ion probes, and environmental sensing of hazardous chemicals such as mercury, In a related experiment, we have demonstrated the highly specific environmental sensing of mercury ions, using a DNA strand displacement reaction integrated with a WGM sensor(9).

Figure 1: Optical observation of single atomic ions Zn2+ and Hg2+ interacting with plasmonic nanorods in solution. The detection signal has been boosted with optical microcavities. Three different interaction regimes (a)-(c) were observed, which depend on the ionic strength of the solution. Adapted from (4).

In-Situ Observation of Single-Molecule Surface Reactions from low to high Affinity

Nanoparticles have become ubiquitous part of nanotechnology and progress to far more mature applications including medical therapy, drug delivery, biological sensing and imaging. The implementation of nanoparticles for such real life applications requires the development of functional surface modifications to meet the specific requirements set by the application itself. Many researcher have therefore put their efforts together to develop protocols to modify the surfaces of diverse nanomaterials. These efforts, however, are somewhat hindered as most metrologies employed to test the modifications are limited to reaction end products thus resulting in time intensive trial and error phases in the early development stages.

In 2016, we have developed a completely new approach to study surface-based interactions by utilizing WGM microcavity sensors(5). This all optical approach resolves transient as well as permanent interactions of single ligand molecules at the nanoparticle interface in situ, Figure 2. Reaction kinetics can thus be monitored over a broad range of affinities and especially under conditions where no reaction product is formed on average. This enables the real time observation and characterization of reactions during the entire procedure of a bottom-up surface modification, ranging from the deposition of ligands to the confirmation of their functionality. This technique will be a powerful tool, not only for extending the fundamental knowledge of molecular interactions occurring on nanomaterial interfaces, but also for the rapid development of new functionalization protocols.

Figure 2: Top: Illustration of surface reactions with low and high affinity. Bottom: The corresponding single-molecule WGM sensor signals. Spikes indicate a low affinity, steps indicate a high-affinity single-molecule reaction. Adapted from (5).

Nanosecond Time-Resolution for WGM Sensors

Currently, most WGM sensors operate with time resolutions of milliseconds to seconds, depending on the operational requirements, whereas these detection speeds are mostly not limited by the sensor system itself but by the method employed to read out the resonator’s spectral response. In scenarios where the swept wavelength modality is used to obtain the WGM spectra, the laser’s maximum scanning speed is the major limiting factor. In principle, the intrinsic time resolution of the system is set by the decay rate of the cavity, which is typically below one microsecond. Recent experimental works from in collaboration with S. Rosenblum et al.(6)achieved the detection of submicrosecond optomechanical vibrations of microtoroids by a cavity ring-up spectroscopy (CRUS), see Figure 3. In this system, a far-detuned (with respect to the WGM) probe laser is abruptly switched on creating a broader spectrum around the laser’s center frequency, where parts of the spectrum is coupled into the resonator. Afterwards, the probe laser reaches cw operation and is thus not coupled to the WGM any longer, while a fraction of the previously excited modes is continuously coupled out of the cavity, where it interferes with the probe laser, thus creating a ring down interferogram, from which the WGM’s lineshape and position can be obtained via Fourier transformation. This technique, therefore, is very similar to the cavity ring down spectroscopy (CRDS), where the decaying emission intensity is measured after the excitation laser is switched off in order to obtain the cavity lifetime. Unlike CRDS, however, CRUS provides the complete spectral information including centre frequency and linewidth of the WGM Mode (including mode split), which thus can be used for monitoring spectral shifts induced by molecules/particles.

Figure 3: Cavity ring-up spectroscopy for ultrafast sensing with optical microresonators. Adapted from (6).

Identifying a novel biomarker for apoptosis and cell death

We have teamed-up with the Institute for Biochemistry and the University Hospital in Erlangen to investigate the response of cells to toxins using optical microcavities. The response of cells to toxins is commonly investigated using biochemical tools for detecting intracellular markers for cell death, such as caspase proteins. This requires the introduction of labels by the permeabilization or complete lysis of cells. In our study(10), we have introduced a non-invasive optical tool for monitoring a caspase protein in the extracellular medium. The tool is based on highly sensitive optical micro-devices, referred to as WGM biosensors (WGMB’s). WGMB’s were functionalized with antibodies for the specific and label-free detection of procaspase-3 released from human cells after introducing toxins. These studies provide evidence for procaspase-3 as a novel extracellular biomarker for cell death, with broad applications in cytotoxicity tests. Such tests could be administered on lab-on-chip and organ-on-chip devices, culminating to the first commercial method for non-invasive, rapid, real-time, and extracellular detection of cell death by procaspase-3 markers.

Thermal characterization of Biopolymers

The structure of biopolymers is known to change with temperature, affecting for example the activity of enzymes and the folding of proteins. We have shown that such structural change can be monitored using highly sensitive WGM optical biosensors(11). To achieve this goal, my group has devised a technique to temperature-stabilize the WGM sensor system, by adding glycerol to a WGM glass microsphere placed in an aqueous sensing environment. The temperature stabilized WGM sensor was utilized to track structural changes in biopolymers, by monitoring frequency shifts associated with optical polarizability change. Using this sensing method, structural changes in albumin protein (figure) could be resolved for only one degree in temperature variation. Such highly sensitive detection of structural change can have many important applications: in single molecule studies, for thermodynamic investigations of biological systems, and for monitoring temperature-dependent reaction kinetics.

Stand-Off Biodetection with asymmetric Microsphere Cavities

Instead of using evanescent coupling, direct excitation and detection via free-space optics, where necessary optics can be placed far-away from the sensors, seems promising alternative for WGM sensors. Separation of excitation and detection instruments from the on-chip sensors can simplify the incorporation with microfluidics and may enable in-vivo measurements. Unlike active cavities, however, the free-space coupling of passive high Q cavities is normally an extremely inefficient process. To increase the efficiency to desirable levels, an asymmetric resonator geometry is required. The coupling can then be achieved by focusing a laser beam onto the periphery of cavity where he break in its symmetry occurs, locations which also double up as directional emission points allowing efficient far field read out. We have demonstrated the use of asymmetric microspheres in aqueous medium for the detection of unspecific bulk adsorption of BSA molecules onto the cavity surface(12). In addition, we have visualized the directional emission pattern from the cavity, see Figure 4.

Figure 4: Visualization of the directional emission from an asymmetric microsphere cavity.

Photonic Crystals: Photoluminescence Enhancements

One of the areas of intense research in the field of silicon photonics is the excitation and extraction of photoluminescence (PL). We have demonstrated optimized photonic crystal designs on Silicon on Insulator (SIO) for maximizing light extraction efficiencies supported with extensive computational predictions, see Figure 5. With near optimal design parameters for the PhCs, we reported more than 500-fold increase in PL intensity measured near the band edge of silicon at room temperature, an enhancement by an order of magnitude in respect to what has been previously reported in similar PhC structures with air holes (13). We believe that our investigation has an imperative impact in increasing the device performance of LEDs, solar cells and precision biosensors, providing very robust and generic platforms with optimized predictions.

Figure 5: Photoluminescence enhancement in photonic crystals. (a) Photonic crystal (b) disordered crystal (c) Corresponding photoluminescence spectra. Inset show the simulation results. Adapted from (13).

Photonic Crystals: Free-space Coupling with polarization-tailored Beam

Two dimensional silicon photonic crystals (2D PhC) are often the ideal structure for localizing light in micro-cavities with sub-wavelength modal volumes and quality factors of up to ~2 million. Furthermore, 2D PhCs allow dispersion engineering of waveguide modes with slow light characteristics. The PhC crystal waveguides and -cavities can be excited with a free space beam that is impinging orthogonally onto the PhC slab. This is a particularly attractive geometry for many sensing and light-routing applications.

In a very recent study(14), we have investigated this alternative method for coupling to PhC waveguide modes and for the excitation of microcavities. We have tailored the state of polarization in a near-diffraction limited spot of a focused light beam impinging orthogonally onto a PhC waveguide, Figure 6. We have characterized the efficiency of coupling for various focal electric field density distributions. In conjunction with the disorder present in PhC waveguides, we demonstrate Anderson localization, and excite Anderson-localized microcavities with Q factors ~105.

Figure 6: Excitation of PhC waveguide (PhCWG) modes with polarization-tailored beams.


1.            M. D. Baaske, M. R. Foreman, F. Vollmer, Single-molecule nucleic acid interactions monitored on a label-free microcavity biosensor platform. Nat. Nanotechnol. 9, 933-939 (2014).

2.            M. R. Foreman, J. D. Swaim, F. Vollmer, Whispering gallery mode sensors. Advances in optics and photonics 7, 168-240 (2015).

3.            M. B. Eugene Kim, Frank Vollmer, Towards next-generation label-free biosensors: recent advances in whispering gallery mode sensors. Lab Chip, volume 17, no. 7, pages 1190-1205, DOI:10.1039/c6lc01595f

4.            M. D. Baaske, F. Vollmer, Optical observation of single atomic ions interacting with plasmonic nanorods in aqueous solution. Nature Photonics, volume 10, no. 11, pages 733-739, DOI:10.1038/nphoton.2016.177

5.            E. Kim, M. D. Baaske, F. Vollmer, In Situ Observation of Single‐Molecule Surface Reactions from Low to High Affinities. Adv. Mater. 28, 9941-9948 (2016).

6.            S. Rosenblum, Y. Lovsky, L. Arazi, F. Vollmer, B. Dayan, Cavity ring-up spectroscopy for ultrafast sensing with optical microresonators. Nature Communications, volume 6, pages 6788-6788, DOI:10.1038/ncomms7788

7.            M. B. Eugene Kim, Isabel Schuldes, Peter Wilsch, Frank Vollmer, Label-free optical detection of single enzyme-reactant reactions and associated conformational changes. Science Advances, DOI:10.1126/sciadv.1603044

8.            F. Vollmer, A roadmap for whispering gallery mode sensors. to appear in Journal of Optics (2017).

9.            F. Wu, Y. Wu, Z. Niu, F. Vollmer, Integrating a DNA Strand Displacement Reaction with a Whispering Gallery Mode Sensor for Label-Free Mercury (II) Ion Detection. Sensors (Basel, Switzerland) 16,  (2016).

10.          C. Ying-Jen, X. Wei, K. Jochen, V. Frank, Tracking micro-optical resonances for identifying and sensing novel procaspase-3 protein marker released from cell cultures in response to toxins. Nanotechnology 27, 164001 (2016).

11.          E. Kim, M. R. Foreman, Martin D. Baaske, F. Vollmer, Thermal characterisation of (bio)polymers with a temperature-stabilised whispering gallery mode microsensor. Appl. Phys. Lett. 106, 161101 (2016).

12.          Z. Ballard, M. Baaske, F. Vollmer, Stand-Off Biodetection with Free-Space Coupled Asymmetric Microsphere Cavities. Sensors 15, 8968 (2015).

13.          A. Mahdavi et al., Maximizing Photoluminescence Extraction in Silicon Photonic Crystal Slabs. Scientific Reports 6, 25135 (2016).

14.          P. R. Ali Mahdavi, Jolly Xavier, Taofiq Paraiso, Peter Banzer, Frank Vollmer, Coupling to Photonic Crystal Waveguide by Polarization Tailored Beam submitted to APL,  (2017).


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