AMOP Physics Open Day

Today is the AMOP Physics Group Open Day for students interested in studying for a PhD.

Programme:

12:30-13.00 Introductory talk by Peter Barker (Room E7, Physics Dept)
13:00-14:00 Buffet Lunch and theory group posters
14:00-16:00 Lab tours 

Visit to NanoSoft Lab, IPCF-CNR (Messina)

This week Susan and Marios are visiting the NanoSoft Lab at IPCF-CNR (Messina) where they are working with Dr Onofrio Marago.  This visit is part of our long-running collaboration with Dr Marago, and is funded by the Royal Society via an International Joint Project.

Gerard Milburn Seminar

Prof Gerard Milburn (University of Queensland) is giving an AMOPP seminar on Quantum measurement and control of optomechanical systems.

Abstract: The emerging field of quantum optomechanics combines quantum optics and new fabrication techniques to control the quantum state of macroscopic mechanical resonators. This now provides a new approach for controlling the mutual interaction between light and mesoscopic structures, which is one of the eminent goals in quantum information science and of importance for fundamental experiments at the quantum-classical boundary. I will give an overview of this new field and discuss some specific models. These include a scheme to conditionally prepare a macroscopic mechanical resonator in an energy eigenstate by measurement, single photon optomechanics, and quantum entanglement in optomechanical networks

David McGloin Visit and Seminar

David McGloin (Dundee University) is visiting and giving the AMOPP/BioP seminar on Optical manipulation of droplets: aerosols and hydrosomes.

Abstract: In this talk I will discuss work in which my group has developed techniques to optical manipulate liquid droplets in both the air (aerosols) and in another liquid phase (hydrosomes). I will look at hope the optical manipulation of airborne droplets is subtly different from the trapping of particles in liquids in that one can access underdamped particle dynamics in contrast to the conventional heavily overdamped optical tweezers. I will touch on different technqiues for sizing such particles and how droplet composition can be determined using enhanced spectroscopic methods. In addition I will also touch on how optical fields can also be used to manipulate lqiuid droplets in an oil phase, both through direct optical forces and through thermal manipulation, and how this could lead to interesting ways to develop new forms of biological well plates.

Paola Borri Visit and Seminar

Paola Borri (Cardiff University) is visiting today and giving the AMOPP/BioP seminar on Novel Multiphoton Microscopy Techniques for Cell Imaging:  CARS Microscopy and Resonant Four-Wave Mixing.

Abstract:  Optical microscopy is an indispensable tool that is driving progress in cell biology, and is still the only practical means of obtaining spatial and temporal resolution within living cells and tissues. Much effort is being devoted recently to achieve intrinsic three-dimensional (3D) spatial resolution by exploiting optical nonlinear effects which can only take place in the small focal volume where high photon densities are reached. One of the most utilised multiphoton (ie nonlinear) microscopy techniques is two-photon fluorescence where the biomolecules of interest are labelled with fluorophores, which are optically excited via simultaneous absorption of two photons. However, these modified biomolecules raise questions if their behaviour is real or artefactual. Furthermore, all organic fluorophores are prone to photo-bleaching which severely limits time-course observations and is accompanied by toxicity effects and consequent cell damage.
Coherent Antistokes Raman Scattering (CARS) microscopy has recently emerged as a new multiphoton microscopy technique which overcomes the need of fluorescent labelling and yet retains biomolecular specificity and intrinsic 3D resolution. We have developed in our laboratory a fully home-built CARS microscope featuring innovative CARS excitation/detection schemes. In particular, we have demonstrated differential-CARS (D-CARS) and single-laser CARS utilising femtosecond laser pulses linearly chirped by glass dispersion. Furthermore we have invented and demonstrated a novel imaging modality, based on the resonant Four-Wave Mixing (FWM) of colloidal nanoparticles. Results on this work showed that nanoparticles, both semiconductor and metallic, can be used as alternative labels beyond fluorescence by exploiting their resonant FWM, to achieve a novel coherent multiphoton microscopy modality free from background and with a spatial resolution significantly surpassing the one-photon diffraction limit. I will present our latest progress with both techniques and their applications to cell imaging.

Brownian Motion of Graphene paper

Our paper 'Brownian Motion of Graphene' has been published online in ACS Nano.  

From the abstract:

Brownian motion is a manifestation of the fluctuation-dissipation theorem of statistical mechanics. It regulates systems in physics, biology, chemistry, and finance. We use graphene as prototype material to unravel the consequences of the fluctuation-dissipation theorem in two dimensions, by studying the Brownian motion of optically trapped graphene flakes. These orient orthogonal to the light polarization, due to the optical constants anisotropy. We explain the flake dynamics in the optical trap and measure force and torque constants from the correlation functions of the tracking signals, as well as comparing experiments with a full electromagnetic theory of optical trapping. The understanding of optical trapping of two-dimensional nanostructures gained through our Brownian motion analysis paves the way to light-controlled manipulation and all-optical sorting of biological membranes and anisotropic macromolecules.

UCL Science Article

A short article on optical trapping called 'Light Forces' written by Susan and Phil is published in the 2010 issue of UCL Science for Schools magazine.

UCL Science is mailed to Schools and Colleges on the UCAS mailing list.  For extra copies contact the editor.