Source: https://groups.oist.jp/light/fy2015-annual-report
Timestamp: 2019-04-19 08:31:48+00:00

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This year the group focussed on work related to nanofibre-mediated nonlinear optics in cold atomic systems, particle trapping at the nanoscale and sensing using whispering gallery resonators. Amongst the major outputs were a proposal for atom trapping based on a nanostructured optical microfibre, the first demonstration of the interaction of higher order optical fibre modes with cold atoms, a demonstration of the Autler-Townes effect in an atomic system for ultralow powers, a model and demonstratioin of optical binding for micron sized particles next to optical nanofibres and the demonstration of nonlinear effects in a variety of whispering gallery resonators.
We present an evanescent field-based device which can confine low refractive index contrast nanoscale particles using modest optical powers (< 1.2 mW) with additional applications in the field of cold atom trapping. We currently focus on using a nanostructured ultrathin optical fibre to trap 100 and 200 nm, low index contrast, fluorescent particles within the structured region, thereby overcoming diffraction limitations. We hope to analyse the trapping potential of this device both experimentally and theoretically, and determine the trap characteristics through analysis of the transmitted laser beam. We have demonstrated the fabrication of such devices with high resolution, as well as some early results showing the trapping of 100 nm polystyrene particles.
Figure 1. SEM images of nanostructured ultrathin optical fibres. Waist diameter 1.4 µm. Slot width 300 nm. Slot length 20 µm.
Figure 2. Still images taken from a video showing the trapping of 200 nm particles using a total power of 30 mW.
We demonstrated propulsion of particles in the evanescent field of fundamental and first group of higher order modes. Using a microfiber/optical tweezers compact system, specific number of particles are trapped and propelled in the evanescent field of an ultrathin fibre. The dependence of the particles’ speeds on their diameter is studied for 1 μm, 3 μm, and 5 μm diameter polystyrene particles using the higher order modes of the fibres. The optical propelling velocity of a single, 3 μm polystyrene particle was found to be 8 times faster under the higher order mode than the fundamental mode field for a waist power of 25 mW. These results highlight the special properties of higher order modes, such as their larger evanescent field amplitudes and longer evanescent field extensions from the fibre’s surface, when compared to what can be achieved for FM propagation. Experimental data are supported by theoretical calculations. This work can be extended to trapping and manipulation of laser-cooled atoms with potential for quantum networks.
In this work, we demonstrated a tunable plasmonic nanodevice which can improve both the trapping field enhancement and detection of nano-objects using singular phase drops in the NIR range. The plasmonic nanodevice consists of an array of nanoring structures connected by slots 50 nm x 50 nm dimensions. These slots act as individual detection and trapping sites. The tunability of the system is achieved by increasing the inner disk size inside of nano-holes. We report experimental evidence of 100 nm polystyrene beads trapping using low incident power on these devices.
Figure 3. Electric field distribution perpendicular to (a) the trapping gap (solid) and to the left inner disk (dashed). (b) Maximum electric field intensity values taken from (a). The inset shows the axis along which the calculations were made. (c) Schematic of the Kretschmann configuration used to experimentally excite the devices. (d) Device fabricated with different inner disk sizes, d, as viewed under a 20X microscope objective (left). Laser source tuned at λ= 950 nm and incident angle θinc = 63°. Polystyrene particles with diameter 100 nm are quickly confined in the arrays with the 150 nm array accumulating a larger number of particles.
In 2015 the Whispering Gallery Resonator Group within the Light-Matter Interactions Unit have continued to work with microcavities for sensing, optomechanics and nonlinear optics.
The tunability of an optical cavity is an essential requirement for many areas of research. We used the Pound–Drever–Hall technique to lock a laser to a whispering gallery mode (WGM) of a microbubble resonator, to show that linear tuning of the WGM, and the corresponding locked laser, display almost zero hysteresis, see Fig. 1. By applying aerostatic pressure to the interior surface of the microbubble resonator, optical mode shift rates of around 58 GHz/MPa are achieved. The system can measure pressure with a detection limit of 2 × 10−4 MPa, which is an improvement made on pressure sensing using this device. The long-term frequency stability of this tuning method for different input pressures is measured. The frequency noise of the WGM measured over 10 min for an input pressure of 0.5 MPa had a maximum standard deviation of 36 MHz.
Fig. 1(left): Laser frequency shift as a function of applied pressure. Solid red (blue) curve represents the laser frequency change for applied pressure in increasing (decreasing) direction. (Right): Long term stability, frequency as a function of time.
Coupled-mode-induced transparency was realized in a single microbubble whispering-gallery mode resonator. Using aerostatic tuning, we find that the pressure-induced shifting rates are different for different radial order modes, see Fig. 2. A finite element simulation considering both the strain and stress effects shows a GHz/bar difference, and this was confirmed by experiments. A transparency spectrum was obtained through precise pressure tuning. The resulting line shapes were fitted with theory. This work lays a foundation for future applications in microbubble sensing.
Fig. 2. Pressure tuning rate of a high Q mode (red dot) and a low Q mode (black square).
Dissipative optomechanics has some advantages in cooling compared to the conventional dispersion dominated systems. We studied the optical response of a cantilever-like, silica, microsphere pendulum, evanescently coupled to a fiber taper. In a whispering gallery mode resonator, the cavity mode and motion of the pendulum result in both dispersive and dissipative optomechanical interactions. This unique mechanism leads to an experimentally observable, asymmetric response function of the transduction spectrum, which can be explained using coupled-mode theory, see Fig. 3.
Fig. 3. (Left): Schematic of a taper-coupled micropendulum system. Inset: image of the micropendulum; (b) Fourier transform spectrum of the transmitted signal through the fiber taper as the pendulum moves relative to the fiber. (c) dissipative and (d) dispersive modulation. (e) A typical transduction response to cavity detuning for the 1 kHz mechanical mode peak. (Right): Coupled mode theory with experimental results, red squares (dotted blue) are the experimental data for the peak amplitudes of the maximum transduction for red(blue) detuning of the optical mode. Red(Blue) curve was obtained from coupled mode theory.
The fabrication of an ultrahigh-quality-factor, bottle-like microresonator from a microcapillary and the realisation of Raman lasing therein at pump wavelengths of 1.55 µm and 780 nm was achieved in 2015. The dependence of the Raman laser threshold on the mode volume was investigated. The mode volume of the fundamental bottle mode was calculated and compared with that of a microsphere. Third-order cascaded Raman lasing was observed under pumping at 780 nm, see Fig. 4. A hollow, bottle-like microresonator (BLMR) was fabricated from a microcapillary with a nearly parabolic profile. From simulations at 1.55 μm the fundamental bottle mode is shown to be in the anomalous dispersion regime, while the conventional whispering gallery mode, confined to the center of the BLMR, is in the normal dispersion regime. We have experimentally shown that, for a BLMR with a diameter of 102 µm, degenerate four-wave mixing can only be observed by judicious selection of the tapered fiber coupling position.
Fig. 4. (Left): Raman spectrum when the pump power is above the threshold. The wavelength of the pump laser and Raman scattering are 1545.1 and 1654.5 nm, respectively. Inset: relationship between the power of the pump and Raman scattering. The black line is a linear fit to the data. (Right) Four wave mixing in BLMR.
Sensors based on whispering gallery resonators have minute footprints and can push achievable sensitivities and resolutions to their limits. Here, we use a microbubble resonator, with a wall thickness of 500 nm and an intrinsic Q-factor of 107 in the telecommunications C-band, to investigate aerostatic pressure sensing via stress and strain of the material. The microbubble is made using two counter-propagating CO2 laser beams focused onto a microcapillary. The measured sensitivity is 19 GHz/bar at 1.55 μm. We show that this can be further improved to 38 GHz/bar when tested at the 780 nm wavelength range. In this case, the resolution for pressure sensing can reach 0.17 mbar with a Q-factor higher than 5 × 10^7, see Fig. 5.
Fig. 5. (Left): Pressure tuning of ultra-thin high-Q microbubble. (Right): WGM at 780 nm in an ultra-thin microbubble with Q in excess of 10^8.
Flow sensing using the concept of a hot whispering gallery microlaser was also demonstrated in 2016. Silica microcapillaries or microbubbles, coated with a layer of erbium:ytterbium (Er:Yb) doped phosphate laser glass, result in a hollow, microbottle-shaped laser geometry. The Er:Yb doped glass outer layer was pumped at 980 nm via a tapered optical fiber and whispering gallery mode lasing was recorded at 1535 nm. When gas passes through the capillary, the WGMs shift toward shorter wavelengths due to the cooling effect of the fluid flow. In this way, thermal tuning of the lasing modes over 70 GHz can be achieved. Gas flow rates were calibrated against a commercial mass flow sensor, see Fig. 6.
Fig. 6. (Left): Lasing spectrum from an Er:Yb doped bottle-shaped resonator on a silica capillary. Inset: Image of the resonator showing a WGM which is visible due to the green upconversion fluorescence (Right): Shift of the 1535 nm lasing WGM as a function of the measured flow rate for different pump powers. The solid lines are fits to the experimental data.
Ultrathin optical fibres integrated into cold atom setups are proving to be ideal building blocks for atom-photon hybrid quantum networks. Such optical nanofibres (ONFs) can be used for the demonstration of nonlinear optics and quantum interference phenomena in atomic media. We observed multilevel cascaded electromagnetically induced transparency (EIT) using an optical nanofibre embedded into a cloud of cold 87Rb atoms. Intense evanescent fields at the ONF allows us observe the effect with ultralow pump powers. The corresponding Rabi frequencies and EIT linewidths are calculated. Finally, the phenomenon is used to demonstrate an all optical switch.
Figure 1: Multiple EIT peaks for coupling beam powers from 0–800 nW as indicated on the graphs. The probe power is 5 pW. The reference signal obtained in a vapour cell (red curves) is used for frequency calibration.
Figure 2: All optical switch demonstrated using the ONF based EIT. Black: photon counts obtained with 10 kHz on–off modulation of the coupling beam in the presence of cold atoms with background counts subtracted. Red: electrical reference signal used for switching on and off the coupling beam. The data is averaged for 150 runs.
We also used an optical nanofibre embedded in a cloud of laser-cooled Rb-87 for near-infrared frequency up-conversion via a resonant two-photon process. Sub-nW powers of the two-photon radiation, at 780 and 776 nm, copropagate through the optical nanofiber and the generation of 420 nm photons is observed. A measurement of the Autler-Townes splitting provides a direct measurement of the Rabi frequency of the 780 nm transition. Through this method, dephasings of the system can be studied. In this work, the optical nanofibre was used as an excitation and detection tool simultaneously, and it highlights some of the advantages of using fully fibred systems for nonlinear optics with atoms.
Daly, M., Sergides, M. & Nic Chormaic, S. Optical trapping and manipulation of micrometer and submicrometer particles. Laser & Photonics Reviews 9, 309-329, doi:10.1002/lpor201500006 (2015).
Daly, M., Troung, V. G. & Nic Chormaic, S. Nanostructured tapered optical fibers for paticle trapping. SPIE Proceedings, Micro-structured and Specialty Optical Fibres IV 9507, 95070E, doi:10.1117/12.2182340 (2015).
Daly, M., Truong, V. G. & Nic Chormaic, S. Submicron particle manipulation using slotted tapered optical fibers. SPIE Proceedings, Optical Trapping and Optical Micromanipulation XII 9548, 954812, doi:10.1117/12.2189168 (2015).
Gokhroo, V., Kumar, R. & Nic Chormaic, S. Optical nanofiber facilitated nonlinear optics effects in cold atoms SPIE Proceedings, Nonlinear Optics and Applications IX 9503, 95030D, doi:10.1117/12.2182341 (2015).
Gusachenko, I., Truong, V. G., Frawley, M. & Nic Chormaic, S. Optical nanofiber integrated into optical tweezers for in-situ fiber probing and optical binding studies. Photonics 2015 795-807, doi:10.3390/photonics2030795 (2015).
Kumar, R., Gokhroo, V., Deasy, K. & Nic Chormaic, S. Autler-Townes splitting via frequency upconversion at ultra-low power levels in cold 87Rb atoms using an optical nanofiber. Physical Review A 91, 053842-053841-053845, doi:10.1103/PhysRevA.91.053842 (2015).
Kumar, R., Gokhroo, V. & Nic Chormaic, S. Multi-level cascaded electromagnetically induced transparency in cold atoms using an optical nanofibre interface. New Journal of Physics 17, 123012, doi:10.1088/1367-2630/17/12/123012 (2015).
Madugani, R., Yang, Y., Ward, J. M., Le, V. H. & Nic Chormaic, S. Optomechanical transduction and characterization of a silica microsphere pendulum via evanescent light. Applied Physics Letters 106, 1-4, doi:10.1063/1.4922637 (2015).
Maimaiti, A., Truong, V. G. & Nic Chormaic, S. Ultrathin optical fibers for particle trapping and manipulation SPIE Proceedings, Optical Trapping and Optical Micromanipulation XII 9548, 954815, doi:10.1117/12.2186497 (2015).
Nieddu, T., Gokhroo, V. & Nic Chormaic, S. Optical nanofibres and neutral atoms. Journal of Optics 18, 053001 (053012pp), doi:10.1088/2040-8978/18/5/053001 (2016).
Ooka, Y., Yang, Y., Ward, J. & Nic Chormaic, S. Raman lasing in a hollow, bottle-like microresonator. Applied Physics Express 8, 0920011-0920014, doi:0.7567/APEX.8.092001 (2015).
Sergides, M., Troung, V. G., Prakash, P., Schloss, J. R., Bhardwaji, B. S. & Nic Chormaic, S. Characterization of periodic plasmonic nanoring devices for nanomanipulation. SPIE Proceedings, Optical Trapping and Optical Micromanipulation XII 9548, 95481T, doi:10.1117/12.2186700 (2015).
Subramonian Rajasree, K., Ray, T. & Nic Chormaic, S. Quantum networks based on cold Rydberg atoms and an optical nanofiber. Frontiers in Optics 2015, OSA Technical Digest (online) (Optical Society of America, 2015) FW3D, 4, doi:10.1364/FIO.2015.FW3D.4 (2015).
Wang, P., Madugani, R., Zhao, H., Ward, J. M., Yang, Y., Farrell, G., Brambilla, G. & Nic Chormaic, S. Development of packaged silica microspheres coupled with tapered optical microfibres Proc. SPIE 9727, Laser Resonators, Microresonators, and Beam Control XVIII, 972704 972704-972701-972705, doi:10.1117/12.2211757 (2016).
Ward, J. M., Yang, Y. & Nic Chormaic, S. Flow sensor using a hollow whispering gallery mode microlaser. Proc. SPIE 9727, Laser Resonators, Microresonators, and Beam Control XVIII, 972718 9727, 972718-972711-972716, doi:10.1117/12.2209205 (2016).
Yang, Y., Ooka, Y., Thompson, R. M., Ward, J. M. & Nic Chormaic, S. Degenerate four-wave mixing in a silica hollow bottle-like microresonator. Optics Letters 41, 575-578, doi: 10.1364/OL.41.000575 (2016).
Yang, Y., Saurabh, S., Ward, J. M. & Nic Chormaic, S. Coupled-mode-induced transparency in aerostatically tuned microbubble whispering-gallery resonators. Optics Letters 40, 1834-1837, doi:10.1364/OL.40.001834 (2015).
Yang, Y., Saurabh, S., Ward, J. M. & Nic Chormaic, S. High-Q, ultrathin-walled microbubble resonator for aerostatic pressure sensing. Optics Express 24, 294-299, doi:10.1364/OE.24.000294 (2016).
Daly, M., Truong, V. G. & Nic Chormaic, S. Nanostructured tapered optical fibers for particle trapping, in SPIE Optics and Optoelectronics - Micro-Structured and Speciality Optics Fibers, Prague, Czech Republic (2015).
Daly, M., Truong, V. G. & Nic Chormaic, S. Nanostructured micro- and nanofibres for optical trapping, in 2nd Optical Manipulation Conference, Yokohama, Japan (2015).
Daly, M., Truong, V. G. & Nic Chormaic, S. Submicron particle manipulation using slotted tapered optical fibers, in SPIE Optics & Photonics - Optical Trapping and Optical Micromanipulation XII, San Diego, USA (2015).
Gokhroo, V., Kumar, R. & Nic Chormaic, S. Optical nanofiber facilitated nonlinear optics effects in cold atoms, in SPIE Optics and Optoelectronics - Nonlinear Optics and Applications, Prague, Czech Republic (2015).
Gusachenko, I., Sergides, M., Truong, V. G. & Nic Chormaic, S. Anisotropic ring arrays for nanoparticle trapping in 2nd Optical Manipulation Conference, Yokohama, Japan (2015).
Gusachenko, I., Truong, V. G. & Nic Chormaic, S. Bisphere-induced transmission changes in optical nanofibre, in 2nd Optical Manipulation Conference, Yokohama, Japan (2015).
Kumar, R., Gokhroo, V. & Nic Chormaic, S. Studies of cold atoms using optical nanofibers in Okinawa School in Physics: Coherent Quantum Dynamics, Okinawa, Japan (2015).
Maimaiti, A., Truong, V. G., Gusachenko, I., Sergides, M. & Nic Chormaic, S. Optical propulsion of dielectric spheres using higher order microfiber modes, in IONS 2015, Nanjing, China (2015).
Maimaiti, A., Truong, V. G., Sergides, M., Gusachenko, I. & Nic Chormaic, S. Propulsion of particles using ultrathin optical fibers, in Optical Trapping Applications, Vancouver, Canada (2015).
Maimaiti, A., Truong, V. G., Sergides, M., Gusachenko, I. & Nic Chormaic, S. Particle propulsion using higher order microfibre modes, in 2nd Optical Manipulation Conference, Yokohama, Japan (2015).
Maimaiti, A., Truong, V. G., Sergides, M., Gusachenko, I. & Nic Chormaic, S. Particle propulsion using higher order microfiber modes in CLEO-PR 2015, Busan, Korea (2015).
Nic Chormaic, S. Research update from the Light-Matter Interactions Unit, in ONNA2015 workshop, Okinawa, Japan (2015).
Nic Chormaic, S. A hybrid quantum system for laser-cooled atoms using optical nanofibres, in Frontiers in Nanophotonics, Ascona, Switzerland (2015).
Nic Chormaic, S. Whispering gallery mode microbubble resonators in PIERS 2015, Prague, Czech Republic (2015).
Nic Chormaic, S., Maimaiti, A., Sergides, M., Gusachenko, I. & Truong, V. G. Ultrathin optical fibers for particle trapping and manipulation, in SPIE Optics & Photonics - Optical Trapping and Optical Micromanipulation XII, San Diego, USA (2015).
Ray, T., Gokhroo, V., Subramonian Rajasree, K. P. & Nic Chormaic, S. Towards Rydberg atoms near the surface of optical nanofibres, in OIST Minisymposium on Rydberg Atoms for Quantum Technologies, Okinawa, Japan (2016).
Sergides, M., Truong, V. G. & Nic Chormaic, S. Highly tunable hybrid plasmonic devices for trapping nano-objects, in The 76th JSAP Annual Meeting, Nagoya, Japan (2015).
Sergides, M., Truong, V. G., Schloss, J. R., Bhardwaji, B. S. & Nic Chormaic, S. Characterization of periodic plasmonic nanoring devices for nanomanipulation, in SPIE Optics & Photonics - Optical Trapping and Optical Micromanipulation XII, San Diego, USA (2015).
Subramonian Rajasree, K. P., Ray, T. & Nic Chormaic, S. Quantum networks based on cold Rydberg atoms and an optical nanofiber in FiO/LS 2015, San Jose, USA (2015).
Truong, V. G., Maimaiti, A., Gusachenko, I. & Nic Chormaic, S. Trapping and manipulation of selective microparticles in the evanescent field of optical micro- and nanofibres, in 2nd Optical Manipulation Conference, Yokohama, Japan (2015).
Truong, V. G., Maimaiti, A., Sergides, M., Daly, M. & Nic Chormaic, S. Trapping and manipulation of micro- and nano-particles with nanofiber and nano-plasmonic tweezer systems, in NanoMA 2015, Tsukuba, Japan (2015).
Wang, P., Madugani, R., Zhao, H., Ward, J. M., Yang, Y., Farrell, G., Brambilla, G. & Nic Chormaic, S. Development of packaged silica microspheres coupled with tapered optical microfibres, in LASE-SPIE Photonics West, San Francisco, USA (2016).
Ward, J., Yang, Y. & Nic Chormaic, S. Gas Flow Sensor using a Hollow WGM Microlaser, in The 76th JSAP Annual Meeting, Nagoya, Japan (2015).
Ward, J. M. Whispering Gallery Resonators, in Okinawa School in Physics: Coherent Quantum Dynamics, Okinawa, Japan (2015).
Ward, J. M., Yang, Y. & Nic Chormaic, S. Flow sensor using a hollow whsipering gallery mode microlaser, in LASE-SPIE Photonics West, San Francisco, USA (2016).
Yang, Y. & Nic Chormaic, S. The micropendulum and towards trapping of its center-of-mass motion, in 2015 Workshop on Microcavity Photonics, Hefei, China (2015).
Yang, Y., Saurabh, S. & Nic Chormaic, S. Improved sensitivity for pressure sensing in microbubble resonators, in Advanced Photonics, Boston, USA (2015).
Yang, Y., Ward, J. & Nic Chormaic, S. Ultrathin-walled microbubbles for high sensitivity pressure sensing, in The 76th JSAP Annual Meeting, Nagoya, Japan (2015).
Daly, M., Truong, V. G. & Nic Chormaic, S. Nanostructured micro- and nanofibres for optical trapping, in ONNA2015 workshop, Okinawa, Japan (2015).
Gokhroo, V., Kumar, R. & Nic Chormaic, S. Investigation of two- photon excitation in cold and hot rubidium atoms in ONNA2015 workshop, Okinawa, Japan (2015).
Gokhroo, V., Kumar, R. & Nic Chormaic, S. Observation of Autler-Townes and EIT effects in cold 87Rb atoms via an optical nanofiber, in ICOLS 2015, Singapore (2015).
Gusachenko, I., Sergides, M., Prakash, P., Truong, V. G. & Nic Chormaic, S. Anisotropic ring plasmonic arrays for nanoparticle trapping, in ONNA2015 workshop, Okinawa, Japan (2015).
Kumar, R., Gokhroo, V., Ray, T. & Nic Chormaic, S. All optical switching with cold Rb atoms using an optical nanofiber, in ONNA2015 workshop, Okinawa, Japan (2015).
Le, V. H., Maimaiti, A., Ward, J. M. & Nic Chormaic, S. Optical micro- and nanofibre pulling rig, in 2nd Optical Manipulation Conference, Yokohama, Japan (2015).
Madugani, R., Yang, Y., Le, V. H., Ward, J. M. & Nic Chormaic, S. Pressure tunable microbubble resonator as an external reference to a laser, in ONNA2015 workshop, Okinawa, Japan (2015).
Maimaiti, A., Truong, V. G., Sergides, M., Gusachenko, I. & NIc Chormaic, S. Optical binding of particles using higher order microfibre modes, in ONNA2015 workshop, Okinawa, Japan (2015).
Nieddu, T., Gokhroo, V., Deasy, K., Truong, V. G. & Nic Chormaic, S. Selective excitation of higher order fiber modes and their interaction with cold atoms, in ONNA2015 workshop, Okinawa, Japan (2015).
Nieddu, T., Gokhroo, V., Deasy, K., Truong, V. G., Ray, T. & Nic Chormaic, S. Selective excitation of higher order nanofiber modes and their interaction with cold atoms, in ICOLS 2015, Singapore (2015).
Ray, T., Kumar, R., Gokhroo, V., Subramonian Rajasree, K. P. & Nic Chormaic, S. Probing interactions in cold atomic systems using optical nanofibres, in 604. Wilhelm and Else Heraeus-Seminar - Hybrid Systems for Quantum Optics, Bad Honnef, Germany (2016).
Sergides, M., Truong, V. G. & Nic Chormaic, S. Optical trapping using plasmonic nanoring arrays, in ONNA2015 workshop, Okinawa, Japan (2015).
Subramonian Rajasree, K. P. Fresnel atom microtraps from geometric apertures, in ONNA2015 workshop, Okinawa, Japan (2015).
Tavala, A., Zeilinger, A. & Nic Chormaic, S. Using lensed fibers for stimulating ex-vivo retina: simulation and measurement results, in ÖPG, SSAA and ÖGAA Joint Annual Meeting 2015, Vienna, Austria (2015).
Truong, V. G., Maimaiti, A., Daly, M., Gusachenko, I., Sergides, M. & Nic Chormaic, S. Compact system of optical tweezers/nanofibres/nano plasmonic structure for particle trapping and manipulation, in ONNA2015 workshop, Okinawa, Japan (2015).
Truong, V. G., Maimaiti, A., Sergides, M., Gusachenko, I. & Nic Chormaic, S. Trapping and manipulation of micro-particles with nanofibre and optical tweezer compact systems in NIMS conference, Tsukuba, Japan (2015).
Ward, J. M. Er:Yb doped microbubble laser, in ONNA2015 workshop, Okinawa, Japan (2015).
Yang, Y., Madugani, R., Ward, J. M. & Nic Chormaic, S. Optomechanical behavior of a micropendulum whispering gallery mode resonator, in Okinawa School in Physics: Coherent Quantum Dynamics, Okinawa, Japan (2015).
Yang, Y., Saraubh, S., Ward, J. M. & Nic Chormaic, S. Pressure tunable microbubble and coupled-mode-induced transparency, in ONNA2015 workshop, Okinawa, Japan (2015).
Nic Chormaic, S. Atomic quantum engineering with nanofibres I, QSciTech, Macquarie University, Sydney, Australia (2015).
Nic Chormaic, S. Atomic quantum engineering with nanofibres II, QSciTech, Macquarie University, Sydney, Australia (2015).
Nic Chormaic, S. Nonlinear optics in two different regimes: cold atoms and whispering gallery resonators, Institut für Physik, Humboldt-Universiät zu Berlin, Germany (2015).
One PhD student, Ravi Kumar, graduated from the unit through University College Cork (Ireland).

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