Hung Doan

Modifying optical properties of reduced/graphene oxide with controlled ozone and thermal treatment in aqueous suspensions

Graphene possesses a number of advantageous properties, however, does not exhibit optical emission, which limits its use in optoelectronics. Unlike graphene, its functional derivative, graphene oxide (GO) exhibits fluorescence emission throughout the visible. Here, we focus on controlled methods for tuning the optical properties of GO. We introduce ozone treatment of reduced graphene oxide (RGO) in order to controllably transform it from non-emissive graphene-like material into GO with a specific fluorescence emission response. Solution-based treatment of RGO for 5-45 min with ∼1.2 g l-1 ozone/oxygen gas mixture yields a drastic color change, bleaching of the absorption in the visible and the stepwise increase in fluorescence intensity and lifetime. This is attributed to the introduction of oxygen-containing functional groups to RGO graphitic platform as detected by the infrared spectroscopy. A reverse process: controllable quenching of this fluorescence is achieved by the thermal treatment of GO in aqueous suspension up to 90 °C. This methodology allows for the wide range alteration of GO optical properties starting from the dark-colored non-emissive RGO material up to nearly transparent highly ozone-oxidized GO showing substantial fluorescence emission. The size of the GO flakes is concomitantly altered by oxidation-induced scission. Semi-empirical PM3 theoretical calculations on HyperChem models are utilized to explore the origins of optical response from GO. Two models are considered, attributing the induced emission either to the localized states produced by oxygen-containing addends or the islands of graphitic carbon enclosed by such addends. Band gap values calculated from the models are in the agreement with experimentally observed transition peak maxima. The controllable variation of GO optical properties in aqueous suspension by ozone and thermal treatments shown in this work provides a route to tune its optical response for particular optoelectronics or biomedical applications.

Linear dichroism and optical anisotropy of silver nanoprisms in polymer films

We present optical studies of two different size distributions of silver triangular nanoprisms, one with a dipole resonance at 520 nm and the other with a dipole resonance at 650 nm, placed in different media. Significant wavelength-dependent depolarization of scattered light from the silver nanoprisms suspended in water indicates strong interference of multiple surface plasmon resonant modes in the same particle. We use this depolarization as a probe of light scattering by the nanoprisms in a lipid solution due to the rejection of a polarized background scattering. Also, the silver nanoprisms were embedded in a polyvinyl alcohol polymer matrix and oriented by stretching the polymer/nanoprism nanocomposite films. We observe significantly increased linear dichroism in the region associated with the plasmonic in-plane dipole mode upon stretching. Additionally, there is a weaker linear dichroism in the region associated with out-of-plane modes, which vanish in the extinction spectrum of the stretched nanocomposite film.

Multi-pulse based approach to study dynamics of molecular assemblies with subwavelength resolution (Conference Presentation)

The long standing unmet need of optical microscopy has been imaging subcellular structures with nanometer precision with speed that will allow following physiological processes in real time. Herein we presenting a new approach (multi-pulse pumping with time-gated detection; MPP-TGD) to increase image resolution and most importantly to significantly improve imaging speed. Alternative change from single pulse to multiple-pulse excitation within continuous excitation trace (in interleave excitation mode) allows for the instantaneous and specific increase (many-folds) in the intensity of subwavelength sized object labeled with long-lived probes. This permits for quick localization of the object. Such intensity change (blinking) on demand can be done with MHz frequency allowing for ultrafast point localization several hundred folds faster than localization based on single molecule blinking. Much higher speed for super-resolution imaging will pave the way for obtaining real time functional information and probing structural rearrangements at the nanometer scale in-vitro and in-vivo. This will have a critical impact on many biomedical applications and enhance our understanding of many cellular functions. We use the microtubules as a model biological system with our new approach to studying microtubule dynamics in real time. The recent work based on single molecule localization microscopy (SMLM) (Mikhaylova et al., 2015) clearly indicates that microtubules are ~25 nm diameter hollow biopolymers that are organized in a closely spaced (about 20-70 nm apart) microtubule bundles. These structures are organized differently between axons and dendrites and their precise organization in different cell compartments is not completely understood.

Multi-pulse pumping for far-field super-resolution imaging

Recently, far-field optical imaging with a resolution significantly beyond diffraction limit has attracted tremendous attention allowing for high resolution imaging in living objects. Various methods have been proposed that are divided in to two basic approaches; deterministic super-resolution like STED or RESOLFT and stochastic super-resolution like PALM or STORM. We propose to achieve super-resolution in far-field fluorescence imaging by the use of controllable (on-demand) bursts of pulses that can change the fluorescence signal of long-lived component over one order of magnitude. We demonstrate that two beads, one labeled with a long-lived dye and another with a short-lived dye, separated by a distance lower than 100 nm can be easily resolved in a single experiment. The proposed method can be used to separate two biological structures in a cell by targeting them with two antibodies labeled with long-lived and short-lived fluorophores.