School of Chemistry - Research Publications

Permanent URI for this collection

http://hdl.handle.net/11343/300

Filters

2020 - 2024 43
Reset filters

Settings
Statistics
Citations
Author: Mulvaney, Paul × End date: 2024 × Start date: 2020 × Type: Journal Article ×

Search Results

Now showing 1 - 10 of 43
  • Item
    Thumbnail Image
    Ultrafast Nanodrum-on-Chip Pixels
    Li, J ; Hutchison, JA ; Smith, D ; Wu, H ; Mulvaney, P (AMER CHEMICAL SOC, 2024-03-15)
    Environmentally friendly, ultrafast display pixels of micrometer sizes are fabricated with nanometer-thick gold films and Si/SiO2 wafers. The color displayed is due to both the plasmon response of the gold film and the optical interference from the Fabry-Peerot cavity formed by the underlying silicon substrate, the semitransparent gold film and the air gap between them. When an electric potential is applied to the gold film, the electrostatic force induces an attraction between the gold film and the silicon wafer. Due to the flexibility of the film, the size of the air gap changes, resulting in a changing color. By applying different driving signals, we have achieved cyan, magenta, and yellow reflected colors. The maximum switching rate of the pixel is primarily determined by the thickness dependence of the metal drum and its Young's modulus and is typically in the MHz regime.
  • Item
    Thumbnail Image
    Surface Lattice Resonances in Self-Assembled Gold Nanoparticle Arrays: Impact of Lattice Period, Structural Disorder, and Refractive Index on Resonance Quality
    Ponomareva, E ; Volk, K ; Mulvaney, P ; Karg, M (American Chemical Society, 2020-11-17)
    Surface lattice resonances are optical resonances composed of hybridized plasmonic and diffractive modes. These collective resonances occur in periodic arrays of plasmonic nanoparticles with wavelength-scale interparticle distances. The appearance and strength of surface lattice resonances strongly depend on the single particle localized surface plasmon resonance and its spectral overlap with the diffractive modes of the array. Coupling to in-plane orders of diffraction is also strongly affected by the refractive index environment and its symmetry. In this work, we address the impact of the interparticle distance, the symmetry of the refractive index environment, and structural imperfections in self-assembled colloidal monolayers on the plasmonic–diffractive coupling. For this purpose, we prepared hexagonally ordered, nonclose packed monolayers of gold nanoparticles using a fast and efficient, interface-mediated, colloidal self-assembly approach. By tuning the thickness and deformability of the polymer shells, we were able to prepare monolayers with a broad range of interparticle distances. The optical properties of the samples were studied experimentally by UV–Vis spectroscopy and theoretically by finite difference time domain simulations. The measured and simulated spectra allow a comprehensive analysis of the details of electromagnetic coupling in periodic plasmonic arrays. In particular, we identify relevant criteria required for surface lattice resonances in the visible wavelength range with optimized quality factors in self-assembled monolayers.
  • Item
    Thumbnail Image
    Growth of Gold Nanorods: A SAXS Study
    Seibt, S ; Zhang, H ; Mudie, S ; Foerster, S ; Mulvaney, P (AMER CHEMICAL SOC, 2021-09-16)
    Using simultaneous, in situ optical spectroscopy and time-resolved, small-angle X-ray scattering (SAXS), we have directly monitored the seeded growth of nearly monodisperse gold nanorods using hydroquinone as the reductant. Growth of the rods is much slower than with the ascorbate ion, allowing the rate of growth along both the longitudinal and transverse directions to be independently determined. The thickness of the stabilizing CTAB layer (3.2 ± 0.3 nm) has also been extracted. We find that increasing the hydrogen tetrachloroaurate(III) concentration produces longer rods, while conversely, increasing the hydroquinone concentration reduces the final aspect ratio. The final number of gold rods is smaller than the initial number of seed particles and decreases in the presence of larger concentrations of HAuCl4. The SAXS data reveal an early transition from a spherical morphology to an ellipsoidal one and then to spherically capped cylinders. The growth curve exhibits at least three distinct regimes: an initial phase comprising spherical seed growth, followed by symmetry breaking and slow elongation. A third phase is marked by rapid rod growth and increases in the aspect ratio. This process is temporally well resolved from the initial symmetry breaking but typically occurs when the rods are around 6 nm in diameter using hydroquinone as the reductant. The results provide qualitative support for the “popcorn model” proposed by Edgar et al. [ Formation of Gold Nanorods by a Stochastic “Popcorn” Mechanism. ACS Nano 2012, 6, 1116 1125 ].
  • Item
    Thumbnail Image
    Spectroelectrochemistry of Colloidal CdSe Quantum Dots
    Ashokan, A ; Mulvaney, P (AMER CHEMICAL SOC, 2021-02-23)
    Solution-phase spectroelectrochemistry was used to study electron injection into colloidal CdSe quantum dots (QDs) with sizes ranging from 3.4 to 11.1 nm in tetrahydrofuran (THF). The absorbance and photoluminescence of the QDs were monitored in response to both charging and discharging cycles, and the optical changes were reversible on a timescale of minutes. Bleaching of the QD 1S3/2h1Se exciton state was used to determine the conduction band energy levels. We found that the negative trion state was stable in THF for hours under an applied cathodic potential. Both the degree of bleaching and the recovery of the exciton state depended on the applied potential. Based on the current and charge measurements, we found that between 10 and 150 electrons were injected into the QDs, depending on the electrode potential and QD size. Most of the electron injection occurred below the band edge and led to quenching of the QD photoluminescence. The potential at which injection into QDs occurred depended on the nature of the QD ligands.
  • Item
    Thumbnail Image
    A reflective display based on the electro-microfluidic assembly of particles within suppressed water-in-oil droplet array
    Shen, S ; Feng, H ; Deng, Y ; Xie, S ; Yi, Z ; Jin, M ; Zhou, G ; Mulvaney, P ; Shui, L (SPRINGERNATURE, 2023-12-05)
    Reflective displays have stimulated considerable interest because of their friendly readability and low energy consumption. Herein, we develop a reflective display technique via an electro-microfluidic assembly of particles (eMAP) strategy whereby colored particles assemble into annular and planar structures inside a dyed water droplet to create "open" and "closed" states of a display pixel. Water-in-oil droplets are compressed within microwells to form a pixel array. The particles dispersed in droplets are driven by deformation-strengthened dielectrophoretic force to achieve fast and reversible motion and assemble into multiple structures. This eMAP based device can display designed information in three primary colors with ≥170° viewing angle, ~0.14 s switching time, and bistability with an optimized material system. This proposed technique demonstrates the basis of a high-performance and energy-saving reflective display, and the display speed and color quality could be further improved by structure and material optimization; exhibiting a potential reflective display technology.
  • Item
    No Preview Available
    Energy dissipation during homogeneous wetting of surfaces with randomly and periodically distributed cylindrical pillars
    Kumar, P ; Mulvaney, P ; Harvie, DJE (ACADEMIC PRESS INC ELSEVIER SCIENCE, 2024-04)
    HYPOTHESIS: Understanding contact angle hysteresis on rough surfaces is important as most industrially relevant and naturally occurring surfaces possess some form of random or structured roughness. We hypothesise that hysteresis can be described by the dilute defect model of Joanny & de Gennes [1] and that the energy dissipation occurring during the stick-slip motion of the contact line is key to developing a predictive equation for hysteresis. EXPERIMENTS: We measured hysteresis on surfaces with randomly distributed and periodically arranged microscopic cylindrical pillars for a variety of different liquids in air. The inherent (flat surface) contact angles tested range from lyophilic (θe=33.8°) to lyophobic (θe=112.0°). FINDINGS: A methodology for averaging the measured advancing and receding contact angles on random surfaces is presented. Based on these results correlations for roughness-induced energy dissipation are derived, and an equation for predicting the advancing and receding contact angles during homogeneous (Wenzel) wetting on random surfaces is presented. Equations that predict the onset of the alternate wetting conditions of hemiwicking, split-advancing, split-receding and heterogeneous (Cassie) wetting are also derived, thus defining the range of validity for the homogeneous wetting equation. A 'cluster' concept is proposed to explain the measurably higher hysteresis exhibited by structured surfaces compared to random surfaces.
  • Item
    No Preview Available
    Electrophoretic Deposition of Single Nanoparticles
    Zhang, H ; Liu, Y ; Dong, Y ; Ashokan, A ; Widmer-Cooper, A ; Ko''hler, J ; Mulvaney, P (AMER CHEMICAL SOC, 2024-02-01)
    The controlled assembly of colloid particles on a solid substrate has always been a major challenge in colloid and surface science. Here we provide an overview of electrophoretic deposition (EPD) of single charge-stabilized nanoparticles. We demonstrate that surface templated EPD (STEPD) assembly, which combines EPD with top-down nanofabrication, allows a wide range of nanoparticles to be built up into arbitrary structures with high speed, scalability, and excellent fidelity. We will also discuss some of the current colloid chemical limitations and challenges in STEPD assembly for sub-10 nm nanoparticles and for the fabrication of densely packed single particle arrays.
  • Item
    No Preview Available
    Spectroelectrochemistry of CdSe/CdS Core-Shell Quantum Dots
    Ashokan, A ; Hutchison, JA ; Mulvaney, P (AMER CHEMICAL SOC, 2024-02-16)
  • Item
    No Preview Available
    The Multiple Roles of Na Ions in Highly Efficient CZTSSe Solar Cells
    Yang, W ; Ji, Y ; Chen, W ; Pan, Y ; Chen, Z ; Wu, S ; Russo, SP ; Xu, Y ; Smith, TA ; Chesman, A ; Mulvaney, P ; Liu, F (WILEY-V C H VERLAG GMBH, 2024-02-11)
    Sodium (Na) doping is a well-established technique employed in chalcopyrite and kesterite solar cells. While various improvements can be achieved in crystalline quality, electrical properties, or defect passivation of the absorber materials by incorporating Na, a comprehensive demonstration of the desired Na distribution in CZTSSe is still lacking. Herein, a straightforward Na doping approach by dissolving NaCl into the CZTS precursor solution is proposed. It is demonstrated that a favorable Na ion distribution should comprise a precisely controlled Na+ concentration at the front surface and an enhanced distribution within the bottom region of the absorber layer. These findings demonstrated that Na ions play several positive roles within the device, leading to an overall power conversion efficiency of 12.51%.
  • Item
    Thumbnail Image
    Polarity-Tunable Field Effect Phototransistors
    Fu, J ; Jiang, H ; Nie, C ; Sun, F ; Tang, L ; Li, Y ; Li, Z ; Xiong, W ; Yang, J ; Li, X ; Zhou, D ; Shen, J ; Feng, S ; Shi, H ; Mulvaney, P ; Wei, X (AMER CHEMICAL SOC, 2023-05-30)
    Field-effect phototransistors feature gate voltage modulation, allowing dynamic performance control and significant signal amplification. A field-effect phototransistor can be designed to be inherently either unipolar or ambipolar in its response. However, conventionally, once a field-effect phototransistor has been fabricated, its polarity cannot be changed. Herein, a polarity-tunable field-effect phototransistor based on a graphene/ultrathin Al2O3/Si structure is demonstrated. Light can modulate the gating effect of the device and change the transfer characteristic curve from unipolar to ambipolar. This photoswitching in turn produces a significantly improved photocurrent signal. The introduction of an ultrathin Al2O3 interlayer also enables the phototransistor to achieve a responsivity in excess of 105 A/W, a 3 dB bandwidth of 100 kHz, a gain-bandwidth product of 9.14 × 1010 s-1, and a specific detectivity of 1.91 × 1013 Jones. This device architecture enables the gain-bandwidth trade-off in current field-effect phototransistors to be overcome, demonstrating the feasibility of simultaneous high-gain and fast-response photodetection.