Please see my full list of publications.
Solar module yield gains from structured ribbons
Feb 25, 2021|
We compare the effects of planar & triangular ribbons, light redirecting films, wires and a new proposed pentagonal ribbon geometry, in fixed optimal inclination, building-integrated (façade), and single-axis tracking installation scenarios of modules in portrait and landscape orientation. We conclude that to fully evaluate the effectiveness of a specific ribbon design, the annual energy yield must consider the angular irradiance distribution and weather conditions at a specific location, the installation scenario, and the module orientation.
Laser contacts from POx/Al2O3 passivation stacks
Aug 20, 2020|
• n+ laser doping demonstrated from POx/Al2O3 passivation stacks on silicon. • Metallised J0 of 540 fA cm−2 for n+ laser-doped region with Rsheet of 39.5 Ω/□. • Consistent with values for POCl3 furnace diffusions, indicating minimal defects. • Same POx/Al2O3 stack provides J0 of 2.5 fA cm−2 on undiffused planar surfaces. • 23.6% simulated efficiency for laser-doped n-type PERL cell based on POx/Al2O3.
Destructive Reverse Bias in Perovskite Tandem Modules
Jun 11, 2020|
We demonstrate how perovskite hysteresis can result in permanent reductions in power output in perovskite/silicon tandem modules—including irreversible hotspot-induced damage—from only brief periods of shading.
Impact of Al Doping on Surface Passivation of TiOx
Apr 13, 2020|
In this work, we find that the crystallization of ALD TiOx is very sensitive to the film’s thickness, where a small increase in TiOx thickness can trigger a phase change from amorphous TiOx into anatase, which causes a significant increase in J0s. More importantly, we demonstrate that the incorporation of Al ions into the TiOx films inhibits crystallization, which in turn retains excellent passivation for thicker TiOx.
Predicting realistic annual yield for solar modules
Sep 12, 2019|
• Optimizing module design for a maximum annual performance. • Detailed gain and loss analysis from cell under STC to module in real environment. • Understanding the impact of module material on the annual module yield. • Impact of angular light, temperatures, lower irradiances on module performance. • Impact of weather condition (ambient temperature, wind speed) on module performance.
Methodology for Generating High Time Resolution Typical Meteorological Year Data for Accurate Photovoltaic Energy Yield Modelling
Jul 30, 2019|
Accurate energy yield prediction is of utmost importance for commercial scale photovoltaic systems. One key parameter crucial to the prediction accuracy is the quality of solar radiation data. Most energy yield prediction models rely on Typical Meteorological Year data with maximum temporal resolution of one hour. In this work we develop a methodology to generate Typical Meteorological Year data with much higher time resolution using gap filling methods that aim to maintain high-quality solar radiation data for photovoltaic yield modelling.
State-of-Energy-Research Conference (SoERC) 2019
Jul 03, 2019|
The SoERC conference is Australia's first research-only conference that highlights the latest advances in energy research. The conference takes place on 3rd and 4th July at the Australian National University, Canberra.
Lifetime energy yield and economic viability of perovskite/silicon tandem modules
Apr 29, 2019|
Impact of perovskite solar cell degradation on the lifetime energy yield and economic viability of perovskite/silicon tandem modules
Analysis of Hotspots in Half Cell Modules Undetected by Current Test Standards
Mar 07, 2019|
Hotspots are a major source of failure for photovoltaic modules in the field. The current standard for module testing IEC 61215-2 can leave critical hotspots undetected in half-cut solar cell modules.
2-D Hot Spot Temperature Simulation for PV Modules
Jul 24, 2018|
A two‐step method to simulate the spatially resolved temperature of a partially shaded cell in a crystalline silicon photovoltaic (PV) module is presented and tested.
Phosphorus diffused LPCVD polysilicon passivated contacts
Jul 06, 2018|
We present a passivated contact technology based on polysilicon deposited using low pressure chemical vapour deposition (LPCVD) over an ultra-thin silicon dioxide layer, which achieves an excellent surface passivation with implied open-circuit voltage of 735 mV, a recombination prefactor below 1 fA cm−2 and contact resistivity below 1 mΩcm2.