High-performance smart solar powered on-chip capacitive energy storage. High performance and environmentally friendly on-chip power system is the key bottleneck issue limiting the further performance improvement and miniaturisation of ever-increasing portable optoelectronic devices. Building on previous work, including recent breakthroughs of on-chip photonic devices in patterned graphene oxide thin film and the record-breaking nanophotonics solar cells, the project aims to investigate a new con ....High-performance smart solar powered on-chip capacitive energy storage. High performance and environmentally friendly on-chip power system is the key bottleneck issue limiting the further performance improvement and miniaturisation of ever-increasing portable optoelectronic devices. Building on previous work, including recent breakthroughs of on-chip photonic devices in patterned graphene oxide thin film and the record-breaking nanophotonics solar cells, the project aims to investigate a new concept of super-resolution direct laser printing and simultaneous dopant activation of graphene oxide thin films. It is expected that the conceptually new development of the functional graphene oxide film patterning will allow for smart solar-powered on-chip power systems that outperform the state-of-the-art pollution generating batteries.Read moreRead less
Investigation into a graphene ultra-flat lens array for silicon solar cells breaking the Shockley-Queisser efficiency limit. Based on a recent discovery of the giant refractive index modulation associated with graphene oxide to graphene transition upon laser exposure and the breakthrough of graphene silicon solar cells. This project aims to investigate a new concept of an integratible, broadband, dispersionless, ultraflat lens array from nanostructured graphene oxide/graphene. This conceptually ....Investigation into a graphene ultra-flat lens array for silicon solar cells breaking the Shockley-Queisser efficiency limit. Based on a recent discovery of the giant refractive index modulation associated with graphene oxide to graphene transition upon laser exposure and the breakthrough of graphene silicon solar cells. This project aims to investigate a new concept of an integratible, broadband, dispersionless, ultraflat lens array from nanostructured graphene oxide/graphene. This conceptually new development of functional graphene oxide/graphene lens array in combination with a lumpy nanoparticle enabled back light trapping layer will allow for the non-reciprocal coupling of the broadband solar light into the photovoltaic devices with minimised entropy losses. Thus ultrahigh efficiency solar cells exceeding the conventional theoretical limit can be developed.Read moreRead less
Understanding and controlling of photoferroelectricity for photoenergy uses. The project seeks to develop high performance photoferroelectric materials for a wide range of photoenergy conversion technologies like photovoltaics and photocatalytics. For the past 50 years, ferroelectric photovoltaics have only been an academic curiosity due to their low energy conversion efficiency relative to the popular semiconductor photovoltaics. This project aims to unlock the potential of ferroelectric photov ....Understanding and controlling of photoferroelectricity for photoenergy uses. The project seeks to develop high performance photoferroelectric materials for a wide range of photoenergy conversion technologies like photovoltaics and photocatalytics. For the past 50 years, ferroelectric photovoltaics have only been an academic curiosity due to their low energy conversion efficiency relative to the popular semiconductor photovoltaics. This project aims to unlock the potential of ferroelectric photovoltaics by introducing an ion co-substitution, which is coupled with electron-pinning, into promising ferroelectric materials and investigating the resultant photo-excited electronic and electrical properties. It is anticipated that the outcomes from this proposed project will provide a solution for optimal ferroelectric visible light absorption to achieve high power conversion efficiency in ferroelectric materials for practical photoenergy applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100067
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
A femtosecond Mmd-IR optical parametric amplifier source for waveguide nonlinear optics. The mid-infrared is an immensely important region of the optical spectrum for sensing toxic or illicit molecules or pollutants using their spectral fingerprints. The equipment will facilitate the development of new techniques for sensing based on nonlinear processes in waveguides.
Discovery Early Career Researcher Award - Grant ID: DE170100320
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Increasing efficiency in tandem silicon-perovskite solar cells. This project aims to increase the efficiency of silicon solar cells. Organo-halide perovskites semiconductors will improve crystalline silicon’s single-junction solar cell efficiency from its current ~25% record to the theoretical limit of 30% at an affordable cost for the market. This project will integrate organo-halide perovskite semiconductors with silicon cells in a tandem solar cell, a structure that harvests sunlight more eff ....Increasing efficiency in tandem silicon-perovskite solar cells. This project aims to increase the efficiency of silicon solar cells. Organo-halide perovskites semiconductors will improve crystalline silicon’s single-junction solar cell efficiency from its current ~25% record to the theoretical limit of 30% at an affordable cost for the market. This project will integrate organo-halide perovskite semiconductors with silicon cells in a tandem solar cell, a structure that harvests sunlight more efficiently. This project should lead to the development of solar cells with state-of-the-art efficiencies greater than 30% at an affordable cost for the energy market.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101300
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Molecules and mirrors: new directions in chemistry and organic optoelectronics using hybrid light or matter states. This project will explore the exotic mixtures of light and matter that can form when molecules are placed in nano-scale mirror cavities. If the chemical reactivity of these mixed light or matter states can be controlled, a new generation of efficient, organic solar energy capture and storage devices is anticipated.
Photonic crystals at visible wavelengths. Three dimensional sculptured nano-structures made at a very high spatial resolution will open way to control light emission, propagation, and transmission at the visible wavelengths. Optically thin and transparent solar cells will be able to harvest light using structures.
Discovery Early Career Researcher Award - Grant ID: DE150100427
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
All-in-one Functional Nanocrystal Inks for Printed Inorganic Solar Cells. At present, manufacturing solar panels involves expensive high temperature and high vacuum processes. The bottleneck to cheaper solar power is the ability to design new methods of manufacturing. The ability to print the active components of a solar cell is an excellent way to mitigate these costs. This project aims to focus on developing the knowledge to print the most crucial component of a solar cell - the light absorbin ....All-in-one Functional Nanocrystal Inks for Printed Inorganic Solar Cells. At present, manufacturing solar panels involves expensive high temperature and high vacuum processes. The bottleneck to cheaper solar power is the ability to design new methods of manufacturing. The ability to print the active components of a solar cell is an excellent way to mitigate these costs. This project aims to focus on developing the knowledge to print the most crucial component of a solar cell - the light absorbing layer. Innovative nanoscience will be used to develop novel solar inks composed of tiny semiconductor crystals. The formulation and transformation of these inks into efficient semiconductor light absorbing layers, with a clear view to cheaper printed solar cells, will be the key objective of this project.Read moreRead less
III-V semiconductor nanowire solar cells without p-n junctions. This project proposes a new class of nanowire solar cells that do not rely on conventional electrical (p-n) junction for photo-generated charge carrier separation. Instead the band structure of the semiconductors is engineered to form a misalignment which leads to the spatial separation of carriers. This approach is expected to fundamentally change the design of solar cells, eliminating the technologically challenging need for formi ....III-V semiconductor nanowire solar cells without p-n junctions. This project proposes a new class of nanowire solar cells that do not rely on conventional electrical (p-n) junction for photo-generated charge carrier separation. Instead the band structure of the semiconductors is engineered to form a misalignment which leads to the spatial separation of carriers. This approach is expected to fundamentally change the design of solar cells, eliminating the technologically challenging need for forming good electrical junctions, while retaining all advantages inherent to III-V semiconductor nanowire solar cells. More importantly, the device concept proposed is expected to have implications for a wider class of solar cells based on exotic/novel materials or nanostructures where achieving both n- and p-doping may be challenging.Read moreRead less
Towards high performance compound semiconductor nanowire array solar cells. Semiconductor nanowires have great potential for photovoltaic applications due to their unique structural, electrical and optical properties. This project aims to establish a new research program to integrate highly sophisticated theoretical modelling, material growth and nanofabrication capabilities to develop high performance III-V compound semiconductor nanowire array solar cells. New concepts, strategies and technolo ....Towards high performance compound semiconductor nanowire array solar cells. Semiconductor nanowires have great potential for photovoltaic applications due to their unique structural, electrical and optical properties. This project aims to establish a new research program to integrate highly sophisticated theoretical modelling, material growth and nanofabrication capabilities to develop high performance III-V compound semiconductor nanowire array solar cells. New concepts, strategies and technologies developed by this project will not only advance the fundamental understanding of many intriguing physics in nanowire materials and devices, but also pave the way towards high efficiency photovoltaics to address the world’s energy-related issues. Read moreRead less