University of New South Wales

ARC National Competitive Grants · FY 2026 · 2026-01

Identification and functional analysis of long noncoding RNAs in cognition. Noncoding RNAs make up the majority of the human genome yet their function is poorly understood. We aim to discover a functional role for long noncoding RNAs (lncRNAs) in cognition. This will be achieved by identifying candidate lncRNAs associated with cognitive processes in humans, selecting and imaging these lncRNAs in rodents, and then knocking down their activity to demonstrate how they regulate learning, memory and perception. Our project will generate the first comprehensive assessment of spatiotemporal expression of lncRNAs and provide a causal relationship between lncRNAs and cognition. This will have benefits for understanding how lncRNAs contribute to brain function in healthy brains, across development and with ageing. Field of research: 3105 - Genetics Technical advances in molecular biology have enabled significant breakthroughs in understanding the brain and how it works. One example is the human genome project, which highlights the role of 'junk DNA' in brain function. Once thought to be a by-product of evolution, it is increasingly clear that RNA created from these regions of DNA have profound and widespread actions across the brain. The aim of this project is to unravel how one type of RNA known as 'long non-coding RNAs (lncRNAs)' can influence cognition, learning and memory. Understanding the role of lncRNAs in the brain will advance our basic understanding of how the brain works, and how it adapts and responds to the environment in which we live. This knowledge is important as we search for answers to understand brain changes in an ageing population, and where brain disorders and mental health disorders are an evolving challenge for society.

GrantConnect (Australian Government grants) · FY 2026 · 2026-01

Understanding cellular adaptation in microgravity with bioengineering... Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2026 · 2026-01

Modeling the impact of online social information on judgments and... Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2026 · 2026-01

Arithmetic Statistics, Dynamics and Quantum Chaos Category: Humanities, Arts and Social Sciences (HASS) Research

ARC National Competitive Grants · FY 2026 · 2026-01

Unravelling Drivers of Cellular Evolution Using Single-Cell Multi-Omics. This project aims to develop algorithms to uncover the molecular drivers of cellular evolution, using single-cell multi-omics data. Understanding how cells evolve is critical for deciphering healthy development and understanding how immune cells respond to disease. Existing methods overlook key interactions between genes and neglect multi-layered molecular data. By developing innovative models that integrate these interactions and data types, the project will identify drivers of cellular changes. This work will enhance global research capabilities, improve our understanding of immune responses, and contribute to Australia’s growth in the rapidly expanding single-cell market. Field of research: 4905 - Statistics Understanding what drives changes in our cells over time is essential to uncovering how the human body develops and responds to its environment. For example, learning how cells adapt as we age can reveal how the body maintains balance and resilience across its lifespan. However, current research is limited by the lack of computational tools that can reliably identify the key molecular changes behind these shifts. This project addresses this gap by developing novel algorithms that use cutting-edge single-cell technologies to pinpoint the biological drivers of cellular change. These tools will make it possible to analyse individual cells in unprecedented detail, and empower researchers to develop new insights into biological processes. This project contributes to positioning Australia as a leader in the rapidly growing single-cell market —expected to exceed USD 100 million locally by 2030—through open-source software, collaboration with industry, and workforce training in genomics and data science. Beyond economic value, this research supports national priorities for “healthier, more resilient communities” by enabling industry and academics to better understand the normal immune response to infection. Outcomes will include publicly available software, with findings shared via workshops and partnerships with researchers and clinicians, ensuring Australian innovation drives the next generation of biomedical discovery.

GrantConnect (Australian Government grants) · FY 2026 · 2026-01

Preserving trust when communicating uncertainty about rare events Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2026 · 2026-01

Unified Near- and Far-Field Communications for Future Wireless Networks Category: Humanities, Arts and Social Sciences (HASS) Research

ARC National Competitive Grants · FY 2026 · 2026-01

Unravelling ammonia slip in zero-carbon rich-lean staged combustors. Ammonia, which can be produced via renewable electricity, has potential as a zero-carbon fuel in gas turbine engines. In emerging rich-lean staged combustion systems, ammonia slip, the emission of unburned ammonia in the primary rich stage is a significant unsolved issue, since it leads to large emissions of oxides of nitrogen when consumed in the second stage. Using large-scale, first principles direct numerical simulations, we aim to provide basic understanding of two proposed mechanisms for ammonia slip that involve local quenching: the interaction with a cold wall or via aerodynamic straining in turbulence. Understanding these mechanisms will facilitate the design of mitigation strategies, enabling ammonia-fuelled zero-carbon engines. Field of research: 4012 - Fluid Mechanics and Thermal Engineering The global energy system must rapidly transition to low-carbon sources if severe climate change is to be avoided. Australia's potential for renewable electricity generation greatly exceeds our domestic needs, and could make a sizeable contribution to this transition if this energy were embodied in chemical form, such as via ammonia or hydrogen. Either fuel would likely be transported in the form of ammonia to reduce costs. Gas turbines could offer a robust, low-cost, and efficient means to use either fuel to produce electricity in the destination market. Ammonia can be burned in a gas turbine, which would improve overall economics, but emissions of oxides of nitrogen are unacceptably high. In emerging rich-lean staged combustors, the bypassing of ammonia from the fuel-rich first stage (ammonia slip) to the fuel-lean second stage is believed to lead to production of nitrogen oxides in the second stage due to oxidation of fuel-bound nitrogen, however the source of ammonia slip is unknown. This project seeks to evaluate, in a fundamental setting, two proposed pathways for ammonia slip that involve local flame quenching: the interaction with a cold wall or via aerodynamic straining in turbulent flows. Clarifying these mechanisms will guide the most promising directions for designing lower emissions ammonia combustors, providing an effective pathway to utilise Australia's stranded renewable energy and realise our significant potential contribution to a global zero-carbon future.

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Age dating the Milky Way halo using new data from NASA’s Kepler mission Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Age dating the Milky Way halo using new data from NASA’s Kepler mission Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Dynamic Nuclear Polarization NMR for Accelerating Materials Science Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Dynamic Nuclear Polarization NMR for Accelerating Materials Science Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Quantifying Uncertainty of Risk-Aware Optimization for Safe... Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Quantifying Uncertainty of Risk-Aware Optimization for Safe... Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Building the world’s largest bipolar Stem Cell resource to elucidate... Category: Medical Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

FEELING AGAIN AFTER PARALYSIS: Combining Haptic Virtual Reality and... Category: Medical Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Quantum-confined Semiconducting Polymeric Carbons for CO2... Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Quantum-confined Semiconducting Polymeric Carbons for CO2... Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Constraining future drought projections for Australia Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Post-quantum Biometrics-based Authentication Key Exchange Protocol Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Post-quantum Biometrics-based Authentication Key Exchange Protocol Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Constraining future drought projections for Australia Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Modulating Piezo1 channels in vascular smooth muscle cells to treat... Category: Medical Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Composite 3D Printing through Sensor-Guided Collaborative Robots Category: Humanities, Arts and Social Sciences (HASS) Research

GrantConnect (Australian Government grants) · FY 2025 · 2025-12

Composite 3D Printing through Sensor-Guided Collaborative Robots Category: Humanities, Arts and Social Sciences (HASS) Research