$15.6m Marsden funding a record for Massey
Thursday, 2 November 2017
$15.6m Marsden funding a record for Massey
Massey
researchers have received more than $15.6 million from the
Royal Society of New Zealand's annual Marsden Fund for 26
projects, a record number of projects funded and total
funding.
The projects include studying super-heavy elements, Māori resilience in post-disaster contexts and sexuality and ethical deliberation in residential aged care.
The 26 successful Marsden grants – made up of 10 “Fast-Start” grants for new and emerging researchers and 16 standard grants – represent 18.4 per cent of the total $84.6 million funding pool this year.
Vice-Chancellor Professor Jan Thomas congratulated the researchers. “This is a tremendous effort and outcome, not only by our world-class researchers but also the many academics and support staff they work with whose contribution is so vital to ensure the quality and impact of the research proposals are prioritised through the various stages of the process,” Professor Thomas says. “Competition for research funding is intense in the New Zealand research environment. The 133 projects selected to receive funding nationwide were chosen from more than 1000 preliminary proposals.”
Assistant Vice-Chancellor Research, Academic and Enterprise Professor Giselle Byrnes says success in this Marsden round showcases the research Massey is known for, tackling the big issues and wicked problems the world is facing and doing this within a rigorous and scholarly context. “The range and diversity of the research projects also showcases the extent of Massey’s broad research expertise,” Professor Byrnes says.
The College of Sciences received grants for an unprecedented 21 projects, which shared more than $12 million of the funding.
One of
the projects will be led by Distinguished Professor Peter
Schwerdtfeger of the New Zealand Institute for Advanced
Study. It receives $910,000 to explore the heaviest elements
in the periodic table.
“Superheavy elements with an
atomic number between 113 [Nihonium] and 118 [Oganesson]
have only very recently been added to the periodic table and
given names. Exploring and extending the periodic table of
elements towards the super-heavy region, with atomic numbers
larger than 103 is driven by the desire to test the very
limits of the existence of matter,” Professor
Schwerdtfeger says.
The complex electronic and nucleonic
structures require state-of-the-art quantum theoretical
approaches due to the huge electric fields involved, which
the project proposes to develop and apply, he says. “A
wealth of entirely new phenomena awaits discovery due to the
interplay between relativistic electrons and nucleons moving
in quantal orbits subject to very strong electrostatic
repulsion. Theoretical calculations of chemical and physical
behaviour are indispensable to guide, design, and explain
the one-atom-at-a-time experiments at the yet-unexplored
regime of mass and charge.”
Living wages, disaster management, bacteria’s memory and DNA diversity – School of Psychology
The College of Humanities and Social Sciences had another strong year with four projects sharing over $2 million. One successful project, Living wages: Transforming lives, transforming work?, received $845,000 and will be led by Professor Stuart Carr of the School of Psychology.
The research aims to inform public deliberations on living wages in an age of societal and organisational transformation. It will consider diverse perspectives of employers and employees.
Māori, Catastrophic Events, and Collective Development of Culture-based Disaster Management Theory and Practice – School of Psychology.
Senior lecturer in indigenous disaster management Dr Christine Kenney receives a Fast-Start grant of $300,000 to explore Māori resilience in post-disaster contexts. The research pioneers Māori disaster management theory through exploring how Māori attributes can act as cultural technologies to manage catastrophic disasters. These attributes will be theorised and assembled within a disaster management framework that is culturally acceptable and widely applicable.
What counts as consent? Sexuality and ethical deliberation in residential aged care – School of Social Work
A project led by Associate Professor Mark Henrickson will receive $845,000 to study sexuality and ethical deliberation in residential aged care. The project will contribute to ethical theory in practice by interrogating and informing conceptualisations of consent in the domain of sexuality and intimacy in residential aged care. It will identify practice implications by interviewing staff, residents and family of residents.
Stuff Memories Are Made Of: How Bacteria Remember and Learn from Environmental Signals –Institute of Natural and Mathematical Sciences
Dr Olin Silander will lead a project
that receives $895,000 to look at the memory of bacteria.
Bacterial growth rates and death rates depend critically on
the way they respond to changes in environmental conditions.
For example, they may employ different stress responses to
survive antibiotic treatment. This phenomenon – when
previous experiences affect future behaviour – is commonly
referred to as memory.
The team will quantitatively
measure the effects of bacterial memory on growth and
survival, using a range of approaches to understand when
memories are formed and what affects the length of time they
are maintained. This work will give them novel insight into
the effects and mechanisms of memory in bacterial
cells
From genotypes to phenotypes: Quantifying the functional load – Institute of Fundamental Sciences
Professor Murray Cox will lead a project
that receives $925,000 to look at our biggest genetic
questions. “We now have a good understanding of genetic
diversity within species, especially in humans,” Professor
Cox says. “Simply describing diversity was never the main
goal of genetics…the question was always bigger: What
fraction of genetic change actually causes a corresponding
change in phenotype?”
The research proposes to offer a
more representative picture of human diversity, with
immediate downstream relevance to the history and health of
Pacific peoples by looking at small traditional villages in
eastern Indonesia. It will analyse and quantify how much DNA
diversity has functional effects. This will provide
evolutionary insight into the genome dynamics of traditional
human populations within the kinds of small community
networks where most human evolution historically
occurred.
The greedy algae that are great for our environment: why do they pay an energy penalty to gorge phosphate? - School of Engineering and Advanced Technology.
Professor Benoit Guieysse will lead a
project that receives $920,000 to look at the mysteries
surrounding polyphosphate. Polyphosphate is found in all
organisms and is involved in functions such as energy and
phosphorus storage and stress response in bacteria. The
project seeks to investigate the evolutionary, ecological,
and industrial implications of this
metabolism.
Improved modelling in
evolutionary transcriptomics and proteomics will advance
understanding of plant adaptation – Institute of
Fundamental
Sciences
Professor Peter
Lockhart receives $925,000 to lead a project
looking at plant
adaptation in New Zealand and the effects of
climate change on New Zealand alpine flora. The study will
look at whether evolution can keep pace with climate change,
which in part depends on how fast plant species evolve to
occupy the available environmental niches. The proposal
seeks to better understand current physiological responses
and investigate how and why these physiologies evolved.
Biodiversity and the ecology of emerging
infectious diseases ¬– Institute of Natural and
Mathematical
Sciences
Professor Mick
Roberts will lead a project team that receives $415,000 look
at the emergence of infectious diseases in relation to
climate change. Their goal is to understand the dynamics of
emerging pathogens and to recognise patterns in these
dynamics that could serve as early warnings of an epidemic.
By combining ecological and epidemiological models,
researchers will describe how changes in ecosystems may
precipitate epidemics, how an infectious disease may change
the ecosystem balance, and how evolving pathogens may also
precipitate epidemics.
Other successful
projects:
• Professor Doug Armstrong ($870,000)
– Is individual variation relevant to population
dynamics?
• Professor Stephen Marsland ($880,000)
– AviaNZ: Making Sure New Zealand Birds Are
Heard
• Associate Professor Georg Zellmer
($832,000) – Water in spinel: a robust hygrometer for
the Earth and Planetary Sciences
• Dr Helen
Fitzsimons ($795,000) – A new role for HDAC4 in
neuronal morphogenesis and memory
• Professor
Thomas Pfeiffer ($735,000) – Predict to decide:
Investigating decision markets in theory, experiments and
practical applications
• Professor Carlo Laing
($670,000) – Function from structure: accurate reduced
models of neuronal networks
• Associate Professor
Adriane Rini ($630,000) – The Logic of Ordinary
Language
• Professor Martin Hazelton ($535,000) –
Lattice polytope samplers: theory, methods and
applications
• Dr Sharon McLennan ($300,000) –
Multiple coincidences: Cuban medical cooperation in the
Pacific
• Dr Luke Fullard ($300,000) –
Understanding friction in granular mixtures: an
experimental and modelling study
• Dr Carl Mesarich
($300,000) – Making the switch: cell surface
modifications that enable plant-pathogenic fungi to
differentiate and maintain infection-related cellular
morphotypes during host colonization
• Dr Miao Qiao
($300,000) – Subgraph Matching: Theory and
Practice
• Dr Emilia Nowak ($300,000) –
Encapsulation of an aqueous liquid in a drop of aqueous
liquid
• Dr Ebubekir Avci ($300,000) – Optical
Nano-Machines to Study Single-Molecules
• Dr
Alastair Clement ($300,000) – Sea-level is not level:
unraveling the drivers of spatial and temporal variations in
past sea-level changes around the New Zealand
coast
• Dr Xiang-Qian Zhu ($300,000) – Pattern
Discovery from Big Medical Data
• Dr Honour McCann
($300,000) – Population Genomics of an Emergent Plant
Infectious
Disease