Your search keyword '"Catriona M.O. Macinnis-Ng"' showing total 23 results

1. Convergence in hydraulic architecture, water relations and primary productivity amongst habitats and across seasons in Sydney

Author

Kate McClenahan, Catriona M.O. Macinnis-Ng, and Derek Eamus

Subjects

Ecophysiology, Ecology, Biome, Plant Biology & Botany, Xylem, Plant Science, Woodland, Biology, Seasonality, medicine.disease, Photosynthesis, Habitat, medicine, Mangrove, Agronomy and Crop Science

Abstract

Convergence in leaf traits across biomes demonstrates generality in plant functioning. Relationships between hydraulic architecture and photosynthesis are less well studied. We investigated convergence in minimum leaf water potential (Ψmin), conductivity per sapwood area (ks), Huber value (Hv) and xylem embolism and photosynthesis in four habitats across two seasons (summer and winter) in the Sydney region in heathland, woodland (ridge-top), woodland (below-ridge) and mangrove. Seasonality strongly influenced all parameters in all habitats. Winter Ψmin values were lower than those for summer in the heathland and both woodland habitats but summer Ψmin values were lower than those for winter in the mangrove. Summer ks values were higher than winter values in all habitats, while Hv was higher in winter than summer for all habitats. Loss of conductance due to xylem embolism was larger in summer than winter in eight of 11 species. We also investigated relationships between the hydraulic parameters across habitats. There was a strong, significant inverse correlation between log-transformed Hv and log-transformed ks, which held across the seasons. There were significant inverse correlations between Ψmin and xylem embolism, which held within seasons but not across seasons. We found a strong, significant positive correlation between ks and Ψmin also within seasons but not across seasons and a significant negative correlation between xylem embolism and ks for winter but only a weak negative correlation between xylem embolism and ks for summer. We believe the seasonal patterns and relationships in hydraulic architecture and water relations are driven by the cost of efficient sapwood. This is demonstrated by the negative correlation between photosynthetic rate and ks in winter.

Published

2020

2. Seasonal variations in tree water use and physiology correlate with soil salinity and soil water content in remnant woodlands on saline soils

Author

Catriona M.O. Macinnis-Ng, Melanie J. B. Zeppel, Derek Eamus, and Anthony R. Palmer

Subjects

0106 biological sciences, Hydrology, Soil salinity, Eucalyptus macrorhyncha, Ecology, Specific leaf area, biology, Vapour Pressure Deficit, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Salinity, Agronomy, Soil water, Environmental science, Dryland salinity, Soil fertility, Ecology, Evolution, Behavior and Systematics, 010606 plant biology & botany, Earth-Surface Processes

Abstract

Ecophysiological studies of remnant woodlands in saline environments are scarce. We investigated seasonal fluctuations in soil water and salinity together with leaf and branch traits (area-based maximum assimilation (Amax), foliar nitrogen, specific leaf area (SLA) and Huber value (Hv)) and sap velocities of Eucalyptus macrorhyncha at four semi-arid sites in south-eastern Australia. Summer and winter soil salinities (10 cm depth) were 15–35 dS m−1 and 8–10 dS m−1 respectively. Gravimetric soil water content in the upper 20 cm was 2–5% in summer and 7–23% in winter, resulting in a significant inverse correlation between soil water and soil salinity. We found significant correlations between soil conditions and plant traits and function across seasons. Soil water content was significantly correlated with foliar N, SLA, Hv and maximum sap velocity while soil salinity was significantly correlated with Amax, Hv and maximum sap velocity. Correlations indicate co-variation of soil conditions and plant physiology in response to environmental conditions such as solar radiation and vapour pressure deficit (D). E. macrorhyncha tolerates the dual stresses of high salinity and low soil water during summer. While the plants appeared unhealthy, our data show that remnant vegetation can remain functional even in close proximity to saline scalds.

Published

2016

3. Leaf age-related and diurnal variation in gas exchange of kauri (Agathis australis)

Author

Luitgard Schwendenmann, Belinda E. Medlyn, Catriona M.O. Macinnis-Ng, Tristan Webb, Yan-Shih Lin, School of Biological Sciences [Auckland], University of Auckland [Auckland], School of environnement, Ecologie et Ecophysiologie Forestières [devient SILVA en 2018] (EEF), Institut National de la Recherche Agronomique (INRA)-Université de Lorraine (UL), Hawkesbury Institute for the Environment [Richmond] (HIE), Western Sydney University (UWS), and Western Sydney University

Subjects

0106 biological sciences, Ecophysiology, Stomatal conductance, water use efficiency, Vapour Pressure Deficit, [SDV]Life Sciences [q-bio], Plant Science, Photosynthesis, 010603 evolutionary biology, 01 natural sciences, water fluxes, Botany, Water-use efficiency, carbon fluxes, Ecology, Evolution, Behavior and Systematics, Agathis australis, Assimilation rates, photosynthesis, biology, Diurnal temperature variation, 15. Life on land, biology.organism_classification, Photosynthetically active radiation, stomatal conductance, southern conifers, 010606 plant biology & botany, New Zealand

Abstract

New Zealand kauri (Agathis australis) (D.Don) Lindl. is a large and long-lived tree species endemic to the species-rich forests of the north of the North Island. Agathis australis are culturally and ecologically significant, but little is known about their ecophysiology. In particular, environmental drivers of fluxes of carbon and water for A. australis trees have not been quantified. We measured leaf gas exchange to explore the effect of leaf age, tree size, foliar nitrogen concentration, photosynthetically active radiation (PAR) and vapour pressure deficit (D) on assimilation rates (A) and stomatal conductance (g(s)). We also measured carbon isotope discrimination of leaves and applied an optimal stomatal behaviour model. Both g(s) and A were highest for year one leaves (130mmolm(-2)s(-1) and 5molm(-2)s(-1), respectively) then declined with leaf age to < 80mmolm(-2)s(-1) and < 3molm(-2)s(-1), respectively, in 4-5-year-old leaves. Instantaneous water use efficiency (A/g(s)) was highly variable, but there was no leaf age-related pattern. Our diurnal results indicate that A. australis g(s) peaks early in the day (before 0900 h at 250mmolm(-2)s(-1)) and A is comparatively low, remaining below 9molm(-2)s(-1) throughout the day. Overall, water use efficiency is low based on intrinsic water use efficiency and the stomatal model. Isotopic analysis indicated moderate water use efficiency over the life of leaves compared to other temperate conifers. This information is valuable for modelling carbon and water fluxes of A. australis and for improving our understanding of the threat of summer droughts to these forest giants.

Published

2017

4. Rainfall partitioning into throughfall and stemflow and associated nutrient fluxes: land use impacts in a lower montane tropical region of Panama

Author

Luitgard Schwendenmann, Henry Müller, Catriona M.O. Macinnis-Ng, and Eric E. Flores

Subjects

Hydrology, Canopy, Nutrient cycle, Stemflow, Deposition (aerosol physics), Environmental Chemistry, Secondary forest, Environmental science, Precipitation, Interception, Throughfall, Earth-Surface Processes, Water Science and Technology

Abstract

Land-use change alters catchment hydrology by influencing the quality and quantity of partitioned rainfall. We compared rainfall partitioning (throughfall, stemflow and interception) and nutrient concentrations in rainfall, throughfall and stemflow in three land-use types [primary forest (PF), secondary forest (SF) and agriculture (A)] in Panama. Measurements of throughfall were highly variable which may have masked seasonal and land use differences but it was clear that throughfall at agricultural sites made up a larger proportion of gross precipitation than at forest sites. Of incident precipitation, 94% became throughfall in agriculture sites while 83 and 81% of gross precipitation became throughfall in PF and SF, respectively. The size of the precipitation event was the main driver of variation in throughfall and stemflow. Consistent patterns in nutrient cycling were also difficult to identify. Vegetation has a vital role in delivering nutrients as throughfall deposition of K was often larger than precipitation deposition. A canopy budget model indicated that canopy exchange was often more dominant than dry deposition. Throughfall was generally enriched with nutrients, especially K and Mg, with enrichment factors of up to 17 and 5 for K and Mg, respectively, in PF. In contrast, Ca was sometimes taken up by the canopy. Values of nutrient deposition were high (with up to 15, 3, 30 and 15 kg ha−1 month−1 in stand deposition of Ca, Mg, K and Na, respectively in PF), possibly due to the slash-and-burn agricultural practices in the area or marine inputs. Throughfall and stemflow are vital sources of nutrients in these ecosystems.

Published

2012

5. Is productivity of mesic savannas light limited or water limited? Results of a simulation study

Author

Derek Eamus, Daniel Taylor, Jason Beringer, Mathew Williams, Lindsay B. Hutley, Melanie J. B. Zeppel, Catriona M.O. Macinnis-Ng, and Rhys Whitley

Subjects

Canopy, Hydrology, Global and Planetary Change, Stomatal conductance, Ecology, Eddy covariance, Atmospheric sciences, Evapotranspiration, Dry season, Environmental Chemistry, Environmental science, Interception, Leaf area index, Water content, General Environmental Science

Abstract

A soil–plant–atmosphere model was used to estimate gross primary productivity (GPP) and evapotranspiration (ET) of a tropical savanna in Australia. This paper describes model modifications required to simulate the substantial C4 grass understory together with C3 trees. The model was further improved to include a seasonal distribution of leaf area and foliar nitrogen through 10 canopy layers. Model outputs were compared with a 5-year eddy covariance dataset. Adding the C4 photosynthesis component improved the model efficiency and root-mean-squared error (RMSE) for total ecosystem GPP by better emulating annual peaks and troughs in GPP across wet and dry seasons. The C4 photosynthesis component had minimal impact on modelled values of ET. Outputs of GPP from the modified model agreed well with measured values, explaining between 79% and 90% of the variance and having a low RMSE (0.003–0.281 g C m � 2 day � 1 ). Approximately, 40% of total annual GPP was contributed by C4 grasses. Total (trees and grasses) wet season GPP was approximately 75–80% of total annual GPP. Light-use efficiency (LUE) was largest for the wet season and smallest in the dry season and C4 LUE was larger than that of the trees. A sensitivity analysis of GPP revealed that daily GPP was most sensitive to changes in leaf area index (LAI) and foliar nitrogen (Nf) and relatively insensitive to changes in maximum carboxylation rate (Vcmax), maximum electron transport rate (Jmax) and minimum leaf water potential (cmin). The modified model was also able to represent daily and seasonal patterns in ET, (explaining 68–81% of variance) with a low RMSE (0.038–0.19 mm day � 1 ). Current values of Nf, LAI and other parameters appear to be colimiting for maximizing GPP. By manipulating LAI and soil moisture content inputs, we show that modelled GPP is limited by light interception rather than water availability at this site.

Published

2011

6. Latent heat fluxes during two contrasting years from a juvenile plantation established over a waste disposal landscape

Author

Sigfredo Fuentes, Melanie J. B. Zeppel, Catriona M.O. Macinnis-Ng, Isa A. M. Yunusa, Derek Eamus, and Anthony R. Palmer

Subjects

Hydrology, Canopy, Tree canopy, ved/biology, Latent heat, ved/biology.organism_classification_rank.species, Environmental science, Sensible heat, Revegetation, Bowen ratio, Groundcover, Water Science and Technology, Waste disposal

Abstract

Summary Revegetation to restore hydrological function to highly disturbed landscapes used for waste disposal or mining is often constrained by the initial low rates of water-use during the early phases of the developing vegetation. This problem is especially pronounced for revegetation that relies on trees due to their prolonged lead-time to achieve canopy closure. Initial low rates of water-use can however be overcome if a groundcover of quick-growing herbaceous species is planted first. To demonstrate the significance of groundcover in the early phase of revegetation, we undertook an energy balance analysis using the Bowen ratio technique for a juvenile plantation growing over a heavy groundcover of herbaceous species on a waste disposal site in 2006/2007 and 2007/2008. Latent heat flux (λE) from the landscape (trees plus groundcover and soil) fluctuated widely between 0.5 and 22 MJ m−2 d−1 and accounted for between 60% and 90% of available energy at the site; this percentage exceeded 100% during periods with significant advection. The latent heat emanating from the tree canopy (λEc), derived from sapflow measurements in the trees, accounted for only between 4% and 18% of daily λE with the balance arising from the groundcover that intercepted more than 90% of incident solar radiation. The λEc was mostly smaller than the net radiation intercepted by the tree canopy (Rnc) with the excess energy expended by the canopy as sensible heat (Hc), which accounted for up to 18% of bulk sensible heat from the landscape. The λE expressed as ET was in excess (114%) of rainfall in the relatively dry first growing (September–May) season, when rainfall was only 87% of the long-term average. It was, however, smaller (80%) than rainfall during the second season, when the annual rainfall was close to the long-term average. We used these data to develop an empirical model for predicting λE from soil–water content and the prevailing evaporative demand.

Published

2011

7. Root biomass distribution and soil properties of an open woodland on a duplex soil

Author

Sigfredo Fuentes, Melanie J. B. Zeppel, Anthony P. O'Grady, Isa A. M. Yunusa, Daniel Taylor, Rhys Whitley, Derek Eamus, Catriona M.O. Macinnis-Ng, and Anthony R. Palmer

Subjects

Topsoil, Angophora bakeri, biology, Eucalyptus sclerophylla, Soil Science, Soil science, Plant Science, biology.organism_classification, Bulk density, Hydraulic conductivity, Loam, Botany, Environmental science, Soil horizon, Subsoil

Abstract

Data on the distribution of root biomass are critical to understanding the ecophysiology of vegetation communities. This is particularly true when models are applied to describe ecohydrology and vegetation function. However, there is a paucity of such information across continental Australia. We quantified vertical and horizontal root biomass distribution in a woodland dominated by Angophora bakeri and Eucalyptus sclerophylla on the Cumberland Plains near Richmond, New South Wales. The site was characterised by a duplex (texture contrast) soil with the A horizon (to 70 cm) consisting of loamy sand and the B horizon (to > 10 m) consisting of sandy clay. The topsoil had a smaller bulk density, a smaller water holding capacity but a larger organic component and a larger hydraulic conductivity in comparison to the subsoil. Root biomass was sampled to 1.5 m depth and declined through the soil profile. Whilst total biomass in the B horizon was relatively small, its contribution to the function of the trees was highly significant. Coarse roots accounted for approximately 82% of the root mass recovered. Lateral distribution of fine roots was generally even but coarse roots were more likely to occur closer to tree stems. Variation in tree diameter explained 75% of the variation in total below-ground biomass. The trench method suggested the belowground biomass was 6.03 ± 1.21 kg m−2 but this method created bias towards sampling close to tree stems. We found that approximately 68% of root material was within a 2 m radius of tree stems and this made up 54% of the total number of samples but in reality, only approximately 5 to 10% of the site is within a 2 m radius of tree stems. Based on these proportions, our recalculated belowground biomass was 2.93 ± 0.59 kg m−2. These measurements provide valuable data for modeling of ecosystem water use and productivity.

Published

2009

8. Comparing the Penman–Monteith equation and a modified Jarvis–Stewart model with an artificial neural network to estimate stand-scale transpiration and canopy conductance

Author

Rhys Whitley, Catriona M.O. Macinnis-Ng, Melanie J. B. Zeppel, Derek Eamus, and Belinda E. Medlyn

Subjects

Hydrology, Canopy, Moisture, Vapour Pressure Deficit, Environmental science, Penman–Monteith equation, Atmospheric sciences, Water content, Surface water, Canopy conductance, Water Science and Technology, Transpiration

Abstract

SUMMARY The responses of canopy conductance to variation in solar radiation, vapour pressure deficit and soil moisture have been extensively modelled using a Jarvis–Stewart (JS) model. Modelled canopy conductance has then often been used to predict transpiration using the Penman–Monteith (PM) model. We previously suggested an alternative approach in which the JS model is modified to directly estimate transpiration rather than canopy conductance. In the present study we used this alternative approach to model tree water fluxes from an Australian native forest over an annual cycle. For comparative purposes we also modelled canopy conductance and estimated transpiration via the PM model. Finally we applied an artificial neural network as a statistical benchmark to compare the performance of both models. Both the PM and modified JS models were parameterised using solar radiation, vapour pressure deficit and soil moisture as inputs with results that compare well with previous studies. Both models performed comparably well during the summer period. However, during winter the PM model was found to fail during periods of high rates of transpiration. In contrast, the modified JS model was able to replicate observed sapflow measurements throughout the year although it too tended to underestimate rates of transpiration in winter under conditions of high rates of transpiration. Both approaches to modelling transpiration gave good agreement with hourly, daily and total sums of sapflow measurements with the modified JS and PM models explaining 87% and 86% of the variance, respectively. We conclude that these three approaches have merit at different time-scales.

Published

2009

9. Investigations of the temporal variation of cyanobacterial and other phytoplanktonic cells at the offtake of a large reservoir, and their survival following passage through it

Author

Tsuyoshi Kobayashi, Catriona M.O. Macinnis-Ng, Ronald Patra, Brian Sanderson, Lee C. Bowling, Bruce Hindmarsh, and Tim Ingleton

Subjects

Hydrology, Cyanobacteria, biology, Ecology, Anabaena, Dinoflagellate, Aquatic Science, biology.organism_classification, Marine Biology & Hydrobiology, Upstream and downstream (DNA), Diatom, Ceratium, Phytoplankton, Hydrobiology

Abstract

The survival and subsequent growth potential of Anabaena spp. and other filamentous cyanobacteria and the cells of Aulacoseira spp. (diatom) and Ceratium hirundinella (dinoflagellate) following passage through the Multi Level Inlet Tower (MLIT) and offtake works at Chaffey Reservoir in New South Wales, Australia was investigated in late summer. The study aimed to test whether the phytoplankton cells were destroyed or otherwise rendered less viable during passage through the outlet works. The reservoir was strongly thermally stratified with a shallow surface mixed layer, which contributed to considerable temporal variability in the numbers of phytoplankton cells present immediately opposite the intake portal of the outlet works. To compensate, considerable replicate sampling was undertaken both upstream and downstream of the MLIT. Results indicate limited destruction of cyanobacteria, with fewer cells present immediately downstream compared to upstream. Greater destruction of cells was indicated at lower mean daily discharge rates compared to higher discharge rates. Filament lengths of both cyanobacteria and Aulacoseira were also reduced during passage. There was no apparent reduction in Ceratium cell number. Laboratory incubation studies on surviving cells collected downstream indicated no impairment on the viability of any taxa. Calculations of rates-of-strain likely to be experienced by the phytoplankton as they transited through the offtake revealed very high stress being applied to the filaments and cells at the valve, and within the spillway sections of the works. These were several orders of magnitude greater than published values shown to disrupt cells and filaments, and to impair viability for subsequent growth in laboratory studies. However, exposure times to the high rates-of-strain at Chaffey Reservoir were brief, which may reduce the impacts of the high turbulence. The conclusions were that unless cyanobacterial cell destruction during passage through an outlet works can be shown to be more effective at larger reservoirs, the withdrawal of warm, cyanobacterial infested waters from close to the surface is unlikely to provide an acceptable management action for the prevention of cold water pollution downstream. © 2008 Springer Science+Business Media B.V.

Published

2008

10. Long term trends of stand transpiration in a remnant forest during wet and dry years

Author

Isa A. M. Yunusa, Catriona M.O. Macinnis-Ng, Rhys Whitley, Derek Eamus, and Melanie J. B. Zeppel

Subjects

Hydrology, Water balance, Stomatal conductance, Evapotranspiration, Environmental science, Leaf area index, Water content, Surface water, Canopy conductance, Water Science and Technology, Transpiration

Abstract

Summary Daily and annual rates of stand transpiration in a drought year and a non-drought year are compared in order to understand the adaptive responses of a remnant woodland to drought and predict the effect of land use change. Two methods were used to estimate stand transpiration. In the first, the ratio of sap velocity of a few trees measured for several hundred days to the mean sap velocity of many trees measured during brief sampling periods (generally 6–7 trees for 5 or 6 days), called the E sv method is used to scale temporally from the few intensive study periods. The second method used was the Penman–Monteith (P–M) equation (called the E PM method). Weather variables and soil moisture were used to predict canopy conductance, which in turn was used to predict daily and annual stand transpiration. Comparisons of daily transpiration estimated with the two methods showed larger values for the E PM method during a drought year and smaller values for the E PM when the rainfall was above average. Generally, though, annual estimates of stand transpiration were similar using the two methods. The E sv method produced an estimate of 318 mm (61% of rainfall) in the drought year and 443 mm (42%) in the year having above average rainfall. The E PM method estimated stand transpiration as 379 mm (73%) and 398 mm (37%), respectively, for the two years. Both estimates of annual stand transpiration demonstrated that the remnant forest showed resilience to an extreme and long-term drought. More importantly, the annual estimates showed that in dry years a larger proportion of rainfall was used as transpiration, and groundwater recharge was absent but in years with above average rainfall recharge was significantly increased. Changes in leaf area index were minimal between years and changes in stomatal conductance were the dominant mechanism for adapting to the drought. The remnant forest rapidly responded to increased water availability after the drought through a new flush of leaves and increased stomatal conductance.

Published

2008

11. Fluorescence imaging application: effect of leaf age on seagrass photokinetics

Author

Catriona M.O. Macinnis-Ng, Peter J. Ralph, and C. Frankart

Subjects

0106 biological sciences, Chlorophyll a, 010604 marine biology & hydrobiology, Halophila ovalis, Plant Science, 15. Life on land, Aquatic Science, Biology, biology.organism_classification, Photosynthesis, 01 natural sciences, Marine Biology & Hydrobiology, Spatial heterogeneity, chemistry.chemical_compound, Seagrass, chemistry, Botany, Spatial variability, Posidonia australis, Zostera capricorni, 010606 plant biology & botany

Abstract

We used the Imaging-PAM fluorometer to map spatial variability of photosynthesis in three seagrass species, Halophila ovalis, Zostera capricorni and Posidonia australis. Photosynthesis was described by relative photosynthetic rate (PS/50), effective quantum yield (ΦPSII), non-photochemical quenching (NPQ and qN), electron transport rate (ETR) and leaf absorptivity. Photosynthetic patterns were linked to leaf age and light climate but patterns were not consistent across species. Longitudinal heterogeneity in photosynthesis was apparent along the leaves of all three species while lateral spatial heterogeneity was found only across Z. capricorni and H. ovalis leaves. Age of leaf tissue, determined by longitudinal location on the leaf, strongly influenced photosynthetic activity of Z. capricorni and P. australis. A comparison of H. ovalis leaves of differing maturity demonstrated the influence of leaf age on photosynthetic activity, yet a comparison of Z. capricorni leaves of differing maturity showed no leaf-age effects. Variations in stress-induced changes across a seagrass leaf can be used to identify areas or particular regions of the leaf, which are more susceptible to photodamage. Clear evidence of substantial within-leaf heterogeneity in photosynthetic activity (i.e., a two-fold variation in half saturation constant along a leaf of P. australis) has serious implications for use of small sections of leaf for photosynthetic incubations (such as O2 or single-point chlorophyll a fluorescence measurements). © 2004 Elsevier B.V. All rights reserved.

Published

2005

12. Species assemblage patterns around a dominant emergent tree are associated with drought resistance

Author

Sarah V. Wyse, Luitgard Schwendenmann, Michael J. Clearwater, Catriona M.O. Macinnis-Ng, and Bruce R. Burns

Subjects

Canopy, Stomatal conductance, Physiology, Climate Change, Drought tolerance, Species distribution, Araucariaceae, Plant Science, Trees, Soil, Stress, Physiological, Agathis australis, biology, Plant Stems, Ecology, fungi, food and beverages, Wilting, Water, Plant community, Plant Transpiration, Carbon Dioxide, biology.organism_classification, Adaptation, Physiological, Droughts, Plant Leaves, Tracheophyta, Seedlings, Plant Stomata, Linear Models, Seasons, New Zealand

Abstract

Water availability has long been recognized as an important driver of species distribution patterns in forests. The conifer Agathis australis (D. Don) Lindl. (kauri; Araucariaceae) grows in the species-rich forests of northern New Zealand. It is accompanied by distinctive species assemblages, and during summer the soil beneath A. australis is often significantly drier than soils beneath surrounding broadleaved angiosperm canopy species. We used a shade house dry-down experiment to determine whether species that grow close to A. australis differed in drought tolerance physiology compared with species that rarely grow close to A. australis. Stomatal conductance (g(s)) was plotted against leaf water potential (ψ) to identify drought tolerance strategies. Seedlings of species that occur in close spatial association with A. australis (including A. australis seedlings) were most resistant to drought stress, and all displayed a drought avoidance strategy of either declining gs to maintain ψ or simultaneous declines in g(s) and ψ. The species not commonly occurring beneath A. australis, but abundant in the surrounding forest, were the most drought-sensitive species and succumbed relatively quickly to drought-induced mortality with rapidly declining gs and ψ values. These results were confirmed with diurnal measurements of g(s) and assimilation rates throughout the day, and leaf wilting analysis. We conclude that the varied abilities of the species to survive periods of drought stress as seedlings shapes the composition of the plant communities beneath A. australis trees. Furthermore, forest diversity may be impacted by climate change as the predicted intensification of droughts in northern New Zealand is likely to select for drought-tolerant species over drought-intolerant species.

Published

2013

13. Applying a SPA model to examine the impact of climate change on GPP of open woodlands and the potential for woody thickening

Author

Melanie J. B. Zeppel, Derek Eamus, Catriona M.O. Macinnis-Ng, and Mathew Williams

Subjects

Hydrology, Stomatal conductance, Biogeochemical cycle, Ecology, Primary production, Aquatic Science, Atmospheric sciences, Ecohydrology, Photosynthetic acclimation, Soil water, Environmental science, Water-use efficiency, Water content, Ecology, Evolution, Behavior and Systematics, Earth-Surface Processes

Abstract

Woody thickening is a global phenomenon that influences landscape C density, regional ecohydrology and biogeochemical cycling. The aim of the work described here is to test the hypothesis that increased atmospheric CO2 concentration, with or without photosynthetic acclimation, can increase gross primary production (GPP) and that this can explain woody thickening. We examine mechanisms underlying the response of GPP and highlight the importance of changes in soil water content by applying a detailed soil–plant–atmosphere model. Through this model, we show that CO2 enrichment with decreased or increased D and photosynthetic acclimation results in decreased canopy water use because of reduced gs. The decline in water use coupled with increased photosynthesis resulted in increased GPP, water-use efficiency and soil moisture content. This study shows that this is a valid mechanism for GPP increase because of CO2 enrichment coupled with either a decrease or an increase in D, in water-limited environments. We also show that a large increase in leaf area index could be sustained in the future as a result of the increased soil moisture content arising from CO2 enrichment and this increase was larger if D decreases rather than increases in the future. Large-scale predictions arising from this simple conceptual model are discussed and found to be supported in the literature. We conclude that woody thickening in Australia and probably globally can be explained by the changes in landscape GPP and soil moisture balance arising principally from the increased atmospheric CO2 concentration. Copyright © 2010 John Wiley & Sons, Ltd.

Published

2011

14. Rates of nocturnal transpiration in two evergreen temperate woodland species with differing water-use strategies

Author

Catriona M.O. Macinnis-Ng, David T. Tissue, Derek Eamus, Daniel Taylor, and Melanie J. B. Zeppel

Subjects

Canopy, Stomatal conductance, Eucalyptus, Physiology, Vapour Pressure Deficit, Myrtaceae, Climate, Diurnal temperature variation, Plant Biology & Botany, Water, Plant Transpiration, Plant Science, Evergreen, Circadian Rhythm, Soil, Water potential, Agronomy, Species Specificity, Botany, Environmental science, New South Wales, Water use, Transpiration

Abstract

Nocturnal fluxes may be a significant factor in the annual water budget of forested ecosystems. Here, we assessed sap flow in two co-occurring evergreen species (Eucalyptus parramattensis and Angophora bakeri) in a temperate woodland for 2 years in order to quantify the magnitude of seasonal nocturnal sap flow (En) under different environmental conditions. The two species showed different diurnal water relations, demonstrated by different diurnal curves of stomatal conductance, sap flow and leaf water potential. The relative influence of several microclimatic variables, including wind speed (U), vapour pressure deficit (D), the product of U and D (UD) and soil moisture content, were quantified. D exerted the strongest influence on En (r2 = 0.59-0.86), soil moisture content influenced En when D was constant, but U and UD did not generally influence En. In both species, cuticular conductance (Gc) was a small proportion of total leaf conductance (Gs) and was not a major pathway for En. We found that En was primarily a function of transpiration from the canopy rather than refilling of stem storage, with canopy transpiration accounting for 50-70% of nocturnal flows. Mean En was 6-8% of the 24-h flux across seasons (spring, summer and winter), but was up to 19% of the 24-h flux on some days in both species. Despite different daytime strategies in water use of the two species, both species demonstrated low night-time water loss, suggesting similar controls on water loss at night. In order to account for the impact of En on pre-dawn leaf water potential arising from the influence of disequilibria between root zone and leaf water potential, we also developed a simple model to more accurately predict soil water potential (ψs). © The Author 2010. Published by Oxford University Press. All rights reserved.

Published

2010

15. An analysis of the sensitivity of sap flux to soil and plant variables assessed for an Australian woodland using a soil-plant-atmosphere model

Author

Sigfredo Fuentes, Rhys Whitley, Derek Eamus, Mathew Williams, Melanie J. B. Zeppel, Isa A. M. Yunusa, Daniel Taylor, Catriona M.O. Macinnis-Ng, and Anthony R. Palmer

Subjects

Hydrology, Stomatal conductance, Eucalyptus sclerophylla, Plant Science, Vegetation, Biology, biology.organism_classification, Canopy conductance, Botany, Soil horizon, Agronomy and Crop Science, Water content, Water use, Transpiration

Abstract

Daily and seasonal patterns of tree water use were measured for the two dominant tree species, Angophora bakeri E.C.Hall (narrow-leaved apple) and Eucalyptus sclerophylla (Blakely) L.A.S. Johnson & Blaxell (scribbly gum), in a temperate, open, evergreen woodland using sap flow sensors, along with information about soil, leaf, tree and micro-climatological variables. The aims of this work were to: (a) validate a soil–plant–atmosphere (SPA) model for the specific site; (b) determine the total depth from which water uptake must occur to achieve the observed rates of tree sap flow; (c) examine whether the water content of the upper soil profile was a significant determinant of daily rates of sap flow; and (d) examine the sensitivity of sap flow to several biotic factors. It was found that: (a) the SPA model was able to accurately replicate the hourly, daily and seasonal patterns of sap flow; (b) water uptake must have occurred from depths of up to 3 m; (c) sap flow was independent of the water content of the top 80 cm of the soil profile; and (d) sap flow was very sensitive to the leaf area of the stand, whole tree hydraulic conductance and the critical water potential of the leaves, but insensitive to stem capacitance and increases in root biomass. These results are important to future studies of the regulation of vegetation water use, landscape-scale behaviour of vegetation, and to water resource managers, because they allow testing of large-scale management options without the need for large-scale manipulations of vegetation cover.

Published

2008

16. A modified Jarvis-Stewart model for predicting stand-scale transpiration of an Australian native forest

Author

Catriona M.O. Macinnis-Ng, Melanie J. B. Zeppel, Nicholas Armstrong, Rhys Whitley, Derek Eamus, and Isa A. M. Yunusa

Subjects

Hydrology, Ecology, Vapour Pressure Deficit, Soil Science, Agronomy & Agriculture, Plant Science, Woodland, Canopy conductance, Native forest, Soil water, Environmental science, Leaf area index, Water use, Transpiration

Abstract

Rates of water uptake by individual trees in a native Australian forest were measured on the Liverpool Plains, New South Wales, Australia, using sapflow sensors. These rates were up-scaled to stand transpiration rate (expressed per unit ground area) using sapwood area as the scalar, and these estimates were compared with modelled stand transpiration. A modified Jarvis-Stewart modelling approach (Jarvis 1976), previously used to calculate canopy conductance, was used to calculate stand transpiration rate. Three environmental variables, namely solar radiation, vapour pressure deficit and soil moisture content, plus leaf area index, were used to calculate stand transpiration, using measured rates of tree water use to parameterise the model. Functional forms for the model were derived by use of a weighted non-linear least squares fitting procedure. The model was able to give comparable estimates of stand transpiration to those derived from a second set of sapflow measurements. It is suggested that short-term, intensive field campaigns where sapflow, weather and soil water content variables are measured could be used to estimate annual patterns of stand transpiration using daily variation in these three environmental variables. Such a methodology will find application in the forestry, mining and water resource management industries where long-term intensive data sets are frequently unavailable. © 2007 Springer Science+Business Media B.V.

Published

2008

17. Comparing model predictions and experimental data for the response of stomatal conductance and guard cell turgor to manipulations of cuticular conductance, leaf-to-air vapour pressure difference and temperature: feedback mechanisms are able to account for all observations

Author

Catriona M.O. Macinnis-Ng, Daniel Taylor, Steve Shanahan, Derek Eamus, and Lionel De Silva

Subjects

Stomatal conductance, Air Pressure, Eucalyptus, Physiology, Vapor pressure, Chemistry, Air, Plant Biology & Botany, fungi, Turgor pressure, Electric Conductivity, Temperature, Conductance, Commelina, Plant Transpiration, Plant Science, Models, Biological, Plant Epidermis, Vicia faba, Guard cell, Botany, Plant Stomata, Biophysics, Transpiration

Abstract

Stomata respond to increasing leaf-to-air vapour pressure difference (LAVPD) (D) by closing. The mechanism by which this occurs is debated. A role for feedback and peristomatal transpiration has been proposed. In this paper, we apply a recent mechanistic model of stomatal behaviour, and compare model and experimental data for the influence of increasing D on stomatal conductance. We manipulated cuticular conductance (gc) by three independent methods. First, we increased gc by using a solvent mixture applied to both leaf surfaces prior to determining stomatal responses to D; second, we increased gc by increasing leaf temperature at constant D; and third, we coated a small area of leaf with a light oil to decrease gc. In all three experiments, experimental data and model outputs showed very close agreement. We conclude, from the close agreement between model and experimental data and the fact that manipulations of gc, and hence cuticular transpiration, influenced gs in ways consistent with a feedback mechanism, that feedback is central in determining stomatal responses to D. © 2008 The Authors.

Published

2007

18. Human Impacts on Seagrasses: Eutrophication, Sedimentation, and Contamination

Author

David A. Tomasko, Stephanie Seddon, Kenneth A. Moore, Catriona M.O. Macinnis-Ng, and Peter J. Ralph

Subjects

Fishery, biology, Ecology, Environmental science, Zostera marina, Sedimentation, Contamination, biology.organism_classification, Eutrophication

Abstract

Growth of human populations along coastal environments, as well as poor water management practices have resulted in the complete loss of seagrass meadows (Kemp et al., 1983; Larkum and West, 1990; Short and Wyllie-Echeverria, 1996; Peters et al., 1997). For example, the catastrophic loss of seagrasses clearly illustrated in Fig. 1 is linked to coastal development and associated reduction in water quality. © 2006/2007 Springer. All Rights Reserved.

Published

2007

19. Use of fluorescence-based ecotoxicological bioassays in monitoring toxicants and pollution in aquatic systems: Review

Author

Peter J. Ralph, R. A. Smith, Catriona M.O. Macinnis-Ng, and Cliff Seery

Subjects

Pollution, Chlorophyll a, Phototroph, Health, Toxicology and Mutagenesis, Aquatic ecosystem, media_common.quotation_subject, Biology, chemistry.chemical_compound, chemistry, Environmental chemistry, Environmental Chemistry, Ecotoxicology, Bioassay, Organism, Environmental Sciences, media_common, Toxicant

Abstract

Chlorophyll a fluorescence has the potential to become a valuable ecotoxicological endpoint, which could be used with a range of aquatic phototrophs. Chlorophyll a fluorescence bioassays have been applied in the assessment of heavy metals, herbicides, petrochemicals and nutrients. The strengths of this endpoint are that it is rapid, non-invasive and non-destructive, while the major weakness is the lack of clear ecological relevance. We provide an overview of chlorophyll a fluorescence applications in ecotoxicology. We reviewed test conditions, parameters and protocols used to date and found standardised protocols to be lacking. The most favoured fluorescence parameters were maximum quantum yield (Fv/Fm) and effective quantum yield (ΦPSII); microalgae were the most widely used tested organism, herbicides the most commonly tested toxicant, while most studies lacked a summary statistic (such as EC50). We recommend that future research in aquatic chlorophyll a fluorescence ecotoxicology focus on standardisation of test protocols and statistical techniques. © 2007 Taylor & Francis.

Published

2007

20. Temporal and spatial variation in the morphology of the brown macroalga Hormosira banksii (Fucales, Phaeophyta)

Author

David A. Morrison, Peter J. Ralph, and Catriona M.O. Macinnis-Ng

Subjects

geography, geography.geographical_feature_category, biology, Ecology, Hormosira, Morphological variation, Morphology (biology), Estuary, Plant Science, Aquatic Science, biology.organism_classification, Marine Biology & Hydrobiology, Taxon, Habitat, Spatial variability, Fucales, Ecology, Evolution, Behavior and Systematics

Abstract

Hormosira banksii is a morphologically variable macroalgal species from southeastern and southern Australia, which has been previously categorised into ecoforms according to habitat. This study is by far the largest quantitative evaluation of morphological variation in H. banksii, covering 74 sites from South Australia, Victoria, New South Wales and Tasmania. Morphological features from 505 samples were analysed using principal components analysis, with the patterns identified being statistically assessed with a Monte Carlo permutation test. There was considerable morphological variation between samples taken at several marine (but not estuarine) sites in both 1994 and 1999. However, this variation was not consistent across either morphological features or populations, and presumably represents random fluctuations. Analysis of the entire dataset demonstrated a significant difference between samples growing in marine and estuarine habitats. Further assessment of variation within these two groups revealed some significantly different populations based on geographical locations but not habitat variation. While this study presents strong evidence for two distinct taxa within H. banksii (marine versus estuarine populations), the taxonomic status of this species should not be altered until genetic studies have been conducted. © 2005 by Walter de Gruyter.

Published

2005

21. Hydraulic architecture and water relations of several species at diverse sites around Sydney

Author

Derek Eamus, Kate McClenahan, and Catriona M.O. Macinnis-Ng

Subjects

Plant ecology, Biomass (ecology), Botany, Plant Biology & Botany, Microclimate, Xylem, Context (language use), Plant Science, Woodland, Mangrove, Biology, Southern Hemisphere, Ecology, Evolution, Behavior and Systematics

Abstract

Seasonal comparisons of leaf water potential, root biomass, hydraulic architecture, xylem embolism and xylem dimensions were made for eight woody species in four diverse habitats (mangroves, coastal heathland, ridge-top woodland and river-flat woodland). In most comparisons, pre-dawn and minimum leaf water potentials were lower in winter than in summer, a result attributed to lower rainfall and a smaller root biomass in winter than in summer. Branch hydraulic conductivities (per unit transverse area, sapwood area or leaf area) were generally larger in summer than in winter across all species in all habitats. An inverse relationship between Huber value and conductivity was observed across all four habitats. Increased solar radiation and evaporative demand in the summer was associated with an increased percentage loss of xylem conductance arising from embolism, compared with winter. These results are discussed in the context of patterns and relationships among water relations, microclimate and hydraulic architecture.

Published

2004

22. In situ impact of multiple pulses of metal and herbicide on the seagrass, Zostera capricorni

Author

Catriona M.O. Macinnis-Ng and Peter J. Ralph

Subjects

Chlorophyll, Time Factors, Photosystem II, Health, Toxicology and Mutagenesis, chemistry.chemical_element, Aquatic Science, Photosynthesis, Fluorescence, chemistry.chemical_compound, Botany, Ecotoxicology, Seawater, Analysis of Variance, biology, Triazines, Zosteraceae, Photosystem II Protein Complex, Pesticide, biology.organism_classification, Copper, Plant Leaves, chemistry, Spectrophotometry, Environmental chemistry, New South Wales, Zostera capricorni, Water Pollutants, Chemical, Toxicant

Abstract

Tides and freshwater inflow which influence water movement in estuarine areas govern the exposure-regime of pollutants. In this experiment, we examined the in situ impact of double pulses of copper and the herbicide Irgarol 1051 on the photosynthesis of the seagrass, Zostera capricorni . Despite a 4-day recovery period between the two 10 h pulses of toxicant, the effective quantum yield of photosystem II (Δ F /Fm′) and total chlorophyll concentrations indicated that multiple-pulses had a greater impact than a single pulse. During the first exposure period, samples exposed to Irgarol 1051 had Δ F /Fm′ values as low as zero while controls remained around 0.6 relative units. After the second exposure period, treated samples recovered to only 0.4 relative units. Samples exposed to copper had Δ F /Fm′ values around 0.3 relative units during the first exposure period and while these samples recovered before the second dose, they remained below 0.2 relative units after the second exposure period. Alternate samples were also exposed to one toxicant, allowed to recover and then exposed to the other toxicant. Δ F /Fm′ values indicated that copper exposure followed by Irgarol 1051 exposure was more toxic than Irgarol 1051 exposure followed by copper exposure.

Published

2003

23. Ecosystem services: an ecophysiological examination

Author

Melanie J. B. Zeppel, Brad R. Murray, Derek Eamus, Grant C. Hose, Daniel Taylor, and Catriona M.O. Macinnis-Ng

Subjects

business.industry, Water flow, Environmental resource management, Total economic value, Biodiversity, Plant Science, Ecosystem services, Goods and services, Botany, Environmental science, Ecosystem, Dryland salinity, business, Ecology, Evolution, Behavior and Systematics, Waste disposal

Abstract

This review aims to discuss ecosystem services, provide illustrative case studies at catchment and local scales and present future research needs. This review discusses the following: (1) Ecosystem services (ES) are those goods and services that are provided by or are attributes of ecosystems that benefit humans. Examples of ES include the timber derived from a forest, the prevention of soil and coastal erosion by vegetation and the amelioration of dryland salinity through prevention of rises in the water table by trees. The provision of ES globally is in decline because of a lack of awareness of the total economic value of ES in the public, policy and political fora. (2) Providing a scientific understanding of the relationships among ecosystem structure, function and provision of ES, plus determining actual economic value of ES, are the central challenges to environmental scientists (including triple-bottom-line economists). (3) Some ES are widely dispersed throughout many different ecosystems. Carbon accumulation in trees and the contribution of biodiversity to ES provision are two examples of highly dispersed attributes common to many ecosystems. In contrast, other ES are best considered within the context of a single defined ecosystem (although they may occur in other ecosystems too). Mangroves as ‘nursery’ sites for juvenile fish is one example. (4) Examples of catchment-scale and local-scale provision of ES are discussed, along with future research issues for the nexus between ES and environmental sciences.

Published

2005