Your search keyword '"Cheesman, Alexander W"' showing total 9 results

1. Microclimate, soil nutrients and stable isotopes in relation to elevation in the Australian Wet Tropics.

Author

Singh Ramesh, Arun, Cheesman, Alexander W., McDonald, William J. F., Crayn, Darren M., and Cernusak, Lucas A.

Subjects

*SEASONAL temperature variations, *RAIN forests, *ANALYTICAL chemistry, *SOIL testing, *STABLE isotopes

Abstract

Microclimate, such as soil and surface air temperatures, and edaphic factors, such as soil organic matter content and nutrient availability, are important parameters of the below‐canopy environment that shape vegetation communities. Yet, the literature examining how microclimate and edaphic properties vary along elevation gradients in tropical rainforests is limited, hindering our understanding of key ecological processes in the forest understory. Here we present an analysis of high‐resolution (15‐min frequency) microclimate data spanning approximately 3 years (December 2019–September 2022) across 20 rainforest sites, ranging from 40 to 1550 meters above sea level (a.s.l.). We also present analyses of soil chemical properties, including δ15N isotope composition from the same study sites. Our study found soils were consistently cooler than air during the day and warmer than air during the night across all sites. The difference in mean temperature between the wettest (summer) and the driest (winter) quarter for both soil and air also increased with elevation, as did the annual temperature range. Soil organic matter content and C:N ratio increased with elevation, in concert with a decline in soil pH. Together, edaphic factors displayed a strong correlation with climatic factors, suggesting temperature as an important driver of soil properties across elevation. Finally, soil δ15N was found to decline with increasing elevation, suggesting a tighter N cycle in high elevation, higher organic matter soils. These observations highlight the existing elevational trends in both microclimate and edaphic variables in the Australian Wet Tropics; understanding how these trends may shift with climate change could be important for predicting impacts on species distributions. [ABSTRACT FROM AUTHOR]

Published

2024

2. Impacts of elevated temperature and vapour pressure deficit on leaf gas exchange and plant growth across six tropical rainforest tree species.

Author

Middleby, Kali B., Cheesman, Alexander W., and Cernusak, Lucas A.

Subjects

*GAS exchange in plants, *RAIN forests, *HIGH temperatures, *PLANT growth, *WATER efficiency, *MICROBIAL inoculants

Abstract

Summary: Elevated air temperature (Tair) and vapour pressure deficit (VPDair) significantly influence plant functioning, yet their relative impacts are difficult to disentangle.We examined the effects of elevated Tair (+6°C) and VPDair (+0.7 kPa) on the growth and physiology of six tropical tree species. Saplings were grown under well‐watered conditions in climate‐controlled glasshouses for 6 months under three treatments: (1) low Tair and low VPDair, (2) high Tair and low VPDair, and (3) high Tair and high VPDair. To assess acclimation, physiological parameters were measured at a set temperature.Warm‐grown plants grown under elevated VPDair had significantly reduced stomatal conductance and increased instantaneous water use efficiency compared to plants grown under low VPDair. Photosynthetic biochemistry and thermal tolerance (Tcrit) were unaffected by VPDair, but elevated Tair caused Jmax25 to decrease and Tcrit to increase. Sapling biomass accumulation for all species responded positively to an increase in Tair, but elevated VPDair limited growth.This study shows that stomatal limitation caused by even moderate increases in VPDair can decrease productivity and growth rates in tropical species independently from Tair and has important implications for modelling the impacts of climate change on tropical forests. [ABSTRACT FROM AUTHOR]

Published

2024

3. Wood traits explain microbial but not termite‐driven decay in Australian tropical rainforest and savanna.

Author

Law, Stephanie, Flores‐Moreno, Habacuc, Cheesman, Alexander W., Clement, Rebecca, Rosenfield, Marc, Yatsko, Abbey, Cernusak, Lucas A., Dalling, James W., Canam, Thomas, Iqsaysa, Isra Abo, Duan, Elizabeth S., Allison, Steven D., Eggleton, Paul, and Zanne, Amy E.

Subjects

RAIN forests, WOOD, SAVANNAS, FORESTS & forestry, WOOD decay, MICROBIAL inoculants, KNOWLEDGE gap theory

Abstract

Variation in decay rates across woody species is a key uncertainty in predicting the fate of carbon stored in deadwood, especially in the tropics. Quantifying the relative contributions of biotic decay agents, particularly microbes and termites, under different climates and across species with diverse wood traits could help explain this variation.To fill this knowledge gap, we deployed woody stems from 16 plant species native to either rainforest (n = 10) or savanna (n = 6) in northeast Australia, with and without termite access. For comparison, we also deployed standardized, non‐native pine blocks at both sites. We hypothesized that termites would increase rates of deadwood decay under conditions that limit microbial activity. Specifically, termite contributions to wood decay should be greater under dry conditions and in wood species with traits that constrain microbial decomposers.Termite discovery of stems was surprisingly low with only 17.6% and 22.6% of accessible native stems discovered in the rainforest and savanna respectively. Contrary to our hypothesis, stems discovered by termites decomposed faster only in the rainforest. Termites discovered and decayed pine blocks at higher rates than native stems in both the rainforest and savanna.We found significant variation in termite discovery and microbial decay rates across native wood species within the same site. Although wood traits explained 85% of the variation in microbial decay, they did not explain termite‐driven decay. For stems undiscovered by termites, decay rates were greater in species with higher wood nutrient concentrations and syringyl:guiacyl lignin ratios but lower carbon concentrations and wood densities.Synthesis. Ecosystem‐scale predictions of deadwood turnover and carbon storage should account for the impact of wood traits on decomposer communities. In tropical Australia, termite‐driven decay was lower than expected for native wood on the ground. Even if termites are present, they may not always increase decomposition rates of fallen native wood in tropical forests. Our study shows how the drivers of wood decay differ between Australian tropical rainforest and savanna; further research should test whether such differences apply world‐wide. [ABSTRACT FROM AUTHOR]

Published

2023

4. Predicting tropical tree mortality with leaf spectroscopy.

Author

Doughty, Christopher E., Cheesman, Alexander W., Riutta, Terhi, Thomson, Eleanor R., Shenkin, Alexander, Nottingham, Andrew T., Telford, Elizabeth M., Huaraca Huasco, Walter, Majalap, Noreen, Arn Teh, Yit, Meir, Patrick, and Malhi, Yadvinder

Subjects

TREE mortality, PARTIAL least squares regression, TROPICAL forests, RAIN forests, CARBON cycle, DEAD trees

Abstract

Do tropical trees close to death have a distinct change to their leaf spectral signature? Tree mortality rates have been increasing in tropical forests, reducing the global carbon sink. Upcoming hyperspectral satellites could be used to predict regions close to experiencing extensive tree mortality during periods of stress, such as drought. Here we show, for a tropical rainforest in Borneo, how imminent tropical tree mortality impacts leaf physiological traits and reflectance. We measured leaf reflectance (400–2500 nm), light‐saturated photosynthesis (Asat), leaf dark respiration (Rdark), leaf mass area (LMA), and % leaf water across five campaigns in a six‐month period during which there were two causes of tree mortality: a major natural drought and a co‐incident tree stem girdling treatment. We find that prior to mortality, there were significant (p < 0.05) leaf spectral changes in the red (650–700 nm), the NIR (1,000–1,400 nm), and SWIR bands (2,000–2,400 nm) and significant reductions in the potential carbon balance of the leaves (increased Rdark and reduced Asat). We show that the partial least squares regression technique can predict mortality in tropical trees across different species and functional groups with medium precision but low accuracy (r2 of.65 and RMSE/mean of 0.58). However, most tree death in our study was due to girdling, which is not a natural form of death. More research is needed to determine if this spectroscopy technique can be applied to tropical forests in general. [ABSTRACT FROM AUTHOR]

Published

2021

5. The effects of an experimental drought on the ecophysiology and fruiting phenology of a tropical rainforest palm.

Author

Vogado, Nara O, Liddell, Michael J, Laurance, Susan G W, Campbell, Mason J, Cheesman, Alexander W, Engert, Jayden E, Palma, Ana C, Ishida, Françoise Y, and Cernusak, Lucas A

Subjects

TROPICAL fruit, RAIN forests, EFFECT of human beings on climate change, WATER efficiency, PLANT phenology, ECOPHYSIOLOGY

Abstract

Aims Anthropogenic climate change is predicted to increase mean temperatures and rainfall seasonality. How tropical rainforest species will respond to this climate change remains uncertain. Here, we analysed the effects of a 4-year experimental throughfall exclusion (TFE) on an Australian endemic palm (Normambya normanbyi) in the Daintree rainforest of North Queensland, Australia. We aimed to understand the impact of a simulated reduction in rainfall on the species' physiological processes and fruiting phenology. Methods We examined the fruiting phenology and ecophysiology of this locally abundant palm to determine the ecological responses of the species to drought. Soil water availability was reduced overall by ~30% under a TFE experiment, established in May 2015. We monitored monthly fruiting activity for 8 years in total (2009–2018), including 4 years prior to the onset of the TFE. In the most recent year of the study, we measured physiological parameters including photosynthetic rate, stomatal conductance and carbon stable isotopes (δ 13C, an integrated measure of water use efficiency) from young and mature leaves in both the dry and wet seasons. Important Findings We determined that the monthly fruiting activity of all palms was primarily driven by photoperiod, mean solar radiation and mean temperature. However, individuals exposed to lower soil moisture in the TFE decreased significantly in fruiting activity, photosynthetic rate and stomatal conductance. We found that these measures of physiological performance were affected by the TFE, season and the interaction of the two. Recovery of fruiting activity in the TFE palms was observed in 2018, when there was an increase in shallow soil moisture compared with previous years in the treatment. Our findings suggest that palms, such as the N. normanbyi , will be sensitive to future climate change with long-term monitoring recommended to determine population-scale impacts. [ABSTRACT FROM AUTHOR]

Published

2020

6. Isotopic and morphologic proxies for reconstructing light environment and leaf function of fossil leaves: a modern calibration in the Daintree Rainforest, Australia.

Author

Cheesman, Alexander W., Duff, Heather, Hill, Kathryn, Cernusak, Lucas A., and McInerney, Francesca A.

Subjects

*LEAF area index, *FOREST canopies, *RAIN forests, *CARBON isotopes, *FOSSILS, *LEAVES, *FOSSIL plants

Abstract

Premise: Within closed‐canopy forests, vertical gradients of light and atmospheric CO2 drive variations in leaf carbon isotope ratios, leaf mass per area (LMA), and the micromorphology of leaf epidermal cells. Variations in traits observed in preserved or fossilized leaves could enable inferences of past forest canopy closure and leaf function and thereby habitat of individual taxa. However, as yet no calibration study has examined how isotopic, micro‐ and macromorphological traits, in combination, reflect position within a modern closed‐canopy forest or how these could be applied to the fossil record. Methods: Leaves were sampled from throughout the vertical profile of the tropical forest canopy using the 48.5 m crane at the Daintree Rainforest Observatory, Queensland, Australia. Carbon isotope ratios, LMA, petiole metric (i.e., petiole‐width2/leaf area, a proposed proxy for LMA that can be measured from fossil leaves), and leaf micromorphology (i.e., undulation index and cell area) were compared within species across a range of canopy positions, as quantified by leaf area index (LAI). Results: Individually, cell area, δ13C, and petiole metric all correlated with both LAI and LMA, but the use of a combined model provided significantly greater predictive power. Conclusions: Using the observed relationships with leaf carbon isotope ratio and morphology to estimate the range of LAI in fossil floras can provide a measure of canopy closure in ancient forests. Similarly, estimates of LAI and LMA for individual taxa can provide comparative measures of light environment and growth strategy of fossil taxa from within a flora. [ABSTRACT FROM AUTHOR]

Published

2020

7. Why are tropical conifers disadvantaged in fertile soils? Comparison of Podocarpus guatemalensis with an angiosperm pioneer, Ficus insipida.

Author

Palma, Ana C, Winter, Klaus, Aranda, Jorge, Dalling, James W, Cheesman, Alexander W, Turner, Benjamin L, and Cernusak, Lucas A

Subjects

ANGIOSPERMS, CONIFERS, MORACEAE, LEAF area, RAIN forests, PHOTOSYNTHETIC rates, PLANT-water relationships

Abstract

Conifers are, for the most part, competitively excluded from tropical rainforests by angiosperms. Where they do occur, conifers often occupy sites that are relatively infertile. To gain insight into the physiological mechanisms by which angiosperms outcompete conifers in more productive sites, we grew seedlings of a tropical conifer (Podocarpus guatemalensis Standley) and an angiosperm pioneer (Ficus insipida Willd.) with and without added nutrients, supplied in the form of a slow-release fertilizer. At the conclusion of the experiment, the dry mass of P. guatemalensis seedlings in fertilized soil was approximately twofold larger than that of seedlings in unfertilized soil; on the other hand, the dry mass of F. insipida seedlings in fertilized soil was ~20-fold larger than seedlings in unfertilized soil. The higher relative growth rate of F. insipida was associated with a larger leaf area ratio and a higher photosynthetic rate per unit leaf area. Higher overall photosynthetic rates in F. insipida were associated with an approximately fivefold larger stomatal conductance than in P. guatemalensis. We surmise that a higher whole-plant hydraulic conductance in the vessel bearing angiosperm F. insipida enabled higher leaf area ratio and higher stomatal conductance per unit leaf area than in the tracheid bearing P. guatemalensis , which enabled F. insipida to capitalize on increased photosynthetic capacity driven by higher nitrogen availability in fertilized soil. [ABSTRACT FROM AUTHOR]

Published

2020

8. Functional traits of lianas in an Australian lowland rainforest align with post‐disturbance rather than dry season advantage.

Author

Buckton, Genevieve, Cheesman, Alexander W., Munksgaard, Niels C., Wurster, Chris M., Liddell, Michael J., and Cernusak, Lucas A.

Subjects

*LIANAS, *TROPICAL forests, *RAIN forests, *BIOGEOCHEMICAL cycles, *PHOTOSYNTHETIC rates, *SEASONS, *ECOLOGICAL disturbances

Abstract

Lianas are an important component of tropical forests; they alter tree mortality and recruitment and impact biogeochemical cycling. Recent evidence suggests that the abundance of lianas in tropical forests is increasing. To understand and predict the effect of lianas on ecosystem processes in tropical forests, it is important to understand the mechanisms through which they compete with trees. In this study, we investigated the functional traits of lianas and trees in a lowland tropical forest in northeast Queensland, Australia. The site is located at 16.1° south latitude and experiences significant seasonality in rainfall, with pronounced wet and dry seasons. It is also subject to relatively frequent disturbance by cyclones. We asked the question of whether the canopy liana community at this site would display functional traits consistent with a competitive advantage over trees in response to disturbance, or in response to dry season water stress. We found that traits that we considered indicative of a dry season advantage (xylem water δ18O as an indicator of rooting depth; leaf and stem tissue δ13C and instantaneous gas exchange as measures of water‐use efficiency) did not differ between canopy lianas and canopy trees. On the other hand, lianas differed from trees in traits that should confer an advantage in response to disturbance (low wood density; low leaf dry matter content; high leaf N concentration; high mass‐based photosynthetic rates). We conclude that the liana community at the study site expressed functional traits geared towards rapid resource acquisition and growth in response to disturbance, rather than outcompeting trees during periods of water stress. These results contribute to a body of literature which will be useful for parameterising a liana functional type in ecosystem models. [ABSTRACT FROM AUTHOR]

Published

2019

9. Plant functional groups within a tropical forest exhibit different wood functional anatomy.

Author

Apgaua, Deborah M. G., Tng, David Y. P., Cernusak, Lucas A., Cheesman, Alexander W., Santos, Rubens M., Edwards, Will J., Laurance, Susan G. W., and Oliveria, Rafael

Subjects

TROPICAL forests, WOOD anatomy, BIOLOGICAL adaptation, PLANT species, RAIN forests, HYDRAULIC conductivity

Abstract

Understanding the anatomical basis of plant water transport in forest ecosystems is crucial for contextualizing community-level adaptations to drought, especially in life-form-rich tropical forests. To provide this context, we explored wood functional anatomy traits related to plant hydraulic architecture across different plant functional groups in a lowland tropical rain forest., We measured wood traits in 90 species from six functional groups (mature-phase, understorey and pioneer trees; understorey and pioneer shrubs; vines) and related these traits to intrinsic water-use efficiency ( WUEi) as a measure of physiological performance. We also examined vessel size distribution patterns across groups to determine trade-offs in theoretical hydraulic safety vs. efficiency., Some plant functional groups exhibited significant differences in vessel parameters and WUEi. Vessel diameters in vines and pioneer trees were two- to threefold greater on average than in understorey trees and shrubs. Contrastingly, vessels in understorey trees and shrubs fell within the smaller size classes, suggesting greater safety mechanisms. In addition to these trends, large vessel dimensions were important predictors of WUEi among the functional groups., We conclude that wood functional anatomy profiles varied across plant functional groups in a tropical rain forest. These groups can therefore serve as a framework for further investigations on structure-function relationships and a sound basis for modelling species responses to drought., A is available for this article. [ABSTRACT FROM AUTHOR]

Published

2017