Your search keyword '"Short Gianotti DJ"' showing total 9 results

1. Proximal remote sensing: an essential tool for bridging the gap between high-resolution ecosystem monitoring and global ecology.

Author

Pierrat ZA, Magney TS, Richardson WP, Runkle BRK, Diehl JL, Yang X, Woodgate W, Smith WK, Johnston MR, Ginting YRS, Koren G, Albert LP, Kibler CL, Morgan BE, Barnes M, Uscanga A, Devine C, Javadian M, Meza K, Julitta T, Tagliabue G, Dannenberg MP, Antala M, Wong CYS, Santos ALD, Hufkens K, Marrs JK, Stovall AEL, Liu Y, Fisher JB, Gamon JA, and Cawse-Nicholson K

Abstract

A new proliferation of optical instruments that can be attached to towers over or within ecosystems, or 'proximal' remote sensing, enables a comprehensive characterization of terrestrial ecosystem structure, function, and fluxes of energy, water, and carbon. Proximal remote sensing can bridge the gap between individual plants, site-level eddy-covariance fluxes, and airborne and spaceborne remote sensing by providing continuous data at a high-spatiotemporal resolution. Here, we review recent advances in proximal remote sensing for improving our mechanistic understanding of plant and ecosystem processes, model development, and validation of current and upcoming satellite missions. We provide current best practices for data availability and metadata for proximal remote sensing: spectral reflectance, solar-induced fluorescence, thermal infrared radiation, microwave backscatter, and LiDAR. Our paper outlines the steps necessary for making these data streams more widespread, accessible, interoperable, and information-rich, enabling us to address key ecological questions unanswerable from space-based observations alone and, ultimately, to demonstrate the feasibility of these technologies to address critical questions in local and global ecology., (© 2025 The Author(s). New Phytologist © 2025 New Phytologist Foundation.)

Published

2025

2. Thermography captures the differential sensitivity of dryland functional types to changes in rainfall event timing and magnitude.

Author

Javadian, Mostafa, Scott, Russell L., Biederman, Joel A., Zhang, Fangyue, Fisher, Joshua B., Reed, Sasha C., Potts, Daniel L., Villarreal, Miguel L., Feldman, Andrew F., and Smith, William K.

Subjects

THERMOGRAPHY, ATMOSPHERIC temperature, PLANT-water relationships, PLANT physiology, WATER supply, RAINFALL

Abstract

Summary: Drylands of the southwestern United States are rapidly warming, and rainfall is becoming less frequent and more intense, with major yet poorly understood implications for ecosystem structure and function. Thermography‐based estimates of plant temperature can be integrated with air temperature to infer changes in plant physiology and response to climate change. However, very few studies have evaluated plant temperature dynamics at high spatiotemporal resolution in rainfall pulse‐driven dryland ecosystems.We address this gap by incorporating high‐frequency thermal imaging into a field‐based precipitation manipulation experiment in a semi‐arid grassland to investigate the impacts of rainfall temporal repackaging.All other factors held constant, we found that fewer/larger precipitation events led to cooler plant temperatures (1.4°C) compared to that of many/smaller precipitation events. Perennials, in particular, were 2.5°C cooler than annuals under the fewest/largest treatment.We show these patterns were driven by: increased and consistent soil moisture availability in the deeper soil layers in the fewest/largest treatment; and deeper roots of perennials providing access to deeper plant available water. Our findings highlight the potential for high spatiotemporal resolution thermography to quantify the differential sensitivity of plant functional groups to soil water availability. Detecting these sensitivities is vital to understanding the ecohydrological implications of hydroclimate change. [ABSTRACT FROM AUTHOR]

Published

2023

3. Dynamic regulation of water potential in Juniperus osteosperma mediates ecosystem carbon fluxes.

Author

Guo JS, Barnes ML, Smith WK, Anderegg WRL, and Kannenberg SA

Subjects

Soil chemistry, Rain, Seasons, Droughts, Juniperus physiology, Water metabolism, Ecosystem, Carbon Cycle, Carbon metabolism

Abstract

Some plants exhibit dynamic hydraulic regulation, in which the strictness of hydraulic regulation (i.e. iso/anisohydry) changes in response to environmental conditions. However, the environmental controls over iso/anisohydry and the implications of flexible hydraulic regulation for plant productivity remain unknown. In Juniperus osteosperma, a drought-resistant dryland conifer, we collected a 5-month growing season time series of in situ, high temporal-resolution plant water potential ( Ψ ) and stand gross primary productivity (GPP). We quantified the stringency of hydraulic regulation associated with environmental covariates and evaluated how predawn water potential contributes to empirically predicting carbon uptake. Juniperus osteosperma showed less stringent hydraulic regulation (more anisohydric) after monsoon precipitation pulses, when soil moisture and atmospheric demand were high, and corresponded with GPP pulses. Predawn water potential matched the timing of GPP fluxes and improved estimates of GPP more strongly than soil and/or atmospheric moisture, notably resolving GPP underestimation before vegetation green-up. Flexible hydraulic regulation appears to allow J. osteosperma to prolong soil water extraction and, therefore, the period of high carbon uptake following monsoon precipitation pulses. Water potential and its dynamic regulation may account for why process-based and empirical models commonly underestimate the magnitude and temporal variability of dryland GPP., (© 2024 The Authors. New Phytologist © 2024 New Phytologist Foundation.)

Published

2024

4. Tree water uptake patterns across the globe.

Author

Bachofen C, Tumber-Dávila SJ, Mackay DS, McDowell NG, Carminati A, Klein T, Stocker BD, Mencuccini M, and Grossiord C

Subjects

Ecosystem, Geography, Plant Roots metabolism, Seasons, Soil chemistry, Drought Resistance, Trees physiology, Water metabolism

Abstract

Plant water uptake from the soil is a crucial element of the global hydrological cycle and essential for vegetation drought resilience. Yet, knowledge of how the distribution of water uptake depth (WUD) varies across species, climates, and seasons is scarce relative to our knowledge of aboveground plant functions. With a global literature review, we found that average WUD varied more among biomes than plant functional types (i.e. deciduous/evergreen broadleaves and conifers), illustrating the importance of the hydroclimate, especially precipitation seasonality, on WUD. By combining records of rooting depth with WUD, we observed a consistently deeper maximum rooting depth than WUD with the largest differences in arid regions - indicating that deep taproots act as lifelines while not contributing to the majority of water uptake. The most ubiquitous observation across the literature was that woody plants switch water sources to soil layers with the highest water availability within short timescales. Hence, seasonal shifts to deep soil layers occur across the globe when shallow soils are drying out, allowing continued transpiration and hydraulic safety. While there are still significant gaps in our understanding of WUD, the consistency across global ecosystems allows integration of existing knowledge into the next generation of vegetation process models., (© 2024 The Authors. New Phytologist © 2024 New Phytologist Foundation.)

Published

2024

5. Leaf surface water, not plant water stress, drives diurnal variation in tropical forest canopy water content.

Author

Xu, Xiangtao, Konings, Alexandra G., Longo, Marcos, Feldman, Andrew, Xu, Liang, Saatchi, Sassan, Wu, Donghai, Wu, Jin, and Moorcroft, Paul

Subjects

PLANT-water relationships, FOREST canopies, MICROWAVE remote sensing, AQUATIC plants, OPTICAL remote sensing, PLANT capacity

Abstract

Summary: Variation in canopy water content (CWC) that can be detected from microwave remote sensing of vegetation optical depth (VOD) has been proposed as an important measure of vegetation water stress. However, the contribution of leaf surface water (LWs), arising from dew formation and rainfall interception, to CWC is largely unknown, particularly in tropical forests and other high‐humidity ecosystems.We compared VOD data from the Advanced Microwave Scanning Radiometer for the Earth Observing System (AMSR‐E) and CWC predicted by a plant hydrodynamics model at four tropical sites in Brazil spanning a rainfall gradient. We assessed how LWs influenced the relationship between VOD and CWC.The analysis indicates that while CWC is strongly correlated with VOD (R2 = 0.62 across all sites), LWs accounts for 61–76% of the diurnal variation in CWC despite being < 10% of CWC. Ignoring LWs weakens the near‐linear relationship between CWC and VOD and reduces the consistency in diurnal variation. The contribution of LWs to CWC variation, however, decreases at longer, seasonal to inter‐annual, time scales.Our results demonstrate that diurnal patterns of dew formation and rainfall interception can be an important driver of diurnal variation in CWC and VOD over tropical ecosystems and therefore should be accounted for when inferring plant diurnal water stress from VOD measurements. See also the Commentary on this article by Gerlien‐Safdi, 231: 5–7. [ABSTRACT FROM AUTHOR]

Published

2021

6. Spatial and temporal shifts in photoperiod with climate change.

Author

Ettinger, A. K., Buonaiuto, D. M., Chamberlain, C. J., Morales‐Castilla, I., and Wolkovich, E. M.

Subjects

CLIMATE change forecasts, CLIMATE change, PHYTOGEOGRAPHY, WOODY plants, PLANT phenology, PHENOLOGY

Abstract

Summary: Climate change causes both temporal (e.g. advancing spring phenology) and geographic (e.g. range expansion poleward) species shifts, which affect the photoperiod experienced at critical developmental stages ('experienced photoperiod'). As photoperiod is a common trigger of seasonal biological responses – affecting woody plant spring phenology in 87% of reviewed studies that manipulated photoperiod – shifts in experienced photoperiod may have important implications for future plant distributions and fitness. However, photoperiod has not been a focus of climate change forecasting to date, especially for early‐season ('spring') events, often assumed to be driven by temperature. Synthesizing published studies, we find that impacts on experienced photoperiod from temporal shifts could be orders of magnitude larger than from spatial shifts (1.6 h of change for expected temporal vs 1 min for latitudinal shifts). Incorporating these effects into forecasts is possible by leveraging existing experimental data; we show that results from growth chamber experiments on woody plants often have data relevant for climate change impacts, and suggest that shifts in experienced photoperiod may increasingly constrain responses to additional warming. Further, combining modeling approaches and empirical work on when, where and how much photoperiod affects phenology could rapidly advance our understanding and predictions of future spatio‐temporal shifts from climate change. [ABSTRACT FROM AUTHOR]

Published

2021

7. Plant responses to rising vapor pressure deficit.

Author

Grossiord, Charlotte, Buckley, Thomas N., Cernusak, Lucas A., Novick, Kimberly A., Poulter, Benjamin, Siegwolf, Rolf T. W., Sperry, John S., and McDowell, Nate G.

Subjects

VAPOR pressure, PLANT mortality, CLIMATE change, FORECASTING, PLANTS

Abstract

Summary: Recent decades have been characterized by increasing temperatures worldwide, resulting in an exponential climb in vapor pressure deficit (VPD). VPD has been identified as an increasingly important driver of plant functioning in terrestrial biomes and has been established as a major contributor in recent drought‐induced plant mortality independent of other drivers associated with climate change. Despite this, few studies have isolated the physiological response of plant functioning to high VPD, thus limiting our understanding and ability to predict future impacts on terrestrial ecosystems. An abundance of evidence suggests that stomatal conductance declines under high VPD and transpiration increases in most species up until a given VPD threshold, leading to a cascade of subsequent impacts including reduced photosynthesis and growth, and higher risks of carbon starvation and hydraulic failure. Incorporation of photosynthetic and hydraulic traits in 'next‐generation' land‐surface models has the greatest potential for improved prediction of VPD responses at the plant‐ and global‐scale, and will yield more mechanistic simulations of plant responses to a changing climate. By providing a fully integrated framework and evaluation of the impacts of high VPD on plant function, improvements in forecasting and long‐term projections of climate impacts can be made. [ABSTRACT FROM AUTHOR]

Published

2020

8. Tracking the phenology of photosynthesis using carotenoid‐sensitive and near‐infrared reflectance vegetation indices in a temperate evergreen and mixed deciduous forest.

Author

Wong, Christopher Y.S., D'Odorico, Petra, Arain, M. Altaf, and Ensminger, Ingo

Subjects

DECIDUOUS forests, PHENOLOGY, REFLECTANCE, CHLOROPHYLL, PHOTOSYNTHESIS, PLANT pigments, COMPOSITION of leaves

Abstract

Summary: Photosynthetic phenology is an important indicator of annual gross primary productivity (GPP). Assessing photosynthetic phenology remotely is difficult for evergreen conifers as they remain green year‐round. Carotenoid‐based vegetation indices such as the photochemical reflectance index (PRI) and chlorophyll/carotenoid index (CCI) are promising tools to remotely track the invisible phenology of photosynthesis by assessing carotenoid pigment dynamics. PRI, CCI and the near‐infrared reflectance of vegetation (NIRV) index may act as proxies of photosynthetic efficiency (ɛ), an important parameter in light‐use efficiency models, or direct proxies of photosynthesis.To understand the physiological mechanisms reflected by PRI and CCI and the ability of vegetation indices to act as proxies of photosynthetic activity for estimating GPP, we measured leaf pigment composition, PRI, CCI, NIRV and photosynthetic activity at the leaf and canopy scales over 2 years in an evergreen and mixed deciduous forest.PRI and CCI captured the large seasonal carotenoid/chlorophyll ratio changes and good relationships were observed between PRI–ɛ and CCI–photosynthesis and NIRV–photosynthesis.PRI‐, CCI‐ and NIRV‐based models effectively tracked observed seasonal GPP. We propose that carotenoid‐based and near‐infrared reflectance vegetation indices may provide useful proxies of photosynthetic activity and can improve remote sensing‐based models of GPP in evergreen and deciduous forests. [ABSTRACT FROM AUTHOR]

Published

2020

9. Detecting the onset of autumn leaf senescence in deciduous forest trees of the temperate zone.

Author

Mariën, Bertold, Balzarolo, Manuela, Dox, Inge, Leys, Sebastien, Lorène, Marchand J., Geron, Charly, Portillo‐Estrada, Miguel, AbdElgawad, Hamada, Asard, Han, and Campioli, Matteo

Subjects

DECIDUOUS plants, DECIDUOUS forests, TEMPERATE forests, LEAF aging, FALL foliage, ALNUS glutinosa, OAK

Abstract

Summary: Information on the onset of leaf senescence in temperate deciduous trees and comparisons on its assessment methods are limited, hampering our understanding of autumn dynamics.We compare five field proxies, five remote sensing proxies and two data analysis approaches to assess leaf senescence onset at one main beech stand, two stands of oak and birch, and three ancillary stands of the same species in Belgium during 2017 and 2018.Across species and sites, onset of leaf senescence was not significantly different for the field proxies based on Chl leaf content and canopy coloration, except for an advanced canopy coloration during the extremely dry and warm 2018. Two remote sensing indices provided results fully consistent with the field data. A significant lag emerged between leaf senescence onset and leaf fall, and when a threshold of 50% change in the seasonal variable under study (e.g. Chl content) was used to derive the leaf senescence onset.Our results provide unprecedented information on the quality and applicability of different proxies to assess leaf senescence onset in temperate deciduous trees. In addition, a sound base is offered to select the most suited methods for the different disciplines that need this type of data. [ABSTRACT FROM AUTHOR]

Published

2019