Your search keyword '"Maschler, Julia"' showing total 14 results

1. The effect of elevated atmospheric CO2 levels on plant carbon storage

Author

Maschler, Julia, Crowther, Tom, Hagedorn, Frank, and Reich, Peter

Subjects

Earth sciences, ddc:550

Published

2023

2. Links across ecological scales: Plant biomass responses to elevatedCO 2

Author

Maschler, Julia, primary, Bialic‐Murphy, Lalasia, additional, Wan, Joe, additional, Andresen, Louise C., additional, Zohner, Constantin M., additional, Reich, Peter B., additional, Lüscher, Andreas, additional, Schneider, Manuel K., additional, Müller, Christoph, additional, Moser, Gerald, additional, Dukes, Jeffrey S., additional, Schmidt, Inger Kappel, additional, Bilton, Mark C., additional, Zhu, Kai, additional, and Crowther, Thomas W., additional

Published

2022

3. Links across ecological scales:Plant biomass responses to elevated CO2

Author

Maschler, Julia, Bialic-Murphy, Lalasia, Wan, Joe, Andresen, Louise C., Zohner, Constantin M., Reich, Peter B., Lüscher, Andreas, Schneider, Manuel K., Müller, Christoph, Moser, Gerald, Dukes, Jeffrey S., Schmidt, Inger Kappel, Bilton, Mark C., Zhu, Kai, Crowther, Thomas W., Maschler, Julia, Bialic-Murphy, Lalasia, Wan, Joe, Andresen, Louise C., Zohner, Constantin M., Reich, Peter B., Lüscher, Andreas, Schneider, Manuel K., Müller, Christoph, Moser, Gerald, Dukes, Jeffrey S., Schmidt, Inger Kappel, Bilton, Mark C., Zhu, Kai, and Crowther, Thomas W.

Abstract

The degree to which elevated CO2 concentrations (e[CO2]) increase the amount of carbon (C) assimilated by vegetation plays a key role in climate change. However, due to the short-term nature of CO2 enrichment experiments and the lack of reconciliation between different ecological scales, the effect of e[CO2] on plant biomass stocks remains a major uncertainty in future climate projections. Here, we review the effect of e[CO2] on plant biomass across multiple levels of ecological organization, scaling from physiological responses to changes in population-, community-, ecosystem-, and global-scale dynamics. We find that evidence for a sustained biomass response to e[CO2] varies across ecological scales, leading to diverging conclusions about the responses of individuals, populations, communities, and ecosystems. While the distinct focus of every scale reveals new mechanisms driving biomass accumulation under e[CO2], none of them provides a full picture of all relevant processes. For example, while physiological evidence suggests a possible long-term basis for increased biomass accumulation under e[CO2] through sustained photosynthetic stimulation, population-scale evidence indicates that a possible e[CO2]-induced increase in mortality rates might potentially outweigh the effect of increases in plant growth rates on biomass levels. Evidence at the global scale may indicate that e[CO2] has contributed to increased biomass cover over recent decades, but due to the difficulty to disentangle the effect of e[CO2] from a variety of climatic and land-use-related drivers of plant biomass stocks, it remains unclear whether nutrient limitations or other ecological mechanisms operating at finer scales will dampen the e[CO2] effect over time. By exploring these discrepancies, we identify key research gaps in our understanding of the effect of e[CO

Published

2022

4. Carbon Source Reduction Postpones Autumn Leaf Senescence in a Widespread Deciduous Tree

Author

Maschler, Julia, primary, Keller, Jenna, additional, Bialic-Murphy, Lalasia, additional, Zohner, Constantin M., additional, and Crowther, Thomas W., additional

Published

2022

5. A reduction of the plant carbon source postpones autumn leaf senescence in birch seedlings

Author

Maschler, Julia, primary, Keller, Jenna, additional, Bialic-Murphy, Lalasia, additional, Zohner, Constantin M., additional, and Crowther, Thomas W., additional

Published

2022

6. Links across ecological scales: Plant biomass responses to elevated CO2.

Author

Maschler, Julia, Bialic‐Murphy, Lalasia, Wan, Joe, Andresen, Louise C., Zohner, Constantin M., Reich, Peter B., Lüscher, Andreas, Schneider, Manuel K., Müller, Christoph, Moser, Gerald, Dukes, Jeffrey S., Schmidt, Inger Kappel, Bilton, Mark C., Zhu, Kai, and Crowther, Thomas W.

Subjects

*COMMUNITIES, *CARBON cycle, *GEOLOGICAL carbon sequestration

Abstract

The degree to which elevated CO2 concentrations (e[CO2]) increase the amount of carbon (C) assimilated by vegetation plays a key role in climate change. However, due to the short‐term nature of CO2 enrichment experiments and the lack of reconciliation between different ecological scales, the effect of e[CO2] on plant biomass stocks remains a major uncertainty in future climate projections. Here, we review the effect of e[CO2] on plant biomass across multiple levels of ecological organization, scaling from physiological responses to changes in population‐, community‐, ecosystem‐, and global‐scale dynamics. We find that evidence for a sustained biomass response to e[CO2] varies across ecological scales, leading to diverging conclusions about the responses of individuals, populations, communities, and ecosystems. While the distinct focus of every scale reveals new mechanisms driving biomass accumulation under e[CO2], none of them provides a full picture of all relevant processes. For example, while physiological evidence suggests a possible long‐term basis for increased biomass accumulation under e[CO2] through sustained photosynthetic stimulation, population‐scale evidence indicates that a possible e[CO2]‐induced increase in mortality rates might potentially outweigh the effect of increases in plant growth rates on biomass levels. Evidence at the global scale may indicate that e[CO2] has contributed to increased biomass cover over recent decades, but due to the difficulty to disentangle the effect of e[CO2] from a variety of climatic and land‐use‐related drivers of plant biomass stocks, it remains unclear whether nutrient limitations or other ecological mechanisms operating at finer scales will dampen the e[CO2] effect over time. By exploring these discrepancies, we identify key research gaps in our understanding of the effect of e[CO2] on plant biomass and highlight the need to integrate knowledge across scales of ecological organization so that large‐scale modeling can represent the finer‐scale mechanisms needed to constrain our understanding of future terrestrial C storage. [ABSTRACT FROM AUTHOR]

Published

2022

7. Links across ecological scales: Plant biomass responses to elevated CO2.

Author

Maschler, Julia, Bialic‐Murphy, Lalasia, Wan, Joe, Andresen, Louise C., Zohner, Constantin M., Reich, Peter B., Lüscher, Andreas, Schneider, Manuel K., Müller, Christoph, Moser, Gerald, Dukes, Jeffrey S., Schmidt, Inger Kappel, Bilton, Mark C., Zhu, Kai, and Crowther, Thomas W.

Subjects

COMMUNITIES, CARBON cycle, GEOLOGICAL carbon sequestration

Abstract

The degree to which elevated CO2 concentrations (e[CO2]) increase the amount of carbon (C) assimilated by vegetation plays a key role in climate change. However, due to the short‐term nature of CO2 enrichment experiments and the lack of reconciliation between different ecological scales, the effect of e[CO2] on plant biomass stocks remains a major uncertainty in future climate projections. Here, we review the effect of e[CO2] on plant biomass across multiple levels of ecological organization, scaling from physiological responses to changes in population‐, community‐, ecosystem‐, and global‐scale dynamics. We find that evidence for a sustained biomass response to e[CO2] varies across ecological scales, leading to diverging conclusions about the responses of individuals, populations, communities, and ecosystems. While the distinct focus of every scale reveals new mechanisms driving biomass accumulation under e[CO2], none of them provides a full picture of all relevant processes. For example, while physiological evidence suggests a possible long‐term basis for increased biomass accumulation under e[CO2] through sustained photosynthetic stimulation, population‐scale evidence indicates that a possible e[CO2]‐induced increase in mortality rates might potentially outweigh the effect of increases in plant growth rates on biomass levels. Evidence at the global scale may indicate that e[CO2] has contributed to increased biomass cover over recent decades, but due to the difficulty to disentangle the effect of e[CO2] from a variety of climatic and land‐use‐related drivers of plant biomass stocks, it remains unclear whether nutrient limitations or other ecological mechanisms operating at finer scales will dampen the e[CO2] effect over time. By exploring these discrepancies, we identify key research gaps in our understanding of the effect of e[CO2] on plant biomass and highlight the need to integrate knowledge across scales of ecological organization so that large‐scale modeling can represent the finer‐scale mechanisms needed to constrain our understanding of future terrestrial C storage. [ABSTRACT FROM AUTHOR]

Published

2022

8. Global maps of current and future nitrogen mineralization

Author

Maschler, Julia, primary, Maynard, Daniel S., additional, Routh, Devin, additional, van den Hoogen, Johan, additional, Li, Zhaolei, additional, Niu, Shuli, additional, and Crowther, Thomas W., additional

Published

2020

9. Understanding climate change from a global analysis of city analogues

Author

Bastin, Jean-Francois, Clark, Emily, Elliott, Thomas, Hart, Simon, van den Hoogen, Johan, Hordijk, Iris, Ma, Haozhi, Majumder, Sabiha, Manoli, Gabriele, Maschler, Julia, Mo, Lidong, Routh, Devin, Yu, Kailiang, Zohner, Constantin M., and Crowther, Thomas W.

Subjects

Cartography, Atmospheric Science, Climate Change, Science, Research and Analysis Methods, Geographical locations, Mathematical and Statistical Techniques, Statistical Methods, Geographic Areas, Northern Hemisphere, Climatology, Principal Component Analysis, Latitude, Geography, Statistics, Europe, Earth sciences, Multivariate Analysis, Physical Sciences, People and Places, North America, Medicine, Southern Hemisphere, Mathematics, Research Article, Urban Areas

Abstract

Combating climate change requires unified action across all sectors of society. However, this collective action is precluded by the ‘consensus gap’ between scientific knowledge and public opinion. Here, we test the extent to which the iconic cities around the world are likely to shift in response to climate change. By analyzing city pairs for 520 major cities of the world, we test if their climate in 2050 will resemble more closely to their own current climate conditions or to the current conditions of other cities in different bioclimatic regions. Even under an optimistic climate scenario (RCP 4.5), we found that 77% of future cities are very likely to experience a climate that is closer to that of another existing city than to its own current climate. In addition, 22% of cities will experience climate conditions that are not currently experienced by any existing major cities. As a general trend, we found that all the cities tend to shift towards the sub-tropics, with cities from the Northern hemisphere shifting to warmer conditions, on average ~1000 km south (velocity ~20 km.year-1), and cities from the tropics shifting to drier conditions. We notably predict that Madrid’s climate in 2050 will resemble Marrakech’s climate today, Stockholm will resemble Budapest, London to Barcelona, Moscow to Sofia, Seattle to San Francisco, Tokyo to Changsha. Our approach illustrates how complex climate data can be packaged to provide tangible information. The global assessment of city analogues can facilitate the understanding of climate change at a global level but also help land managers and city planners to visualize the climate futures of their respective cities, which can facilitate effective decision-making in response to on-going climate change., PLoS ONE, 14 (7), ISSN:1932-6203

Published

2019

10. Correction: Understanding climate change from a global analysis of city analogues

Author

Bastin, Jean-Francois, primary, Clark, Emily, additional, Elliott, Thomas, additional, Hart, Simon, additional, van den Hoogen, Johan, additional, Hordijk, Iris, additional, Ma, Haozhi, additional, Majumder, Sabiha, additional, Manoli, Gabriele, additional, Maschler, Julia, additional, Mo, Lidong, additional, Routh, Devin, additional, Yu, Kailiang, additional, Zohner, Constantin M., additional, and Crowther, Thomas W., additional

Published

2019

11. Cities of the future, visualizing climate change to inspire actions

Author

Bastin, Jean-Francois, primary, Clark, Emily, additional, Elliott, Thomas, additional, Hart, Simon, additional, den Hoogen, Johan van, additional, Hordijk, Iris, additional, Ma, Haozhi, additional, Majumder, Sabiha, additional, Manoli, Gabriele, additional, Maschler, Julia, additional, Mo, Lidong, additional, Routh, Devin, additional, Yu, Kailiang, additional, Zohner, Constantin, additional, and Crowther, Thomas, W., additional

Published

2018

12. Individual Tree Crown Segmentation and Classification of 13 Tree Species Using Airborne Hyperspectral Data

Author

Maschler, Julia, primary, Atzberger, Clement, additional, and Immitzer, Markus, additional

Published

2018

13. Understanding climate change from a global analysis of city analogues

Author

Añel, Juan A., Bastin, Jean-Francois, Clark, Emily, Elliott, Thomas, Hart, Simon, van den Hoogen, Johan, Hordijk, Iris, Ma, Haozhi, Majumder, Sabiha, Manoli, Gabriele, Maschler, Julia, Mo, Lidong, Routh, Devin, Yu, Kailiang, Zohner, Constantin M., and Crowther, Thomas W.

Abstract

Combating climate change requires unified action across all sectors of society. However, this collective action is precluded by the ‘consensus gap’ between scientific knowledge and public opinion. Here, we test the extent to which the iconic cities around the world are likely to shift in response to climate change. By analyzing city pairs for 520 major cities of the world, we test if their climate in 2050 will resemble more closely to their own current climate conditions or to the current conditions of other cities in different bioclimatic regions. Even under an optimistic climate scenario (RCP 4.5), we found that 77% of future cities are very likely to experience a climate that is closer to that of another existing city than to its own current climate. In addition, 22% of cities will experience climate conditions that are not currently experienced by any existing major cities. As a general trend, we found that all the cities tend to shift towards the sub-tropics, with cities from the Northern hemisphere shifting to warmer conditions, on average ~1000 km south (velocity ~20 km.year-1), and cities from the tropics shifting to drier conditions. We notably predict that Madrid’s climate in 2050 will resemble Marrakech’s climate today, Stockholm will resemble Budapest, London to Barcelona, Moscow to Sofia, Seattle to San Francisco, Tokyo to Changsha. Our approach illustrates how complex climate data can be packaged to provide tangible information. The global assessment of city analogues can facilitate the understanding of climate change at a global level but also help land managers and city planners to visualize the climate futures of their respective cities, which can facilitate effective decision-making in response to on-going climate change.

14. Links across ecological scales: Plant biomass responses to elevated CO 2 .

Author

Maschler J, Bialic-Murphy L, Wan J, Andresen LC, Zohner CM, Reich PB, Lüscher A, Schneider MK, Müller C, Moser G, Dukes JS, Schmidt IK, Bilton MC, Zhu K, and Crowther TW

Subjects

Biomass, Carbon, Carbon Cycle, Humans, Plants, Carbon Dioxide, Ecosystem

Abstract

The degree to which elevated CO 2 concentrations (e[CO 2 ]) increase the amount of carbon (C) assimilated by vegetation plays a key role in climate change. However, due to the short-term nature of CO 2 enrichment experiments and the lack of reconciliation between different ecological scales, the effect of e[CO 2 ] on plant biomass stocks remains a major uncertainty in future climate projections. Here, we review the effect of e[CO 2 ] on plant biomass across multiple levels of ecological organization, scaling from physiological responses to changes in population-, community-, ecosystem-, and global-scale dynamics. We find that evidence for a sustained biomass response to e[CO 2 ] varies across ecological scales, leading to diverging conclusions about the responses of individuals, populations, communities, and ecosystems. While the distinct focus of every scale reveals new mechanisms driving biomass accumulation under e[CO 2 ], none of them provides a full picture of all relevant processes. For example, while physiological evidence suggests a possible long-term basis for increased biomass accumulation under e[CO 2 ] through sustained photosynthetic stimulation, population-scale evidence indicates that a possible e[CO 2 ]-induced increase in mortality rates might potentially outweigh the effect of increases in plant growth rates on biomass levels. Evidence at the global scale may indicate that e[CO 2 ] has contributed to increased biomass cover over recent decades, but due to the difficulty to disentangle the effect of e[CO 2 ] from a variety of climatic and land-use-related drivers of plant biomass stocks, it remains unclear whether nutrient limitations or other ecological mechanisms operating at finer scales will dampen the e[CO 2 ] effect over time. By exploring these discrepancies, we identify key research gaps in our understanding of the effect of e[CO 2 ] on plant biomass and highlight the need to integrate knowledge across scales of ecological organization so that large-scale modeling can represent the finer-scale mechanisms needed to constrain our understanding of future terrestrial C storage., (© 2022 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2022