Your search keyword '"KUEPPERS, LARA M."' showing total 42 results

1. Linking soil phosphorus with forest litterfall resistance and resilience to cyclone disturbance: A pantropical meta-analysis.

Author

Bomfim, Barbara, Bomfim, Barbara, Walker, Anthony P, McDowell, William H, Zimmerman, Jess K, Feng, Yanlei, Kueppers, Lara M, Bomfim, Barbara, Bomfim, Barbara, Walker, Anthony P, McDowell, William H, Zimmerman, Jess K, Feng, Yanlei, and Kueppers, Lara M

Abstract

While tropical cyclone regimes are shifting with climate change, the mechanisms underpinning the resistance (ability to withstand disturbance-induced change) and resilience (capacity to return to pre-disturbance reference) of tropical forest litterfall to cyclones remain largely unexplored pantropically. Single-site studies in Australia and Hawaii suggest that litterfall on low-phosphorus (P) soils is more resistant and less resilient to cyclones. We conducted a meta-analysis to investigate the pantropical importance of total soil P in mediating forest litterfall resistance and resilience to 22 tropical cyclones. We evaluated cyclone-induced and post-cyclone litterfall mass (g/m2 /day), and P and nitrogen (N) fluxes (mg/m2 /day) and concentrations (mg/g), all indicators of ecosystem function and essential for nutrient cycling. Across 73 case studies in Australia, Guadeloupe, Hawaii, Mexico, Puerto Rico, and Taiwan, total litterfall mass flux increased from ~2.5 ± 0.3 to 22.5 ± 3 g/m2 /day due to cyclones, with large variation among studies. Litterfall P and N fluxes post-cyclone represented ~5% and 10% of the average annual fluxes, respectively. Post-cyclone leaf litterfall N and P concentrations were 21.6 ± 1.2% and 58.6 ± 2.3% higher than pre-cyclone means. Mixed-effects models determined that soil P negatively moderated the pantropical litterfall resistance to cyclones, with a 100 mg P/kg increase in soil P corresponding to a 32% to 38% decrease in resistance. Based on 33% of the resistance case studies, total litterfall mass flux reached pre-disturbance levels within one-year post-disturbance. A GAMM indicated that soil P, gale wind duration and time post-cyclone jointly moderate the short-term resilience of total litterfall, with the nature of the relationship between resilience and soil P contingent on time and wind duration. Across pantropical forests observed to date, our results indicate that litterfall resistance and resilience in the face of intensifying

Published

2022

2. Linking soil phosphorus with forest litterfall resistance and resilience to cyclone disturbance: A pantropical meta-analysis.

Author

Bomfim, Barbara, Bomfim, Barbara, Walker, Anthony P, McDowell, William H, Zimmerman, Jess K, Feng, Yanlei, Kueppers, Lara M, Bomfim, Barbara, Bomfim, Barbara, Walker, Anthony P, McDowell, William H, Zimmerman, Jess K, Feng, Yanlei, and Kueppers, Lara M

Abstract

While tropical cyclone regimes are shifting with climate change, the mechanisms underpinning the resistance (ability to withstand disturbance-induced change) and resilience (capacity to return to pre-disturbance reference) of tropical forest litterfall to cyclones remain largely unexplored pantropically. Single-site studies in Australia and Hawaii suggest that litterfall on low-phosphorus (P) soils is more resistant and less resilient to cyclones. We conducted a meta-analysis to investigate the pantropical importance of total soil P in mediating forest litterfall resistance and resilience to 22 tropical cyclones. We evaluated cyclone-induced and post-cyclone litterfall mass (g/m2 /day), and P and nitrogen (N) fluxes (mg/m2 /day) and concentrations (mg/g), all indicators of ecosystem function and essential for nutrient cycling. Across 73 case studies in Australia, Guadeloupe, Hawaii, Mexico, Puerto Rico, and Taiwan, total litterfall mass flux increased from ~2.5 ± 0.3 to 22.5 ± 3 g/m2 /day due to cyclones, with large variation among studies. Litterfall P and N fluxes post-cyclone represented ~5% and 10% of the average annual fluxes, respectively. Post-cyclone leaf litterfall N and P concentrations were 21.6 ± 1.2% and 58.6 ± 2.3% higher than pre-cyclone means. Mixed-effects models determined that soil P negatively moderated the pantropical litterfall resistance to cyclones, with a 100 mg P/kg increase in soil P corresponding to a 32% to 38% decrease in resistance. Based on 33% of the resistance case studies, total litterfall mass flux reached pre-disturbance levels within one-year post-disturbance. A GAMM indicated that soil P, gale wind duration and time post-cyclone jointly moderate the short-term resilience of total litterfall, with the nature of the relationship between resilience and soil P contingent on time and wind duration. Across pantropical forests observed to date, our results indicate that litterfall resistance and resilience in the face of intensifying

Published

2022

3. Simulating environmentally-sensitive tree recruitment in vegetation demographic models.

Author

Hanbury-Brown, Adam R, Hanbury-Brown, Adam R, Powell, Thomas L, Muller-Landau, Helene C, Wright, S Joseph, Kueppers, Lara M, Hanbury-Brown, Adam R, Hanbury-Brown, Adam R, Powell, Thomas L, Muller-Landau, Helene C, Wright, S Joseph, and Kueppers, Lara M

Abstract

Vegetation demographic models (VDMs) endeavor to predict how global forests will respond to climate change. This requires simulating which trees, if any, are able to recruit under changing environmental conditions. We present a new recruitment scheme for VDMs in which functional-type-specific recruitment rates are sensitive to light, soil moisture and the productivity of reproductive trees. We evaluate the scheme by predicting tree recruitment for four tropical tree functional types under varying meteorology and canopy structure at Barro Colorado Island, Panama. We compare predictions to those of a current VDM, quantitative observations and ecological expectations. We find that the scheme improves the magnitude and rank order of recruitment rates among functional types and captures recruitment limitations in response to variable understory light, soil moisture and precipitation regimes. Our results indicate that adopting this framework will improve VDM capacity to predict functional-type-specific tree recruitment in response to climate change, thereby improving predictions of future forest distribution, composition and function.

Published

2022

4. Forest regeneration within Earth system models: current process representations and ways forward.

Author

Hanbury-Brown, Adam R, Hanbury-Brown, Adam R, Ward, Rachel E, Kueppers, Lara M, Hanbury-Brown, Adam R, Hanbury-Brown, Adam R, Ward, Rachel E, and Kueppers, Lara M

Abstract

Earth system models must predict forest responses to global change in order to simulate future global climate, hydrology, and ecosystem dynamics. These models are increasingly adopting vegetation demographic approaches that explicitly represent tree growth, mortality, and recruitment, enabling advances in the projection of forest vulnerability and resilience, as well as evaluation with field data. To date, simulation of regeneration processes has received far less attention than simulation of processes that affect growth and mortality, in spite of their critical role maintaining forest structure, facilitating turnover in forest composition over space and time, enabling recovery from disturbance, and regulating climate-driven range shifts. Our critical review of regeneration process representations within current Earth system vegetation demographic models reveals the need to improve parameter values and algorithms for reproductive allocation, dispersal, seed survival and germination, environmental filtering in the seedling layer, and tree regeneration strategies adapted to wind, fire, and anthropogenic disturbance regimes. These improvements require synthesis of existing data, specific field data-collection protocols, and novel model algorithms compatible with global-scale simulations. Vegetation demographic models offer the opportunity to more fully integrate ecological understanding into Earth system prediction; regeneration processes need to be a critical part of the effort.

Published

2022

5. Hydraulically-vulnerable trees survive on deep-water access during droughts in a tropical forest.

Author

Chitra-Tarak, Rutuja, Chitra-Tarak, Rutuja, Xu, Chonggang, Aguilar, Salomón, Anderson-Teixeira, Kristina J, Chambers, Jeff, Detto, Matteo, Faybishenko, Boris, Fisher, Rosie A, Knox, Ryan G, Koven, Charles D, Kueppers, Lara M, Kunert, Nobert, Kupers, Stefan J, McDowell, Nate G, Newman, Brent D, Paton, Steven R, Pérez, Rolando, Ruiz, Laurent, Sack, Lawren, Warren, Jeffrey M, Wolfe, Brett T, Wright, Cynthia, Wright, S Joseph, Zailaa, Joseph, McMahon, Sean M, Chitra-Tarak, Rutuja, Chitra-Tarak, Rutuja, Xu, Chonggang, Aguilar, Salomón, Anderson-Teixeira, Kristina J, Chambers, Jeff, Detto, Matteo, Faybishenko, Boris, Fisher, Rosie A, Knox, Ryan G, Koven, Charles D, Kueppers, Lara M, Kunert, Nobert, Kupers, Stefan J, McDowell, Nate G, Newman, Brent D, Paton, Steven R, Pérez, Rolando, Ruiz, Laurent, Sack, Lawren, Warren, Jeffrey M, Wolfe, Brett T, Wright, Cynthia, Wright, S Joseph, Zailaa, Joseph, and McMahon, Sean M

Abstract

Deep-water access is arguably the most effective, but under-studied, mechanism that plants employ to survive during drought. Vulnerability to embolism and hydraulic safety margins can predict mortality risk at given levels of dehydration, but deep-water access may delay plant dehydration. Here, we tested the role of deep-water access in enabling survival within a diverse tropical forest community in Panama using a novel data-model approach. We inversely estimated the effective rooting depth (ERD, as the average depth of water extraction), for 29 canopy species by linking diameter growth dynamics (1990-2015) to vapor pressure deficit, water potentials in the whole-soil column, and leaf hydraulic vulnerability curves. We validated ERD estimates against existing isotopic data of potential water-access depths. Across species, deeper ERD was associated with higher maximum stem hydraulic conductivity, greater vulnerability to xylem embolism, narrower safety margins, and lower mortality rates during extreme droughts over 35 years (1981-2015) among evergreen species. Species exposure to water stress declined with deeper ERD indicating that trees compensate for water stress-related mortality risk through deep-water access. The role of deep-water access in mitigating mortality of hydraulically-vulnerable trees has important implications for our predictive understanding of forest dynamics under current and future climates.

Published

2021

6. Hydraulically-vulnerable trees survive on deep-water access during droughts in a tropical forest.

Author

Chitra-Tarak, Rutuja, Chitra-Tarak, Rutuja, Xu, Chonggang, Aguilar, Salomón, Anderson-Teixeira, Kristina J, Chambers, Jeff, Detto, Matteo, Faybishenko, Boris, Fisher, Rosie A, Knox, Ryan G, Koven, Charles D, Kueppers, Lara M, Kunert, Nobert, Kupers, Stefan J, McDowell, Nate G, Newman, Brent D, Paton, Steven R, Pérez, Rolando, Ruiz, Laurent, Sack, Lawren, Warren, Jeffrey M, Wolfe, Brett T, Wright, Cynthia, Wright, S Joseph, Zailaa, Joseph, McMahon, Sean M, Chitra-Tarak, Rutuja, Chitra-Tarak, Rutuja, Xu, Chonggang, Aguilar, Salomón, Anderson-Teixeira, Kristina J, Chambers, Jeff, Detto, Matteo, Faybishenko, Boris, Fisher, Rosie A, Knox, Ryan G, Koven, Charles D, Kueppers, Lara M, Kunert, Nobert, Kupers, Stefan J, McDowell, Nate G, Newman, Brent D, Paton, Steven R, Pérez, Rolando, Ruiz, Laurent, Sack, Lawren, Warren, Jeffrey M, Wolfe, Brett T, Wright, Cynthia, Wright, S Joseph, Zailaa, Joseph, and McMahon, Sean M

Abstract

Deep-water access is arguably the most effective, but under-studied, mechanism that plants employ to survive during drought. Vulnerability to embolism and hydraulic safety margins can predict mortality risk at given levels of dehydration, but deep-water access may delay plant dehydration. Here, we tested the role of deep-water access in enabling survival within a diverse tropical forest community in Panama using a novel data-model approach. We inversely estimated the effective rooting depth (ERD, as the average depth of water extraction), for 29 canopy species by linking diameter growth dynamics (1990-2015) to vapor pressure deficit, water potentials in the whole-soil column, and leaf hydraulic vulnerability curves. We validated ERD estimates against existing isotopic data of potential water-access depths. Across species, deeper ERD was associated with higher maximum stem hydraulic conductivity, greater vulnerability to xylem embolism, narrower safety margins, and lower mortality rates during extreme droughts over 35 years (1981-2015) among evergreen species. Species exposure to water stress declined with deeper ERD indicating that trees compensate for water stress-related mortality risk through deep-water access. The role of deep-water access in mitigating mortality of hydraulically-vulnerable trees has important implications for our predictive understanding of forest dynamics under current and future climates.

Published

2021

7. Hydraulically-vulnerable trees survive on deep-water access during droughts in a tropical forest.

Author

Chitra-Tarak, Rutuja, Chitra-Tarak, Rutuja, Xu, Chonggang, Aguilar, Salomón, Anderson-Teixeira, Kristina J, Chambers, Jeff, Detto, Matteo, Faybishenko, Boris, Fisher, Rosie A, Knox, Ryan G, Koven, Charles D, Kueppers, Lara M, Kunert, Nobert, Kupers, Stefan J, McDowell, Nate G, Newman, Brent D, Paton, Steven R, Pérez, Rolando, Ruiz, Laurent, Sack, Lawren, Warren, Jeffrey M, Wolfe, Brett T, Wright, Cynthia, Wright, S Joseph, Zailaa, Joseph, McMahon, Sean M, Chitra-Tarak, Rutuja, Chitra-Tarak, Rutuja, Xu, Chonggang, Aguilar, Salomón, Anderson-Teixeira, Kristina J, Chambers, Jeff, Detto, Matteo, Faybishenko, Boris, Fisher, Rosie A, Knox, Ryan G, Koven, Charles D, Kueppers, Lara M, Kunert, Nobert, Kupers, Stefan J, McDowell, Nate G, Newman, Brent D, Paton, Steven R, Pérez, Rolando, Ruiz, Laurent, Sack, Lawren, Warren, Jeffrey M, Wolfe, Brett T, Wright, Cynthia, Wright, S Joseph, Zailaa, Joseph, and McMahon, Sean M

Abstract

Deep-water access is arguably the most effective, but under-studied, mechanism that plants employ to survive during drought. Vulnerability to embolism and hydraulic safety margins can predict mortality risk at given levels of dehydration, but deep-water access may delay plant dehydration. Here, we tested the role of deep-water access in enabling survival within a diverse tropical forest community in Panama using a novel data-model approach. We inversely estimated the effective rooting depth (ERD, as the average depth of water extraction), for 29 canopy species by linking diameter growth dynamics (1990-2015) to vapor pressure deficit, water potentials in the whole-soil column, and leaf hydraulic vulnerability curves. We validated ERD estimates against existing isotopic data of potential water-access depths. Across species, deeper ERD was associated with higher maximum stem hydraulic conductivity, greater vulnerability to xylem embolism, narrower safety margins, and lower mortality rates during extreme droughts over 35 years (1981-2015) among evergreen species. Species exposure to water stress declined with deeper ERD indicating that trees compensate for water stress-related mortality risk through deep-water access. The role of deep-water access in mitigating mortality of hydraulically-vulnerable trees has important implications for our predictive understanding of forest dynamics under current and future climates.

Published

2021

8. Warming and provenance limit tree recruitment across and beyond the elevation range of subalpine forest.

Author

Kueppers, Lara M, Kueppers, Lara M, Conlisk, Erin, Castanha, Cristina, Moyes, Andrew B, Germino, Matthew J, de Valpine, Perry, Torn, Margaret S, Mitton, Jeffry B, Kueppers, Lara M, Kueppers, Lara M, Conlisk, Erin, Castanha, Cristina, Moyes, Andrew B, Germino, Matthew J, de Valpine, Perry, Torn, Margaret S, and Mitton, Jeffry B

Abstract

Climate niche models project that subalpine forest ranges will extend upslope with climate warming. These projections assume that the climate suitable for adult trees will be adequate for forest regeneration, ignoring climate requirements for seedling recruitment, a potential demographic bottleneck. Moreover, local genetic adaptation is expected to facilitate range expansion, with tree populations at the upper forest edge providing the seed best adapted to the alpine. Here, we test these expectations using a novel combination of common gardens, seeded with two widely distributed subalpine conifers, and climate manipulations replicated at three elevations. Infrared heaters raised temperatures in heated plots, but raised temperatures more in the forest than at or above treeline because strong winds at high elevation reduced heating efficiency. Watering increased season-average soil moisture similarly across sites. Contrary to expectations, warming reduced Engelmann spruce recruitment at and above treeline, as well as in the forest. Warming reduced limber pine first-year recruitment in the forest, but had no net effect on fourth-year recruitment at any site. Watering during the snow-free season alleviated some negative effects of warming, indicating that warming exacerbated water limitations. Contrary to expectations of local adaptation, low-elevation seeds of both species initially recruited more strongly than high-elevation seeds across the elevation gradient, although the low-provenance advantage diminished by the fourth year for Engelmann spruce, likely due to small sample sizes. High- and low-elevation provenances responded similarly to warming across sites for Engelmann spruce, but differently for limber pine. In the context of increasing tree mortality, lower recruitment at all elevations with warming, combined with lower quality, high-provenance seed being most available for colonizing the alpine, portends range contraction for Engelmann spruce. The lower sensi

Published

2017

9. Warming and provenance limit tree recruitment across and beyond the elevation range of subalpine forest.

Author

Kueppers, Lara M, Kueppers, Lara M, Conlisk, Erin, Castanha, Cristina, Moyes, Andrew B, Germino, Matthew J, de Valpine, Perry, Torn, Margaret S, Mitton, Jeffry B, Kueppers, Lara M, Kueppers, Lara M, Conlisk, Erin, Castanha, Cristina, Moyes, Andrew B, Germino, Matthew J, de Valpine, Perry, Torn, Margaret S, and Mitton, Jeffry B

Abstract

Climate niche models project that subalpine forest ranges will extend upslope with climate warming. These projections assume that the climate suitable for adult trees will be adequate for forest regeneration, ignoring climate requirements for seedling recruitment, a potential demographic bottleneck. Moreover, local genetic adaptation is expected to facilitate range expansion, with tree populations at the upper forest edge providing the seed best adapted to the alpine. Here, we test these expectations using a novel combination of common gardens, seeded with two widely distributed subalpine conifers, and climate manipulations replicated at three elevations. Infrared heaters raised temperatures in heated plots, but raised temperatures more in the forest than at or above treeline because strong winds at high elevation reduced heating efficiency. Watering increased season-average soil moisture similarly across sites. Contrary to expectations, warming reduced Engelmann spruce recruitment at and above treeline, as well as in the forest. Warming reduced limber pine first-year recruitment in the forest, but had no net effect on fourth-year recruitment at any site. Watering during the snow-free season alleviated some negative effects of warming, indicating that warming exacerbated water limitations. Contrary to expectations of local adaptation, low-elevation seeds of both species initially recruited more strongly than high-elevation seeds across the elevation gradient, although the low-provenance advantage diminished by the fourth year for Engelmann spruce, likely due to small sample sizes. High- and low-elevation provenances responded similarly to warming across sites for Engelmann spruce, but differently for limber pine. In the context of increasing tree mortality, lower recruitment at all elevations with warming, combined with lower quality, high-provenance seed being most available for colonizing the alpine, portends range contraction for Engelmann spruce. The lower sensi

Published

2017

10. A meta-analysis of 1,119 manipulative experiments on terrestrial carbon-cycling responses to global change

Author

Song, Jian, Wan, Shiqiang, Piao, Shilong, Knapp, Alan K., Classen, Aimee T., Vicca, Sara, Ciais, Philippe, Hovenden, Mark J., Leuzinger, Sebastian, Beier, Claus, Kardol, Paul, Xia, Jianyang, Liu, Qiang, Ru, Jingyi, Zhou, Zhenxing, Luo, Yiqi, Guo, Dali, Langley, J. Adam, Zscheischler, Jakob, Dukes, Jeffrey S., Tang, Jianwu, Chen, Jiquan, Hofmockel, Kirsten S., Kueppers, Lara M., Rustad, Lindsey E., Liu, Lingli, Smith, Melinda D., Templer, Pamela H., Thomas, R. Quinn, Norby, Richard J., Phillips, Richard P., Niu, Shuli, Fatichi, Simone, Wang, Yingping, Shao, Pengshuai, Han, Hongyan, Wang, Dandan, Lei, Lingjie, Wang, Jiali, Li, Xiaona, Zhang, Qian, Li, Xiaoming, Su, Fanglong, Liu, Bin, Yang, Fan, Ma, Gaigai, Li, Guoyong, Liu, Yanchun, Liu, Yinzhan, Yang, Zhongling, Zhang, Kesheng, Miao, Yuan, Hu, Mengjun, Yan, Chuang, Zhang, Ang, Zhong, Mingxing, Hui, Yan, Li, Ying, Zheng, Mengmei, Song, Jian, Wan, Shiqiang, Piao, Shilong, Knapp, Alan K., Classen, Aimee T., Vicca, Sara, Ciais, Philippe, Hovenden, Mark J., Leuzinger, Sebastian, Beier, Claus, Kardol, Paul, Xia, Jianyang, Liu, Qiang, Ru, Jingyi, Zhou, Zhenxing, Luo, Yiqi, Guo, Dali, Langley, J. Adam, Zscheischler, Jakob, Dukes, Jeffrey S., Tang, Jianwu, Chen, Jiquan, Hofmockel, Kirsten S., Kueppers, Lara M., Rustad, Lindsey E., Liu, Lingli, Smith, Melinda D., Templer, Pamela H., Thomas, R. Quinn, Norby, Richard J., Phillips, Richard P., Niu, Shuli, Fatichi, Simone, Wang, Yingping, Shao, Pengshuai, Han, Hongyan, Wang, Dandan, Lei, Lingjie, Wang, Jiali, Li, Xiaona, Zhang, Qian, Li, Xiaoming, Su, Fanglong, Liu, Bin, Yang, Fan, Ma, Gaigai, Li, Guoyong, Liu, Yanchun, Liu, Yinzhan, Yang, Zhongling, Zhang, Kesheng, Miao, Yuan, Hu, Mengjun, Yan, Chuang, Zhang, Ang, Zhong, Mingxing, Hui, Yan, Li, Ying, and Zheng, Mengmei

Abstract

Direct quantification of terrestrial biosphere responses to global change is crucial for projections of future climate change in Earth system models. Here, we synthesized ecosystem carbon-cycling data from 1,119 experiments performed over the past four decades concerning changes in temperature, precipitation, CO2 and nitrogen across major terrestrial vegetation types of the world. Most experiments manipulated single rather than multiple global change drivers in temperate ecosystems of the USA, Europe and China. The magnitudes of warming and elevated CO2 treatments were consistent with the ranges of future projections, whereas those of precipitation changes and nitrogen inputs often exceeded the projected ranges. Increases in global change drivers consistently accelerated, but decreased precipitation slowed down carbon-cycle processes. Nonlinear (including synergistic and antagonistic) effects among global change drivers were rare. Belowground carbon allocation responded negatively to increased precipitation and nitrogen addition and positively to decreased precipitation and elevated CO2. The sensitivities of carbon variables to multiple global change drivers depended on the background climate and ecosystem condition, suggesting that Earth system models should be evaluated using site-specific conditions for best uses of this large dataset. Together, this synthesis underscores an urgent need to explore the interactions among multiple global change drivers in under-represented regions such as semi-arid ecosystems, forests in the tropics and subtropics, and Arctic tundra when forecasting future terrestrial carbon-climate feedback.

Published

2019

11. A meta-analysis of 1,119 manipulative experiments on terrestrial carbon-cycling responses to global change

Author

Forest Resources and Environmental Conservation, Song, Jian, Wan, Shiqiang, Piao, Shilong, Knapp, Alan K., Classen, Aimee T., Vicca, Sara, Ciais, Philippe, Hovenden, Mark J., Leuzinger, Sebastian, Beier, Claus, Kardol, Paul, Xia, Jianyang, Liu, Qiang, Ru, Jingyi, Zhou, Zhenxing, Luo, Yiqi, Guo, Dali, Langley, J. Adam, Zscheischler, Jakob, Dukes, Jeffrey S., Tang, Jianwu, Chen, Jiquan, Hofmockel, Kirsten S., Kueppers, Lara M., Rustad, Lindsey E., Liu, Lingli, Smith, Melinda D., Templer, Pamela H., Thomas, R. Quinn, Norby, Richard J., Phillips, Richard P., Niu, Shuli, Fatichi, Simone, Wang, Yingping, Shao, Pengshuai, Han, Hongyan, Wang, Dandan, Lei, Lingjie, Wang, Jiali, Li, Xiaona, Zhang, Qian, Li, Xiaoming, Su, Fanglong, Liu, Bin, Yang, Fan, Ma, Gaigai, Li, Guoyong, Liu, Yanchun, Liu, Yinzhan, Yang, Zhongling, Zhang, Kesheng, Miao, Yuan, Hu, Mengjun, Yan, Chuang, Zhang, Ang, Zhong, Mingxing, Hui, Yan, Li, Ying, Zheng, Mengmei, Forest Resources and Environmental Conservation, Song, Jian, Wan, Shiqiang, Piao, Shilong, Knapp, Alan K., Classen, Aimee T., Vicca, Sara, Ciais, Philippe, Hovenden, Mark J., Leuzinger, Sebastian, Beier, Claus, Kardol, Paul, Xia, Jianyang, Liu, Qiang, Ru, Jingyi, Zhou, Zhenxing, Luo, Yiqi, Guo, Dali, Langley, J. Adam, Zscheischler, Jakob, Dukes, Jeffrey S., Tang, Jianwu, Chen, Jiquan, Hofmockel, Kirsten S., Kueppers, Lara M., Rustad, Lindsey E., Liu, Lingli, Smith, Melinda D., Templer, Pamela H., Thomas, R. Quinn, Norby, Richard J., Phillips, Richard P., Niu, Shuli, Fatichi, Simone, Wang, Yingping, Shao, Pengshuai, Han, Hongyan, Wang, Dandan, Lei, Lingjie, Wang, Jiali, Li, Xiaona, Zhang, Qian, Li, Xiaoming, Su, Fanglong, Liu, Bin, Yang, Fan, Ma, Gaigai, Li, Guoyong, Liu, Yanchun, Liu, Yinzhan, Yang, Zhongling, Zhang, Kesheng, Miao, Yuan, Hu, Mengjun, Yan, Chuang, Zhang, Ang, Zhong, Mingxing, Hui, Yan, Li, Ying, and Zheng, Mengmei

Abstract

Direct quantification of terrestrial biosphere responses to global change is crucial for projections of future climate change in Earth system models. Here, we synthesized ecosystem carbon-cycling data from 1,119 experiments performed over the past four decades concerning changes in temperature, precipitation, CO2 and nitrogen across major terrestrial vegetation types of the world. Most experiments manipulated single rather than multiple global change drivers in temperate ecosystems of the USA, Europe and China. The magnitudes of warming and elevated CO2 treatments were consistent with the ranges of future projections, whereas those of precipitation changes and nitrogen inputs often exceeded the projected ranges. Increases in global change drivers consistently accelerated, but decreased precipitation slowed down carbon-cycle processes. Nonlinear (including synergistic and antagonistic) effects among global change drivers were rare. Belowground carbon allocation responded negatively to increased precipitation and nitrogen addition and positively to decreased precipitation and elevated CO2. The sensitivities of carbon variables to multiple global change drivers depended on the background climate and ecosystem condition, suggesting that Earth system models should be evaluated using site-specific conditions for best uses of this large dataset. Together, this synthesis underscores an urgent need to explore the interactions among multiple global change drivers in under-represented regions such as semi-arid ecosystems, forests in the tropics and subtropics, and Arctic tundra when forecasting future terrestrial carbon-climate feedback.

Published

2019

12. A meta-analysis of 1,119 manipulative experiments on terrestrial carbon-cycling responses to global change

Author

Song, Jian, Wan, Shiqiang, Piao, Shilong, Knapp, Alan K., Classen, Aimee T., Vicca, Sara, Ciais, Philippe, Hovenden, Mark J., Leuzinger, Sebastian, Beier, Claus, Kardol, Paul, Xia, Jianyang, Liu, Qiang, Ru, Jingyi, Zhou, Zhenxing, Luo, Yiqi, Guo, Dali, Langley, J. Adam, Zscheischler, Jakob, Dukes, Jeffrey S., Tang, Jianwu, Chen, Jiquan, Hofmockel, Kirsten S., Kueppers, Lara M., Rustad, Lindsey, Liu, Lingli, Smith, Melinda D., Templer, Pamela H., Thomas, R. Quinn, Norby, Richard J., Phillips, Richard P., Niu, Shuli, Fatichi, Simone, Wang, Yingping, Shao, Pengshuai, Han, Hongyan, Wang, Dandan, Lei, Lingjie, Wang, Jiali, Li, Xiaona, Zhang, Qian, Li, Xiaoming, Su, Fanglong, Liu, Bin, Yang, Fan, Ma, Gaigai, Li, Guoyong, Liu, Yanchun, Liu, Yinzhan, Yang, Zhongling, Zhang, Kesheng, Miao, Yuan, Hu, Mengjun, Yan, Chuang, Zhang, Ang, Zhong, Mingxing, Hui, Yan, Li, Ying, Zheng, Mengmei, Song, Jian, Wan, Shiqiang, Piao, Shilong, Knapp, Alan K., Classen, Aimee T., Vicca, Sara, Ciais, Philippe, Hovenden, Mark J., Leuzinger, Sebastian, Beier, Claus, Kardol, Paul, Xia, Jianyang, Liu, Qiang, Ru, Jingyi, Zhou, Zhenxing, Luo, Yiqi, Guo, Dali, Langley, J. Adam, Zscheischler, Jakob, Dukes, Jeffrey S., Tang, Jianwu, Chen, Jiquan, Hofmockel, Kirsten S., Kueppers, Lara M., Rustad, Lindsey, Liu, Lingli, Smith, Melinda D., Templer, Pamela H., Thomas, R. Quinn, Norby, Richard J., Phillips, Richard P., Niu, Shuli, Fatichi, Simone, Wang, Yingping, Shao, Pengshuai, Han, Hongyan, Wang, Dandan, Lei, Lingjie, Wang, Jiali, Li, Xiaona, Zhang, Qian, Li, Xiaoming, Su, Fanglong, Liu, Bin, Yang, Fan, Ma, Gaigai, Li, Guoyong, Liu, Yanchun, Liu, Yinzhan, Yang, Zhongling, Zhang, Kesheng, Miao, Yuan, Hu, Mengjun, Yan, Chuang, Zhang, Ang, Zhong, Mingxing, Hui, Yan, Li, Ying, and Zheng, Mengmei

Published

2019

13. A meta-analysis of 1,119 manipulative experiments on terrestrial carbon-cycling responses to global change

Author

Song, Jian, Wan, Shiqiang, Piao, Shilong, Knapp, Alan K., Classen, Aimee T., Vicca, Sara, Ciais, Philippe, Hovenden, Mark J., Leuzinger, Sebastian, Beier, Claus, Kardol, Paul, Xia, Jianyang, Liu, Qiang, Ru, Jingyi, Zhou, Zhenxing, Luo, Yiqi, Guo, Dali, Langley, J. Adam, Zscheischler, Jakob, Dukes, Jeffrey S., Tang, Jianwu, Chen, Jiquan, Hofmockel, Kirsten S., Kueppers, Lara M., Rustad, Lindsey, Liu, Lingli, Smith, Melinda D., Templer, Pamela H., Thomas, R. Quinn, Norby, Richard J., Phillips, Richard P., Niu, Shuli, Fatichi, Simone, Wang, Yingping, Shao, Pengshuai, Han, Hongyan, Wang, Dandan, Lei, Lingjie, Wang, Jiali, Li, Xiaona, Zhang, Qian, Li, Xiaoming, Su, Fanglong, Liu, Bin, Yang, Fan, Ma, Gaigai, Li, Guoyong, Liu, Yanchun, Liu, Yinzhan, Yang, Zhongling, Zhang, Kesheng, Miao, Yuan, Hu, Mengjun, Yan, Chuang, Zhang, Ang, Zhong, Mingxing, Hui, Yan, Li, Ying, Zheng, Mengmei, Song, Jian, Wan, Shiqiang, Piao, Shilong, Knapp, Alan K., Classen, Aimee T., Vicca, Sara, Ciais, Philippe, Hovenden, Mark J., Leuzinger, Sebastian, Beier, Claus, Kardol, Paul, Xia, Jianyang, Liu, Qiang, Ru, Jingyi, Zhou, Zhenxing, Luo, Yiqi, Guo, Dali, Langley, J. Adam, Zscheischler, Jakob, Dukes, Jeffrey S., Tang, Jianwu, Chen, Jiquan, Hofmockel, Kirsten S., Kueppers, Lara M., Rustad, Lindsey, Liu, Lingli, Smith, Melinda D., Templer, Pamela H., Thomas, R. Quinn, Norby, Richard J., Phillips, Richard P., Niu, Shuli, Fatichi, Simone, Wang, Yingping, Shao, Pengshuai, Han, Hongyan, Wang, Dandan, Lei, Lingjie, Wang, Jiali, Li, Xiaona, Zhang, Qian, Li, Xiaoming, Su, Fanglong, Liu, Bin, Yang, Fan, Ma, Gaigai, Li, Guoyong, Liu, Yanchun, Liu, Yinzhan, Yang, Zhongling, Zhang, Kesheng, Miao, Yuan, Hu, Mengjun, Yan, Chuang, Zhang, Ang, Zhong, Mingxing, Hui, Yan, Li, Ying, and Zheng, Mengmei

Published

2019

14. Variation in hydroclimate sustains tropical forest biomass and promotes functional diversity.

Author

Powell, Thomas L, Powell, Thomas L, Koven, Charles D, Johnson, Daniel J, Faybishenko, Boris, Fisher, Rosie A, Knox, Ryan G, McDowell, Nate G, Condit, Richard, Hubbell, Stephen P, Wright, S Joseph, Chambers, Jeffrey Q, Kueppers, Lara M, Powell, Thomas L, Powell, Thomas L, Koven, Charles D, Johnson, Daniel J, Faybishenko, Boris, Fisher, Rosie A, Knox, Ryan G, McDowell, Nate G, Condit, Richard, Hubbell, Stephen P, Wright, S Joseph, Chambers, Jeffrey Q, and Kueppers, Lara M

Abstract

The fate of tropical forests under climate change is unclear as a result, in part, of the uncertainty in projected changes in precipitation and in the ability of vegetation models to capture the effects of drought-induced mortality on aboveground biomass (AGB). We evaluated the ability of a terrestrial biosphere model with demography and hydrodynamics (Ecosystem Demography, ED2-hydro) to simulate AGB and mortality of four tropical tree plant functional types (PFTs) that operate along light- and water-use axes. Model predictions were compared with observations of canopy trees at Barro Colorado Island (BCI), Panama. We then assessed the implications of eight hypothetical precipitation scenarios, including increased annual precipitation, reduced inter-annual variation, El Niño-related droughts and drier wet or dry seasons, on AGB and functional diversity of the model forest. When forced with observed meteorology, ED2-hydro predictions capture multiple BCI benchmarks. ED2-hydro predicts that AGB will be sustained under lower rainfall via shifts in the functional composition of the forest, except under the drier dry-season scenario. These results support the hypothesis that inter-annual variation in mean and seasonal precipitation promotes the coexistence of functionally diverse PFTs because of the relative differences in mortality rates. If the hydroclimate becomes chronically drier or wetter, functional evenness related to drought tolerance may decline.

Published

2018

15. Comparative Transcriptomics Among Four White Pine Species.

Author

Baker, Ethan AG, Baker, Ethan AG, Wegrzyn, Jill L, Sezen, Uzay U, Falk, Taylor, Maloney, Patricia E, Vogler, Detlev R, Delfino-Mix, Annette, Jensen, Camille, Mitton, Jeffry, Wright, Jessica, Knaus, Brian, Rai, Hardeep, Cronn, Richard, Gonzalez-Ibeas, Daniel, Vasquez-Gross, Hans A, Famula, Randi A, Liu, Jun-Jun, Kueppers, Lara M, Neale, David B, Baker, Ethan AG, Baker, Ethan AG, Wegrzyn, Jill L, Sezen, Uzay U, Falk, Taylor, Maloney, Patricia E, Vogler, Detlev R, Delfino-Mix, Annette, Jensen, Camille, Mitton, Jeffry, Wright, Jessica, Knaus, Brian, Rai, Hardeep, Cronn, Richard, Gonzalez-Ibeas, Daniel, Vasquez-Gross, Hans A, Famula, Randi A, Liu, Jun-Jun, Kueppers, Lara M, and Neale, David B

Abstract

Conifers are the dominant plant species throughout the high latitude boreal forests as well as some lower latitude temperate forests of North America, Europe, and Asia. As such, they play an integral economic and ecological role across much of the world. This study focused on the characterization of needle transcriptomes from four ecologically important and understudied North American white pines within the Pinus subgenus Strobus The populations of many Strobus species are challenged by native and introduced pathogens, native insects, and abiotic factors. RNA from the needles of western white pine (Pinus monticola), limber pine (Pinus flexilis), whitebark pine (Pinus albicaulis), and sugar pine (Pinus lambertiana) was sampled, Illumina short read sequenced, and de novo assembled. The assembled transcripts and their subsequent structural and functional annotations were processed through custom pipelines to contend with the challenges of non-model organism transcriptome validation. Orthologous gene family analysis of over 58,000 translated transcripts, implemented through Tribe-MCL, estimated the shared and unique gene space among the four species. This revealed 2025 conserved gene families, of which 408 were aligned to estimate levels of divergence and reveal patterns of selection. Specific candidate genes previously associated with drought tolerance and white pine blister rust resistance in conifers were investigated.

Published

2018

16. Seed origin and warming constrain lodgepole pine recruitment, slowing the pace of population range shifts.

Author

Conlisk, Erin, Conlisk, Erin, Castanha, Cristina, Germino, Matthew J, Veblen, Thomas T, Smith, Jeremy M, Moyes, Andrew B, Kueppers, Lara M, Conlisk, Erin, Conlisk, Erin, Castanha, Cristina, Germino, Matthew J, Veblen, Thomas T, Smith, Jeremy M, Moyes, Andrew B, and Kueppers, Lara M

Abstract

Understanding how climate warming will affect the demographic rates of different ecotypes is critical to predicting shifts in species distributions. Here, we present results from a common garden, climate change experiment in which we measured seedling recruitment of lodgepole pine, a widespread North American conifer that is also planted globally. Seeds from a low-elevation provenance had more than three-fold greater recruitment to their third year than seeds from a high-elevation provenance across sites within and above its native elevation range and across climate manipulations. Heating halved recruitment to the third year of both low- and high-elevation seed sources across the elevation gradient, while watering more than doubled recruitment, alleviating some of the negative effects of heating. Demographic models based on recruitment data from the climate manipulations and long-term observations of adult populations revealed that heating could effectively halt modeled upslope range expansion except when combined with watering. Simulating fire and rapid postfire forest recovery at lower elevations accelerated lodgepole pine expansion into the alpine, but did not alter final abundance rankings among climate scenarios. Regardless of climate scenario, greater recruitment of low-elevation seeds compensated for longer dispersal distances to treeline, assuming colonization was allowed to proceed over multiple centuries. Our results show that ecotypes from lower elevations within a species' range could enhance recruitment and facilitate upslope range shifts with climate change.

Published

2018

17. Snowmelt Timing Regulates Community Composition, Phenology, and Physiological Performance of Alpine Plants.

Author

Winkler, Daniel E, Winkler, Daniel E, Butz, Ramona J, Germino, Matthew J, Reinhardt, Keith, Kueppers, Lara M, Winkler, Daniel E, Winkler, Daniel E, Butz, Ramona J, Germino, Matthew J, Reinhardt, Keith, and Kueppers, Lara M

Abstract

The spatial patterning of alpine plant communities is strongly influenced by the variation in physical factors such as temperature and moisture, which are strongly affected by snow depth and snowmelt patterns. Earlier snowmelt timing and greater soil-moisture limitations may favor wide-ranging species adapted to a broader set of ecohydrological conditions than alpine-restricted species. We asked how plant community composition, phenology, plant water relations, and photosynthetic gas exchange of alpine-restricted and wide-ranging species differ in their responses to a ca. 40-day snowmelt gradient in the Colorado Rocky Mountains (Lewisia pygmaea, Sibbaldia procumbens, and Hymenoxys grandiflora were alpine-restricted and Artemisia scopulorum, Carex rupestris, and Geum rossii were wide-ranging species). As hypothesized, species richness and foliar cover increased with earlier snowmelt, due to a greater abundance of wide-ranging species present in earlier melting plots. Flowering initiation occurred earlier with earlier snowmelt for 12 out of 19 species analyzed, while flowering duration was shortened with later snowmelt for six species (all but one were wide-ranging species). We observed >50% declines in net photosynthesis from July to September as soil moisture and plant water potentials declined. Early-season stomatal conductance was higher in wide-ranging species, indicating a more competitive strategy for water acquisition when soil moisture is high. Even so, there were no associated differences in photosynthesis or transpiration, suggesting no strong differences between these groups in physiology. Our findings reveal that plant species with different ranges (alpine-restricted vs. wide-ranging) could have differential phenological and physiological responses to snowmelt timing and associated soil moisture dry-down, and that alpine-restricted species' performance is more sensitive to snowmelt. As a result, alpine-restricted species may serve as better indicator s

Published

2018

18. Variation in hydroclimate sustains tropical forest biomass and promotes functional diversity.

Author

Powell, Thomas L, Powell, Thomas L, Koven, Charles D, Johnson, Daniel J, Faybishenko, Boris, Fisher, Rosie A, Knox, Ryan G, McDowell, Nate G, Condit, Richard, Hubbell, Stephen P, Wright, S Joseph, Chambers, Jeffrey Q, Kueppers, Lara M, Powell, Thomas L, Powell, Thomas L, Koven, Charles D, Johnson, Daniel J, Faybishenko, Boris, Fisher, Rosie A, Knox, Ryan G, McDowell, Nate G, Condit, Richard, Hubbell, Stephen P, Wright, S Joseph, Chambers, Jeffrey Q, and Kueppers, Lara M

Abstract

The fate of tropical forests under climate change is unclear as a result, in part, of the uncertainty in projected changes in precipitation and in the ability of vegetation models to capture the effects of drought-induced mortality on aboveground biomass (AGB). We evaluated the ability of a terrestrial biosphere model with demography and hydrodynamics (Ecosystem Demography, ED2-hydro) to simulate AGB and mortality of four tropical tree plant functional types (PFTs) that operate along light- and water-use axes. Model predictions were compared with observations of canopy trees at Barro Colorado Island (BCI), Panama. We then assessed the implications of eight hypothetical precipitation scenarios, including increased annual precipitation, reduced inter-annual variation, El Niño-related droughts and drier wet or dry seasons, on AGB and functional diversity of the model forest. When forced with observed meteorology, ED2-hydro predictions capture multiple BCI benchmarks. ED2-hydro predicts that AGB will be sustained under lower rainfall via shifts in the functional composition of the forest, except under the drier dry-season scenario. These results support the hypothesis that inter-annual variation in mean and seasonal precipitation promotes the coexistence of functionally diverse PFTs because of the relative differences in mortality rates. If the hydroclimate becomes chronically drier or wetter, functional evenness related to drought tolerance may decline.

Published

2018

19. Snowmelt Timing Regulates Community Composition, Phenology, and Physiological Performance of Alpine Plants.

Author

Winkler, Daniel E, Winkler, Daniel E, Butz, Ramona J, Germino, Matthew J, Reinhardt, Keith, Kueppers, Lara M, Winkler, Daniel E, Winkler, Daniel E, Butz, Ramona J, Germino, Matthew J, Reinhardt, Keith, and Kueppers, Lara M

Abstract

The spatial patterning of alpine plant communities is strongly influenced by the variation in physical factors such as temperature and moisture, which are strongly affected by snow depth and snowmelt patterns. Earlier snowmelt timing and greater soil-moisture limitations may favor wide-ranging species adapted to a broader set of ecohydrological conditions than alpine-restricted species. We asked how plant community composition, phenology, plant water relations, and photosynthetic gas exchange of alpine-restricted and wide-ranging species differ in their responses to a ca. 40-day snowmelt gradient in the Colorado Rocky Mountains (Lewisia pygmaea, Sibbaldia procumbens, and Hymenoxys grandiflora were alpine-restricted and Artemisia scopulorum, Carex rupestris, and Geum rossii were wide-ranging species). As hypothesized, species richness and foliar cover increased with earlier snowmelt, due to a greater abundance of wide-ranging species present in earlier melting plots. Flowering initiation occurred earlier with earlier snowmelt for 12 out of 19 species analyzed, while flowering duration was shortened with later snowmelt for six species (all but one were wide-ranging species). We observed >50% declines in net photosynthesis from July to September as soil moisture and plant water potentials declined. Early-season stomatal conductance was higher in wide-ranging species, indicating a more competitive strategy for water acquisition when soil moisture is high. Even so, there were no associated differences in photosynthesis or transpiration, suggesting no strong differences between these groups in physiology. Our findings reveal that plant species with different ranges (alpine-restricted vs. wide-ranging) could have differential phenological and physiological responses to snowmelt timing and associated soil moisture dry-down, and that alpine-restricted species' performance is more sensitive to snowmelt. As a result, alpine-restricted species may serve as better indicator s

Published

2018

20. Seed origin and warming constrain lodgepole pine recruitment, slowing the pace of population range shifts.

Author

Conlisk, Erin, Conlisk, Erin, Castanha, Cristina, Germino, Matthew J, Veblen, Thomas T, Smith, Jeremy M, Moyes, Andrew B, Kueppers, Lara M, Conlisk, Erin, Conlisk, Erin, Castanha, Cristina, Germino, Matthew J, Veblen, Thomas T, Smith, Jeremy M, Moyes, Andrew B, and Kueppers, Lara M

Abstract

Understanding how climate warming will affect the demographic rates of different ecotypes is critical to predicting shifts in species distributions. Here, we present results from a common garden, climate change experiment in which we measured seedling recruitment of lodgepole pine, a widespread North American conifer that is also planted globally. Seeds from a low-elevation provenance had more than three-fold greater recruitment to their third year than seeds from a high-elevation provenance across sites within and above its native elevation range and across climate manipulations. Heating halved recruitment to the third year of both low- and high-elevation seed sources across the elevation gradient, while watering more than doubled recruitment, alleviating some of the negative effects of heating. Demographic models based on recruitment data from the climate manipulations and long-term observations of adult populations revealed that heating could effectively halt modeled upslope range expansion except when combined with watering. Simulating fire and rapid postfire forest recovery at lower elevations accelerated lodgepole pine expansion into the alpine, but did not alter final abundance rankings among climate scenarios. Regardless of climate scenario, greater recruitment of low-elevation seeds compensated for longer dispersal distances to treeline, assuming colonization was allowed to proceed over multiple centuries. Our results show that ecotypes from lower elevations within a species' range could enhance recruitment and facilitate upslope range shifts with climate change.

Published

2018

21. Comparative Transcriptomics Among Four White Pine Species.

Author

Baker, Ethan AG, Baker, Ethan AG, Wegrzyn, Jill L, Sezen, Uzay U, Falk, Taylor, Maloney, Patricia E, Vogler, Detlev R, Delfino-Mix, Annette, Jensen, Camille, Mitton, Jeffry, Wright, Jessica, Knaus, Brian, Rai, Hardeep, Cronn, Richard, Gonzalez-Ibeas, Daniel, Vasquez-Gross, Hans A, Famula, Randi A, Liu, Jun-Jun, Kueppers, Lara M, Neale, David B, Baker, Ethan AG, Baker, Ethan AG, Wegrzyn, Jill L, Sezen, Uzay U, Falk, Taylor, Maloney, Patricia E, Vogler, Detlev R, Delfino-Mix, Annette, Jensen, Camille, Mitton, Jeffry, Wright, Jessica, Knaus, Brian, Rai, Hardeep, Cronn, Richard, Gonzalez-Ibeas, Daniel, Vasquez-Gross, Hans A, Famula, Randi A, Liu, Jun-Jun, Kueppers, Lara M, and Neale, David B

Abstract

Conifers are the dominant plant species throughout the high latitude boreal forests as well as some lower latitude temperate forests of North America, Europe, and Asia. As such, they play an integral economic and ecological role across much of the world. This study focused on the characterization of needle transcriptomes from four ecologically important and understudied North American white pines within the Pinus subgenus Strobus The populations of many Strobus species are challenged by native and introduced pathogens, native insects, and abiotic factors. RNA from the needles of western white pine (Pinus monticola), limber pine (Pinus flexilis), whitebark pine (Pinus albicaulis), and sugar pine (Pinus lambertiana) was sampled, Illumina short read sequenced, and de novo assembled. The assembled transcripts and their subsequent structural and functional annotations were processed through custom pipelines to contend with the challenges of non-model organism transcriptome validation. Orthologous gene family analysis of over 58,000 translated transcripts, implemented through Tribe-MCL, estimated the shared and unique gene space among the four species. This revealed 2025 conserved gene families, of which 408 were aligned to estimate levels of divergence and reveal patterns of selection. Specific candidate genes previously associated with drought tolerance and white pine blister rust resistance in conifers were investigated.

Published

2018

22. Novel tropical forests: response to global change.

Author

Holm, Jennifer A, Holm, Jennifer A, Kueppers, Lara M, Chambers, Jeffrey Q, Holm, Jennifer A, Holm, Jennifer A, Kueppers, Lara M, and Chambers, Jeffrey Q

Published

2017

23. A Cost of Tractability? Estimating Climate Change Impacts Using a Single Crop Market Understates Impacts on Market Conditions and Variability

Author

Thompson, Wyatt, Thompson, Wyatt, Gerlt, Scott, Campbell, J Elliott, Kueppers, Lara M, Lu, Yaqiong, Snyder, Mark A, Thompson, Wyatt, Thompson, Wyatt, Gerlt, Scott, Campbell, J Elliott, Kueppers, Lara M, Lu, Yaqiong, and Snyder, Mark A

Abstract

Scientists estimate that U.S. Corn Belt crop yields will increase or decrease, on average, and become more variable with climate change. Corn and soybean farming dominates this region, but studies typically do not assess the joint impact of new distributions of corn and soybean yields on markets. We use a structural economic model with projections of climate-driven yield changes to simulate these effects. Our findings suggest that a narrow focus on a single crop in this key growing region risks underestimating the impact on price distributions and average crop receipts, and can lead to incorrect signs on estimated impacts.

Published

2017

24. Climate and landscape drive the pace and pattern of conifer encroachment into subalpine meadows.

Author

Lubetkin, Kaitlin C, Lubetkin, Kaitlin C, Westerling, Anthony LeRoy, Kueppers, Lara M, Lubetkin, Kaitlin C, Lubetkin, Kaitlin C, Westerling, Anthony LeRoy, and Kueppers, Lara M

Abstract

Mountain meadows have high biodiversity and help regulate stream water release following the snowmelt pulse. However, many meadows are experiencing woody plant encroachment, threatening these ecosystem services. While there have been field surveys of individual meadows and remote sensing-based landscape-scale studies of encroachment, what is missing is a broad-scale, ground-based study to understand common regional drivers, especially at high elevations, where land management has often played a less direct role. With this study, we ask: What are the climate and landscape conditions conducive to woody plant encroachment at the landscape scale, and how has historical climate variation affected tree recruitment in subalpine meadows over time? We measured density of encroaching trees across 340 subalpine meadows in the central Sierra Nevada, California, USA, and used generalized additive models (GAMs) to determine the relationship between landscape-scale patterns of encroachment and meadow environmental properties. We determined ages of trees in 30 survey meadows, used observed climate and GAMs to model the relationship between timing of recruitment and climate since the early 1900s, and extrapolated recruitment patterns into the future using downscaled climate scenarios. Encroachment was high among meadows with lodgepole pine (Pinus contorta Douglas ex Loudon var. murrayana (Balf.) Engelm.) in the immediate vicinity, at lower elevations, with physical conditions favoring strong soil drying, and with maximum temperatures above or below average. Climatic conditions during the year of germination were unimportant, with tree recruitment instead depending on a 3-yr seed production period prior to germination and a 6-yr seedling establishment period following germination. Recruitment was high when the seed production period had high snowpack, and when the seedling establishment period had warm summer maximum temperatures, high summer precipitation, and high snowpack. Applyin

Published

2017

25. Novel tropical forests: response to global change.

Author

Holm, Jennifer A, Holm, Jennifer A, Kueppers, Lara M, Chambers, Jeffrey Q, Holm, Jennifer A, Holm, Jennifer A, Kueppers, Lara M, and Chambers, Jeffrey Q

Published

2017

26. A Cost of Tractability? Estimating Climate Change Impacts Using a Single Crop Market Understates Impacts on Market Conditions and Variability

Author

Thompson, Wyatt, Thompson, Wyatt, Gerlt, Scott, Campbell, J Elliott, Kueppers, Lara M, Lu, Yaqiong, Snyder, Mark A, Thompson, Wyatt, Thompson, Wyatt, Gerlt, Scott, Campbell, J Elliott, Kueppers, Lara M, Lu, Yaqiong, and Snyder, Mark A

Abstract

Scientists estimate that U.S. Corn Belt crop yields will increase or decrease, on average, and become more variable with climate change. Corn and soybean farming dominates this region, but studies typically do not assess the joint impact of new distributions of corn and soybean yields on markets. We use a structural economic model with projections of climate-driven yield changes to simulate these effects. Our findings suggest that a narrow focus on a single crop in this key growing region risks underestimating the impact on price distributions and average crop receipts, and can lead to incorrect signs on estimated impacts.

Published

2017

27. Climate and landscape drive the pace and pattern of conifer encroachment into subalpine meadows.

Author

Lubetkin, Kaitlin C, Lubetkin, Kaitlin C, Westerling, Anthony LeRoy, Kueppers, Lara M, Lubetkin, Kaitlin C, Lubetkin, Kaitlin C, Westerling, Anthony LeRoy, and Kueppers, Lara M

Abstract

Mountain meadows have high biodiversity and help regulate stream water release following the snowmelt pulse. However, many meadows are experiencing woody plant encroachment, threatening these ecosystem services. While there have been field surveys of individual meadows and remote sensing-based landscape-scale studies of encroachment, what is missing is a broad-scale, ground-based study to understand common regional drivers, especially at high elevations, where land management has often played a less direct role. With this study, we ask: What are the climate and landscape conditions conducive to woody plant encroachment at the landscape scale, and how has historical climate variation affected tree recruitment in subalpine meadows over time? We measured density of encroaching trees across 340 subalpine meadows in the central Sierra Nevada, California, USA, and used generalized additive models (GAMs) to determine the relationship between landscape-scale patterns of encroachment and meadow environmental properties. We determined ages of trees in 30 survey meadows, used observed climate and GAMs to model the relationship between timing of recruitment and climate since the early 1900s, and extrapolated recruitment patterns into the future using downscaled climate scenarios. Encroachment was high among meadows with lodgepole pine (Pinus contorta Douglas ex Loudon var. murrayana (Balf.) Engelm.) in the immediate vicinity, at lower elevations, with physical conditions favoring strong soil drying, and with maximum temperatures above or below average. Climatic conditions during the year of germination were unimportant, with tree recruitment instead depending on a 3-yr seed production period prior to germination and a 6-yr seedling establishment period following germination. Recruitment was high when the seed production period had high snowpack, and when the seedling establishment period had warm summer maximum temperatures, high summer precipitation, and high snowpack. Applyin

Published

2017

28. Soil moisture mediates alpine life form and community productivity responses to warming.

Author

Winkler, Daniel E, Winkler, Daniel E, Chapin, Kenneth J, Kueppers, Lara M, Winkler, Daniel E, Winkler, Daniel E, Chapin, Kenneth J, and Kueppers, Lara M

Abstract

Climate change is expected to alter primary production and community composition in alpine ecosystems, but the direction and magnitude of change is debated. Warmer, wetter growing seasons may increase productivity; however, in the absence of additional precipitation, increased temperatures may decrease soil moisture, thereby diminishing any positive effect of warming. Since plant species show individual responses to environmental change, responses may depend on community composition and vary across life form or functional groups. We warmed an alpine plant community at Niwot Ridge, Colorado continuously for four years to test whether warming increases or decreases productivity of life form groups and the whole community. We provided supplemental water to a subset of plots to alleviate the drying effect of warming. We measured annual above-ground productivity and soil temperature and moisture, from which we calculated soil degree days and adequate soil moisture days. Using an information-theoretic approach, we observed that positive productivity responses to warming at the community level occur only when warming is combined with supplemental watering; otherwise we observed decreased productivity. Watering also increased community productivity in the absence of warming. Forbs accounted for the majority of the productivity at the site and drove the contingent community response to warming, while cushions drove the generally positive response to watering and graminoids muted the community response. Warming advanced snowmelt and increased soil degree days, while watering increased adequate soil moisture days. Heated and watered plots had more adequate soil moisture days than heated plots. Overall, measured changes in soil temperature and moisture in response to treatments were consistent with expected productivity responses. We found that available soil moisture largely determines the responses of this forb-dominated alpine community to simulated climate warming.

Published

2016

29. Soil moisture mediates alpine life form and community productivity responses to warming.

Author

Winkler, Daniel E, Winkler, Daniel E, Chapin, Kenneth J, Kueppers, Lara M, Winkler, Daniel E, Winkler, Daniel E, Chapin, Kenneth J, and Kueppers, Lara M

Abstract

Climate change is expected to alter primary production and community composition in alpine ecosystems, but the direction and magnitude of change is debated. Warmer, wetter growing seasons may increase productivity; however, in the absence of additional precipitation, increased temperatures may decrease soil moisture, thereby diminishing any positive effect of warming. Since plant species show individual responses to environmental change, responses may depend on community composition and vary across life form or functional groups. We warmed an alpine plant community at Niwot Ridge, Colorado continuously for four years to test whether warming increases or decreases productivity of life form groups and the whole community. We provided supplemental water to a subset of plots to alleviate the drying effect of warming. We measured annual above-ground productivity and soil temperature and moisture, from which we calculated soil degree days and adequate soil moisture days. Using an information-theoretic approach, we observed that positive productivity responses to warming at the community level occur only when warming is combined with supplemental watering; otherwise we observed decreased productivity. Watering also increased community productivity in the absence of warming. Forbs accounted for the majority of the productivity at the site and drove the contingent community response to warming, while cushions drove the generally positive response to watering and graminoids muted the community response. Warming advanced snowmelt and increased soil degree days, while watering increased adequate soil moisture days. Heated and watered plots had more adequate soil moisture days than heated plots. Overall, measured changes in soil temperature and moisture in response to treatments were consistent with expected productivity responses. We found that available soil moisture largely determines the responses of this forb-dominated alpine community to simulated climate warming.

Published

2016

30. Soil moisture mediates alpine life form and community productivity responses to warming.

Author

Winkler, Daniel E, Winkler, Daniel E, Chapin, Kenneth J, Kueppers, Lara M, Winkler, Daniel E, Winkler, Daniel E, Chapin, Kenneth J, and Kueppers, Lara M

Abstract

Climate change is expected to alter primary production and community composition in alpine ecosystems, but the direction and magnitude of change is debated. Warmer, wetter growing seasons may increase productivity; however, in the absence of additional precipitation, increased temperatures may decrease soil moisture, thereby diminishing any positive effect of warming. Since plant species show individual responses to environmental change, responses may depend on community composition and vary across life form or functional groups. We warmed an alpine plant community at Niwot Ridge, Colorado continuously for four years to test whether warming increases or decreases productivity of life form groups and the whole community. We provided supplemental water to a subset of plots to alleviate the drying effect of warming. We measured annual above-ground productivity and soil temperature and moisture, from which we calculated soil degree days and adequate soil moisture days. Using an information-theoretic approach, we observed that positive productivity responses to warming at the community level occur only when warming is combined with supplemental watering; otherwise we observed decreased productivity. Watering also increased community productivity in the absence of warming. Forbs accounted for the majority of the productivity at the site and drove the contingent community response to warming, while cushions drove the generally positive response to watering and graminoids muted the community response. Warming advanced snowmelt and increased soil degree days, while watering increased adequate soil moisture days. Heated and watered plots had more adequate soil moisture days than heated plots. Overall, measured changes in soil temperature and moisture in response to treatments were consistent with expected productivity responses. We found that available soil moisture largely determines the responses of this forb-dominated alpine community to simulated climate warming.

Published

2016

31. Soil moisture mediates alpine life form and community productivity responses to warming.

Author

Winkler, Daniel E, Winkler, Daniel E, Chapin, Kenneth J, Kueppers, Lara M, Winkler, Daniel E, Winkler, Daniel E, Chapin, Kenneth J, and Kueppers, Lara M

Abstract

Climate change is expected to alter primary production and community composition in alpine ecosystems, but the direction and magnitude of change is debated. Warmer, wetter growing seasons may increase productivity; however, in the absence of additional precipitation, increased temperatures may decrease soil moisture, thereby diminishing any positive effect of warming. Since plant species show individual responses to environmental change, responses may depend on community composition and vary across life form or functional groups. We warmed an alpine plant community at Niwot Ridge, Colorado continuously for four years to test whether warming increases or decreases productivity of life form groups and the whole community. We provided supplemental water to a subset of plots to alleviate the drying effect of warming. We measured annual above-ground productivity and soil temperature and moisture, from which we calculated soil degree days and adequate soil moisture days. Using an information-theoretic approach, we observed that positive productivity responses to warming at the community level occur only when warming is combined with supplemental watering; otherwise we observed decreased productivity. Watering also increased community productivity in the absence of warming. Forbs accounted for the majority of the productivity at the site and drove the contingent community response to warming, while cushions drove the generally positive response to watering and graminoids muted the community response. Warming advanced snowmelt and increased soil degree days, while watering increased adequate soil moisture days. Heated and watered plots had more adequate soil moisture days than heated plots. Overall, measured changes in soil temperature and moisture in response to treatments were consistent with expected productivity responses. We found that available soil moisture largely determines the responses of this forb-dominated alpine community to simulated climate warming.

Published

2016

32. Back to the future: using historical climate variation to project near-term shifts in habitat suitable for coast redwood.

Author

Fernández, Miguel, Fernández, Miguel, Hamilton, Healy H, Kueppers, Lara M, Fernández, Miguel, Fernández, Miguel, Hamilton, Healy H, and Kueppers, Lara M

Abstract

Studies that model the effect of climate change on terrestrial ecosystems often use climate projections from downscaled global climate models (GCMs). These simulations are generally too coarse to capture patterns of fine-scale climate variation, such as the sharp coastal energy and moisture gradients associated with wind-driven upwelling of cold water. Coastal upwelling may limit future increases in coastal temperatures, compromising GCMs' ability to provide realistic scenarios of future climate in these coastal ecosystems. Taking advantage of naturally occurring variability in the high-resolution historic climatic record, we developed multiple fine-scale scenarios of California climate that maintain coherent relationships between regional climate and coastal upwelling. We compared these scenarios against coarse resolution GCM projections at a regional scale to evaluate their temporal equivalency. We used these historically based scenarios to estimate potential suitable habitat for coast redwood (Sequoia sempervirens D. Don) under 'normal' combinations of temperature and precipitation, and under anomalous combinations representative of potential future climates. We found that a scenario of warmer temperature with historically normal precipitation is equivalent to climate projected by GCMs for California by 2020-2030 and that under these conditions, climatically suitable habitat for coast redwood significantly contracts at the southern end of its current range. Our results suggest that historical climate data provide a high-resolution alternative to downscaled GCM outputs for near-term ecological forecasts. This method may be particularly useful in other regions where local climate is strongly influenced by ocean-atmosphere dynamics that are not represented by coarse-scale GCMs.

Published

2015

33. Linking carbon and water relations to drought-induced mortality in Pinus flexilis seedlings.

Author

Reinhardt, Keith, Reinhardt, Keith, Germino, Matthew J, Kueppers, Lara M, Domec, Jean-Christophe, Mitton, Jeffry, Reinhardt, Keith, Reinhardt, Keith, Germino, Matthew J, Kueppers, Lara M, Domec, Jean-Christophe, and Mitton, Jeffry

Abstract

Survival of tree seedlings at high elevations has been shown to be limited by thermal constraints on carbon balance, but it is unknown if carbon relations also limit seedling survival at lower elevations, where water relations may be more important. We measured and modeled carbon fluxes and water relations in first-year Pinus flexilis seedlings in garden plots just beyond the warm edge of their natural range, and compared these with dry-mass gain and survival across two summers. We hypothesized that mortality in these seedlings would be associated with declines in water relations, more so than with carbon-balance limitations. Rather than gradual declines in survivorship across growing seasons, we observed sharp, large-scale mortality episodes that occurred once volumetric soil-moisture content dropped below 10%. By this point, seedling water potentials had decreased below -5 MPa, seedling hydraulic conductivity had decreased by 90% and seedling hydraulic resistance had increased by >900%. Additionally, non-structural carbohydrates accumulated in aboveground tissues at the end of both summers, suggesting impairments in phloem-transport from needles to roots. This resulted in low carbohydrate concentrations in roots, which likely impaired root growth and water uptake at the time of critically low soil moisture. While photosynthesis and respiration on a leaf area basis remained high until critical hydraulic thresholds were exceeded, modeled seedling gross primary productivity declined steadily throughout the summers. At the time of mortality, modeled productivity was insufficient to support seedling biomass-gain rates, metabolism and secondary costs. Thus the large-scale mortality events that we observed near the end of each summer were most directly linked with acute, episodic declines in plant hydraulic function that were linked with important changes in whole-seedling carbon relations.

Published

2015

34. Moisture rivals temperature in limiting photosynthesis by trees establishing beyond their cold-edge range limit under ambient and warmed conditions.

Author

Moyes, Andrew B, Moyes, Andrew B, Germino, Matthew J, Kueppers, Lara M, Moyes, Andrew B, Moyes, Andrew B, Germino, Matthew J, and Kueppers, Lara M

Abstract

Climate change is altering plant species distributions globally, and warming is expected to promote uphill shifts in mountain trees. However, at many cold-edge range limits, such as alpine treelines in the western United States, tree establishment may be colimited by low temperature and low moisture, making recruitment patterns with warming difficult to predict. We measured response functions linking carbon (C) assimilation and temperature- and moisture-related microclimatic factors for limber pine (Pinus flexilis) seedlings growing in a heating × watering experiment within and above the alpine treeline. We then extrapolated these response functions using observed microclimate conditions to estimate the net effects of warming and associated soil drying on C assimilation across an entire growing season. Moisture and temperature limitations were each estimated to reduce potential growing season C gain from a theoretical upper limit by 15-30% (c. 50% combined). Warming above current treeline conditions provided relatively little benefit to modeled net assimilation, whereas assimilation was sensitive to either wetter or drier conditions. Summer precipitation may be at least as important as temperature in constraining C gain by establishing subalpine trees at and above current alpine treelines as seasonally dry subalpine and alpine ecosystems continue to warm.

Published

2015

35. Back to the future: using historical climate variation to project near-term shifts in habitat suitable for coast redwood.

Author

Fernández, Miguel, Fernández, Miguel, Hamilton, Healy H, Kueppers, Lara M, Fernández, Miguel, Fernández, Miguel, Hamilton, Healy H, and Kueppers, Lara M

Abstract

Studies that model the effect of climate change on terrestrial ecosystems often use climate projections from downscaled global climate models (GCMs). These simulations are generally too coarse to capture patterns of fine-scale climate variation, such as the sharp coastal energy and moisture gradients associated with wind-driven upwelling of cold water. Coastal upwelling may limit future increases in coastal temperatures, compromising GCMs' ability to provide realistic scenarios of future climate in these coastal ecosystems. Taking advantage of naturally occurring variability in the high-resolution historic climatic record, we developed multiple fine-scale scenarios of California climate that maintain coherent relationships between regional climate and coastal upwelling. We compared these scenarios against coarse resolution GCM projections at a regional scale to evaluate their temporal equivalency. We used these historically based scenarios to estimate potential suitable habitat for coast redwood (Sequoia sempervirens D. Don) under 'normal' combinations of temperature and precipitation, and under anomalous combinations representative of potential future climates. We found that a scenario of warmer temperature with historically normal precipitation is equivalent to climate projected by GCMs for California by 2020-2030 and that under these conditions, climatically suitable habitat for coast redwood significantly contracts at the southern end of its current range. Our results suggest that historical climate data provide a high-resolution alternative to downscaled GCM outputs for near-term ecological forecasts. This method may be particularly useful in other regions where local climate is strongly influenced by ocean-atmosphere dynamics that are not represented by coarse-scale GCMs.

Published

2015

36. Linking carbon and water relations to drought-induced mortality in Pinus flexilis seedlings.

Author

Reinhardt, Keith, Ryan, Michael1, Reinhardt, Keith, Germino, Matthew J, Kueppers, Lara M, Domec, Jean-Christophe, Mitton, Jeffry, Reinhardt, Keith, Ryan, Michael1, Reinhardt, Keith, Germino, Matthew J, Kueppers, Lara M, Domec, Jean-Christophe, and Mitton, Jeffry

Abstract

Survival of tree seedlings at high elevations has been shown to be limited by thermal constraints on carbon balance, but it is unknown if carbon relations also limit seedling survival at lower elevations, where water relations may be more important. We measured and modeled carbon fluxes and water relations in first-year Pinus flexilis seedlings in garden plots just beyond the warm edge of their natural range, and compared these with dry-mass gain and survival across two summers. We hypothesized that mortality in these seedlings would be associated with declines in water relations, more so than with carbon-balance limitations. Rather than gradual declines in survivorship across growing seasons, we observed sharp, large-scale mortality episodes that occurred once volumetric soil-moisture content dropped below 10%. By this point, seedling water potentials had decreased below -5 MPa, seedling hydraulic conductivity had decreased by 90% and seedling hydraulic resistance had increased by >900%. Additionally, non-structural carbohydrates accumulated in aboveground tissues at the end of both summers, suggesting impairments in phloem-transport from needles to roots. This resulted in low carbohydrate concentrations in roots, which likely impaired root growth and water uptake at the time of critically low soil moisture. While photosynthesis and respiration on a leaf area basis remained high until critical hydraulic thresholds were exceeded, modeled seedling gross primary productivity declined steadily throughout the summers. At the time of mortality, modeled productivity was insufficient to support seedling biomass-gain rates, metabolism and secondary costs. Thus the large-scale mortality events that we observed near the end of each summer were most directly linked with acute, episodic declines in plant hydraulic function that were linked with important changes in whole-seedling carbon relations.

Published

2015

37. Moisture rivals temperature in limiting photosynthesis by trees establishing beyond their cold-edge range limit under ambient and warmed conditions.

Author

Moyes, Andrew B, Moyes, Andrew B, Germino, Matthew J, Kueppers, Lara M, Moyes, Andrew B, Moyes, Andrew B, Germino, Matthew J, and Kueppers, Lara M

Abstract

Climate change is altering plant species distributions globally, and warming is expected to promote uphill shifts in mountain trees. However, at many cold-edge range limits, such as alpine treelines in the western United States, tree establishment may be colimited by low temperature and low moisture, making recruitment patterns with warming difficult to predict. We measured response functions linking carbon (C) assimilation and temperature- and moisture-related microclimatic factors for limber pine (Pinus flexilis) seedlings growing in a heating × watering experiment within and above the alpine treeline. We then extrapolated these response functions using observed microclimate conditions to estimate the net effects of warming and associated soil drying on C assimilation across an entire growing season. Moisture and temperature limitations were each estimated to reduce potential growing season C gain from a theoretical upper limit by 15-30% (c. 50% combined). Warming above current treeline conditions provided relatively little benefit to modeled net assimilation, whereas assimilation was sensitive to either wetter or drier conditions. Summer precipitation may be at least as important as temperature in constraining C gain by establishing subalpine trees at and above current alpine treelines as seasonally dry subalpine and alpine ecosystems continue to warm.

Published

2015

38. Snowpack-climate manipulation using infrared heaters in subalpine forests of the Southern Rocky Mountains, USA

Author

Meromy, Leah, Meromy, Leah, Kueppers, Lara M, Molotch, Noah P, Musselman, Keith N, Williams, Mark W, Meromy, Leah, Meromy, Leah, Kueppers, Lara M, Molotch, Noah P, Musselman, Keith N, and Williams, Mark W

Abstract

Effects of infrared heaters on snow accumulation, snowmelt, and snow–atmosphere energy exchange were examined at Niwot Ridge, Colorado (CO) and compared to a naturally warmer, but otherwise similar subalpine site in the Valles Caldera National Preserve, New Mexico (NM). Observed snow accumulation was 30% lower on average and snow melted out 16 days earlier in the heated plots compared to the controls. Soil temperature during snowmelt was 3°C greater on average and soil moisture was 4% lower on average in heated plots compared to controls. In NM, snow accumulation was 23% lower, snow melted 23 days earlier, soil temperature was 0.6°C greater, and soil moisture was 13% lower on average relative to CO controls. In order to estimate differences in energy and mass balance fluxes at the snow–atmosphere interface in control versus warmer plots, the 1-D, physically based snowmelt model, SNOWPACK, was used. Model results indicated that heaters alter radiative, turbulent and mass fluxes by amounts comparable to the differences between CO and NM fluxes. The proportion of the energy flux associated with latent heat exchange during snowmelt was 9–27% of the total energy flux in heated models and 19–22% of NM models compared to 3–7% in control models. Thus, sublimation loss to the atmosphere was greater in both experimentally and naturally warmer cases relative to the control case. We conclude that IR heaters can provide alterations to the timing and magnitude of snow accumulation and snowmelt consistent with conditions observed at a warmer analog site and with climate and hydrology model projections. Impacts of IR heating on energy partitioning and sublimation should be considered when designing manipulations of the snowpack, as reductions in snowmelt water may alter biological or ecological processes.

Published

2015

39. Coordinated approaches to quantify long-term ecosystem dynamics in response to global change

Author

LUO, YIQI, LUO, YIQI, MELILLO, JERRY, NIU, SHULI, BEIER, CLAUS, CLARK, JAMES S, CLASSEN, AIMÉE T, DAVIDSON, ERIC, DUKES, JEFFREY S, EVANS, R DAVE, FIELD, CHRISTOPHER B, CZIMCZIK, CLAUDIA I, KELLER, MICHAEL, KIMBALL, BRUCE A, KUEPPERS, LARA M, NORBY, RICHARD J, PELINI, SHANNON L, PENDALL, ELISE, RASTETTER, EDWARD, SIX, JOHAN, SMITH, MELINDA, TJOELKER, MARK G, TORN, MARGARET S, LUO, YIQI, LUO, YIQI, MELILLO, JERRY, NIU, SHULI, BEIER, CLAUS, CLARK, JAMES S, CLASSEN, AIMÉE T, DAVIDSON, ERIC, DUKES, JEFFREY S, EVANS, R DAVE, FIELD, CHRISTOPHER B, CZIMCZIK, CLAUDIA I, KELLER, MICHAEL, KIMBALL, BRUCE A, KUEPPERS, LARA M, NORBY, RICHARD J, PELINI, SHANNON L, PENDALL, ELISE, RASTETTER, EDWARD, SIX, JOHAN, SMITH, MELINDA, TJOELKER, MARK G, and TORN, MARGARET S

Abstract

Many serious ecosystem consequences of climate change will take decades or even centuries to emerge. Long-term ecological responses to global change are strongly regulated by slow processes, such as changes in species composition, carbon dynamics in soil and by long-lived plants, and accumulation of nutrient capitals. Understanding and predicting these processes require experiments on decadal time scales. But decadal experiments by themselves may not be adequate because many of the slow processes have characteristic time scales much longer than experiments can be maintained. This article promotes a coordinated approach that combines long-term, large-scale global change experiments with process studies and modeling. Long-term global change manipulative experiments, especially in high-priority ecosystems such as tropical forests and high-latitude regions, are essential to maximize information gain concerning future states of the earth system. The long-term experiments should be conducted in tandem with complementary process studies, such as those using model ecosystems, species replacements, laboratory incubations, isotope tracers, and greenhouse facilities. Models are essential to assimilate data from long-term experiments and process studies together with information from long-term observations, surveys, and space-for-time studies along environmental and biological gradients. Future research programs with coordinated long-term experiments, process studies, and modeling have the potential to be the most effective strategy to gain the best information on long-term ecosystem dynamics in response to global change.

Published

2011

40. Biophysical considerations in forestry for climate protection

Author

Anderson, Ray G, Anderson, Ray G, Canadell, Josep G, Randerson, James T, Jackson, Robert B, Hungate, Bruce A, Baldocchi, Dennis D, Ban-Weiss, George A, Bonan, Gordon B, Caldeira, Ken, Cao, Long, Diffenbaugh, Noah S, Gurney, Kevin R, Kueppers, Lara M, Law, Beverly E, Luyssaert, Sebastiaan, O'Halloran, Thomas L, Anderson, Ray G, Anderson, Ray G, Canadell, Josep G, Randerson, James T, Jackson, Robert B, Hungate, Bruce A, Baldocchi, Dennis D, Ban-Weiss, George A, Bonan, Gordon B, Caldeira, Ken, Cao, Long, Diffenbaugh, Noah S, Gurney, Kevin R, Kueppers, Lara M, Law, Beverly E, Luyssaert, Sebastiaan, and O'Halloran, Thomas L

Abstract

Forestry – including afforestation (the planting of trees on land where they have not recently existed), reforestation, avoided deforestation, and forest management – can lead to increased sequestration of atmospheric carbon dioxide and has therefore been proposed as a strategy to mitigate climate change. However, forestry also influences land-surface properties, including albedo (the fraction of incident sunlight reflected back to space), surface roughness, and evapotranspiration, all of which affect the amount and forms of energy transfer to the atmosphere. In some circumstances, these biophysical feedbacks can result in local climate warming, thereby counteracting the effects of carbon sequestration on global mean temperature and reducing or eliminating the net value of climate-change mitigation projects. Here, we review published and emerging research that suggests ways in which forestry projects can counteract the consequences associated with biophysical interactions, and highlight knowledge gaps in managing forests for climate protection. We also outline several ways in which biophysical effects can be incorporated into frameworks that use the maintenance of forests as a climate protection strategy.

Published

2011

41. Biophysical considerations in forestry for climate protection

Author

Anderson, Ray G, Anderson, Ray G, Canadell, Josep G, Randerson, James T, Jackson, Robert B, Hungate, Bruce A, Baldocchi, Dennis D, Ban-Weiss, George A, Bonan, Gordon B, Caldeira, Ken, Cao, Long, Diffenbaugh, Noah S, Gurney, Kevin R, Kueppers, Lara M, Law, Beverly E, Luyssaert, Sebastiaan, O'Halloran, Thomas L, Anderson, Ray G, Anderson, Ray G, Canadell, Josep G, Randerson, James T, Jackson, Robert B, Hungate, Bruce A, Baldocchi, Dennis D, Ban-Weiss, George A, Bonan, Gordon B, Caldeira, Ken, Cao, Long, Diffenbaugh, Noah S, Gurney, Kevin R, Kueppers, Lara M, Law, Beverly E, Luyssaert, Sebastiaan, and O'Halloran, Thomas L

Abstract

Forestry – including afforestation (the planting of trees on land where they have not recently existed), reforestation, avoided deforestation, and forest management – can lead to increased sequestration of atmospheric carbon dioxide and has therefore been proposed as a strategy to mitigate climate change. However, forestry also influences land-surface properties, including albedo (the fraction of incident sunlight reflected back to space), surface roughness, and evapotranspiration, all of which affect the amount and forms of energy transfer to the atmosphere. In some circumstances, these biophysical feedbacks can result in local climate warming, thereby counteracting the effects of carbon sequestration on global mean temperature and reducing or eliminating the net value of climate-change mitigation projects. Here, we review published and emerging research that suggests ways in which forestry projects can counteract the consequences associated with biophysical interactions, and highlight knowledge gaps in managing forests for climate protection. We also outline several ways in which biophysical effects can be incorporated into frameworks that use the maintenance of forests as a climate protection strategy.

Published

2011

42. Coordinated approaches to quantify long-term ecosystem dynamics in response to global change

Author

LUO, YIQI, LUO, YIQI, MELILLO, JERRY, NIU, SHULI, BEIER, CLAUS, CLARK, JAMES S, CLASSEN, AIMÉE T, DAVIDSON, ERIC, DUKES, JEFFREY S, EVANS, R DAVE, FIELD, CHRISTOPHER B, CZIMCZIK, CLAUDIA I, KELLER, MICHAEL, KIMBALL, BRUCE A, KUEPPERS, LARA M, NORBY, RICHARD J, PELINI, SHANNON L, PENDALL, ELISE, RASTETTER, EDWARD, SIX, JOHAN, SMITH, MELINDA, TJOELKER, MARK G, TORN, MARGARET S, LUO, YIQI, LUO, YIQI, MELILLO, JERRY, NIU, SHULI, BEIER, CLAUS, CLARK, JAMES S, CLASSEN, AIMÉE T, DAVIDSON, ERIC, DUKES, JEFFREY S, EVANS, R DAVE, FIELD, CHRISTOPHER B, CZIMCZIK, CLAUDIA I, KELLER, MICHAEL, KIMBALL, BRUCE A, KUEPPERS, LARA M, NORBY, RICHARD J, PELINI, SHANNON L, PENDALL, ELISE, RASTETTER, EDWARD, SIX, JOHAN, SMITH, MELINDA, TJOELKER, MARK G, and TORN, MARGARET S

Abstract

Many serious ecosystem consequences of climate change will take decades or even centuries to emerge. Long-term ecological responses to global change are strongly regulated by slow processes, such as changes in species composition, carbon dynamics in soil and by long-lived plants, and accumulation of nutrient capitals. Understanding and predicting these processes require experiments on decadal time scales. But decadal experiments by themselves may not be adequate because many of the slow processes have characteristic time scales much longer than experiments can be maintained. This article promotes a coordinated approach that combines long-term, large-scale global change experiments with process studies and modeling. Long-term global change manipulative experiments, especially in high-priority ecosystems such as tropical forests and high-latitude regions, are essential to maximize information gain concerning future states of the earth system. The long-term experiments should be conducted in tandem with complementary process studies, such as those using model ecosystems, species replacements, laboratory incubations, isotope tracers, and greenhouse facilities. Models are essential to assimilate data from long-term experiments and process studies together with information from long-term observations, surveys, and space-for-time studies along environmental and biological gradients. Future research programs with coordinated long-term experiments, process studies, and modeling have the potential to be the most effective strategy to gain the best information on long-term ecosystem dynamics in response to global change.

Published

2011