Your search keyword '"Robert D. Hollister"' showing total 15 results

1. Shading decreases and delays NDVI and flowering of prostrate Arctic shrubs1

Author

Jeremy L. May, Steven F. Oberbauer, Steven L. Unger, Matthew J. Simon, Katlyn R. Betway, and Robert D. Hollister

Subjects

bearberry, lingonberry, phenology, climate change, Vaccinium vitis-idaea, Arctous alpina, Environmental sciences, GE1-350, Environmental engineering, TA170-171

Abstract

Increases in shrub growth and canopy cover are well documented community responses to climate warming in the Arctic. An important consequence of larger deciduous shrubs is shading of prostrate plant species, many of which are important sources of nectar and berries. Here, we present the impact of a shading experiment on two prostrate shrubs, Vaccinium vitis-idaea L. and Arctous alpina L., in northern Alaska over two growing seasons. We implemented three levels of shading (no shade, 40% shade, and 80% shade) in dry heath and moist acidic tundra. Plots were monitored for soil moisture content, surface temperature, normalized difference vegetation index (NDVI), and flowering. Shading was shown to, on average, lower surface temperature (0.7 °C to 5.3 °C) and increase soil moisture content (0.5% to 5.6%) in both communities. Both species- and plot-level NDVI values were delayed in timing of peak values (7 to 13 days) and decreased at the highest shading. Flower abundance of both species was lower in shaded plots and peak flowering was delayed (3 to 8 days) compared with controls. Changes in timing may result in phenological mismatches and can impact other trophic levels in the Arctic as both the flowers and resulting berries are important food sources for animals.

Published

2022

2. NDVI Changes Show Warming Increases the Length of the Green Season at Tundra Communities in Northern Alaska: A Fine-Scale Analysis

Author

Jeremy L. May, Robert D. Hollister, Katlyn R. Betway, Jacob A. Harris, Craig E. Tweedie, Jeffrey M. Welker, William A. Gould, and Steven F. Oberbauer

Subjects

Arctic shrubs, Normalized Difference Vegetation Index, climate change, seasonality, phenology, International Tundra Experiment, Plant culture, SB1-1110

Abstract

A warming Arctic has been associated with increases in aboveground plant biomass, specifically shrubs, and changes in vegetation cover. However, the magnitude and direction of changes in NDVI have not been consistent across different tundra types. Here we examine the responsiveness of fine-scale NDVI values to experimental warming at eight sites in northern Alaska, United States. Warming in our eight sites ranged in duration from 2‑23 seasons. Dry, wet and moist tundra communities were monitored for canopy surface temperatures and NDVI in ambient and experimentally-warmed plots at near-daily frequencies during the summer of 2017 to assess the impact of the warming treatment on the magnitude and timing of greening. Experimental warming increased canopy-level surface temperatures across all sites (+0.47 to +3.14˚C), with the strongest warming effect occurring during June and July and for the southernmost sites. Green-up was accelerated by warming at six sites, and autumn senescence was delayed at five sites. Warming increased the magnitude of peak NDVI values at five sites, decreased it at one site, and at two sites it did not change. Warming resulted in earlier peak NDVI at three sites and no significant change in the other sites. Shrub and graminoid cover was positively correlated with the magnitude of peak NDVI (r=0.37 to 0.60) while cryptogam influence was mixed. The magnitude and timing of peak NDVI showed considerable variability across sites. Warming extended the duration of the summer green season at most sites due to accelerated greening in the spring and delayed senescence in the autumn. We show that in a warmer Arctic (as simulated by our experiment) the timing and total period of carbon gain may change. Our results suggest these changes are dependent on community composition and abundance of specific growth forms and therefore will likely impact net primary productivity and trophic interactions.

Published

2020

3. Short-Term Impacts of the Air Temperature on Greening and Senescence in Alaskan Arctic Plant Tundra Habitats

Author

Jeremy L. May, Nathan C. Healey, Hella E. Ahrends, Robert D. Hollister, Craig E. Tweedie, Jeffrey M. Welker, William A. Gould, and Steven F. Oberbauer

Subjects

arctic shrubs, Mobile Instrumented Sensor Platform, Normalized Difference Vegetation Index, climate change, phenology, Science

Abstract

Climate change is warming the temperatures and lengthening the Arctic growing season with potentially important effects on plant phenology. The ability of plant species to acclimate to changing climatic conditions will dictate the level to which their spatial coverage and habitat-type dominance is different in the future. While the effect of changes in temperature on phenology and species composition have been observed at the plot and at the regional scale, a systematic assessment at medium spatial scales using new noninvasive sensor techniques has not been performed yet. At four sites across the North Slope of Alaska, changes in the Normalized Difference Vegetation Index (NDVI) signal were observed by Mobile Instrumented Sensor Platforms (MISP) that are suspended over 50 m transects spanning local moisture gradients. The rates of greening (measured in June) and senescence (measured in August) in response to the air temperature was estimated by changes in NDVI measured as the difference between the NDVI on a specific date and three days later. In June, graminoid- and shrub-dominated habitats showed the greatest rates of NDVI increase in response to the high air temperatures, while forb- and lichen-dominated habitats were less responsive. In August, the NDVI was more responsive to variations in the daily average temperature than spring greening at all sites. For graminoid- and shrub-dominated habitats, we observed a delayed decrease of the NDVI, reflecting a prolonged growing season, in response to high August temperatures. Consequently, the annual C assimilation capacity of these habitats is increased, which in turn may be partially responsible for shrub expansion and further increases in net summer CO2 fixation. Strong interannual differences highlight that long-term and noninvasive measurements of such complex feedback mechanisms in arctic ecosystems are critical to fully articulate the net effects of climate variability and climate change on plant community and ecosystem processes.

Published

2017

4. The tundra phenology database: More than two decades of tundra phenology responses to climate change

Author

Ingibjörg S. Jónsdóttir, Bo Elberling, Eric Post, Henrik Wahren, Sabine Rumpf, Greg H. R. Henry, Isla H. Myers-Smith, Marguerite Mauritz, Esther Lévesque, Christopher W. Kopp, Sarah C. Elmendorf, Nicoletta Cannone, Juha M. Alatalo, Elisabeth J. Cooper, Jeffery M. Welker, Esther R. Frei, Michele Carbognani, Philipp R. Semenchuk, Katherine N. Suding, Orjan Toteland, Isabel W. Ashton, Jakob J. Assmann, Chelsea Chisholm, Alessandro Petraglia, Ulf Molau, Courtney G. Collins, Jane G. Smith, Jeffrey T. Kerby, Robert G. Björk, Christian Rixen, Tiffany G. Troxler, Robert D. Hollister, Heidi Rodenhizer, Sonja Wipf, Yue Yang, S. F. Oberbauer, Niels Martin Schmidt, Susan M. Natali, Anne D. Bjorkman, Karin Clark, Janet S. Prevéy, Mats P. Björkman, Edward A. G. Schuur, Toke T. Høye, Zoe A. Panchen, and Kari Klanderud

Subjects

flowering, Phenology, Ecology, alpine, Climate change, plant, Tundra, Arctic, climate change, vegetation change, experimental warming, International Tundra Experiment (ITEX), Effects of global warming, General Earth and Planetary Sciences, Environmental science, Terrestrial ecosystem, General Agricultural and Biological Sciences, General Environmental Science

Abstract

Observations of changes in phenology have provided some of the strongest signals of the effects of climate change on terrestrial ecosystems. The International Tundra Experiment (ITEX), initiated in the early 1990s, established a common protocol to measure plant phenology in tundra study areas across the globe. Today, this valuable collection of phenology measurements depicts the responses of plants at the colder extremes of our planet to experimental and ambient changes in temperature over the past decades. The database contains 150,434 phenology observations of 278 plant species taken at 28 study areas for periods of 1 to 26 years. Here we describe the full dataset to increase the visibility and use of these data in global analyses, and to invite phenology data contributions from underrepresented tundra locations. Portions of this tundra phenology database have been used in three recent syntheses, some datasets are expanded, others are from entirely new study areas, and the entirety of these data are now available at the Polar Data Catalogue., Arctic Science, 8 (3), ISSN:2368-7460

Published

2022

5. Shading decreases and delays NDVI and flowering of prostrate Arctic shrubs1

Author

Jeremy L. May, Steven F. Oberbauer, Steven L. Unger, Matthew J. Simon, Katlyn R. Betway, and Robert D. Hollister

Subjects

Environmental sciences, climate change, lingonberry, Environmental engineering, Vaccinium vitis-idaea, GE1-350, TA170-171, phenology, Arctous alpina, bearberry

Abstract

Increases in shrub growth and canopy cover are well documented community responses to climate warming in the Arctic. An important consequence of larger deciduous shrubs is shading of prostrate plant species, many of which are important sources of nectar and berries. Here, we present the impact of a shading experiment on two prostrate shrubs, Vaccinium vitis-idaea L. and Arctous alpina L., in northern Alaska over two growing seasons. We implemented three levels of shading (no shade, 40% shade, and 80% shade) in dry heath and moist acidic tundra. Plots were monitored for soil moisture content, surface temperature, normalized difference vegetation index (NDVI), and flowering. Shading was shown to, on average, lower surface temperature (0.7 °C to 5.3 °C) and increase soil moisture content (0.5% to 5.6%) in both communities. Both species- and plot-level NDVI values were delayed in timing of peak values (7 to 13 days) and decreased at the highest shading. Flower abundance of both species was lower in shaded plots and peak flowering was delayed (3 to 8 days) compared with controls. Changes in timing may result in phenological mismatches and can impact other trophic levels in the Arctic as both the flowers and resulting berries are important food sources for animals.

Published

2021

6. Warming shortens flowering seasons of tundra plant communities

Author

Sabine B. Rumpf, Marguerite Mauritz, Zoe A. Panchen, Susan M. Natali, Bo Elberling, Ørjan Totland, Christian Rixen, Niels Martin Schmidt, Tiffany G. Troxler, Nadja Rüger, Elisabeth J. Cooper, Karin Clark, Robert D. Hollister, Edward A. G. Schuur, Ingibjörg S. Jónsdóttir, Janet S. Prevéy, Steven F. Oberbauer, Chelsea Chisholm, Kari Klanderud, Katharine N. Suding, Carl-Henrik Wahren, Nicoletta Cannone, Isla H. Myers-Smith, Gregory H. R. Henry, Philipp R. Semenchuk, Eric Post, Jeffrey M. Welker, Sonja Wipf, Isabel W. Ashton, Jane G. Smith, Esther Lévesque, Anna Maria Fosaa, Christopher W. Kopp, Sarah C. Elmendorf, Toke T. Høye, Susanna Venn, Ulf Molau, and Anne D. Bjorkman

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Evolution, Climate Change, Biome, Plant Development, Climate change, Flowers, Biology, 010603 evolutionary biology, 01 natural sciences, Behavior and Systematics, Effects of global warming, Ecosystem, Tundra, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Trophic level, Ecology, Phenology, Temperature, Plant community, Seasons

Abstract

Advancing phenology is one of the most visible effects of climate change on plant communities, and has been especially pronounced in temperature-limited tundra ecosystems. However, phenological responses have been shown to differ greatly between species, with some species shifting phenology more than others. We analysed a database of 42,689 tundra plant phenological observations to show that warmer temperatures are leading to a contraction of community-level flowering seasons in tundra ecosystems due to a greater advancement in the flowering times of late-flowering species than early-flowering species. Shorter flowering seasons with a changing climate have the potential to alter trophic interactions in tundra ecosystems. Interestingly, these findings differ from those of warmer ecosystems, where early-flowering species have been found to be more sensitive to temperature change, suggesting that community-level phenological responses to warming can vary greatly between biomes.

Published

2018

7. Experimental warming differentially affects vegetative and reproductive phenology of tundra plants

Author

Steven F. Oberbauer, Heidi Rodenhizer, Christopher W. Kopp, Sarah C. Elmendorf, Heidi Steltzer, Philipp R. Semenchuk, Carolyn Livensperger, Isabel W. Ashton, Ørjan Totland, Jane G. Smith, Karin Clark, Jakob J. Assmann, Marilyn D. Walker, Chelsea Chisholm, Juha M. Alatalo, Emily Ogburn, Janet S. Prevéy, Christian Rixen, Greg H. R. Henry, Courtney G. Collins, Jeremy L. May, Isla H. Myers-Smith, Ingibjörg S. Jónsdóttir, Anne D. Bjorkman, Marguerite Mauritz, Chiara Forrester, Eric Post, Zoe A. Panchen, Edward A. G. Schuur, Elisabeth J. Cooper, Kari Klanderud, Alessandro Petraglia, Katharine N. Suding, Robert D. Hollister, Jeffrey M. Welker, Ulf Molau, and Michele Carbognani

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Chemistry(all), Science, Climate, General Physics and Astronomy, Growing season, Flowers, Biology, Physics and Astronomy(all), 010603 evolutionary biology, 01 natural sciences, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Article, Spatio-Temporal Analysis, Models, VDP::Mathematics and natural science: 400::Zoology and botany: 480, Ecosystem, Plant ecology, Tundra, Plant Physiological Phenomena, 0105 earth and related environmental sciences, Trophic level, Multidisciplinary, Ecology, Phenology, Biochemistry, Genetics and Molecular Biology(all), Arctic Regions, Reproduction, Global warming, Temperature, General Chemistry, Plants, Biological, Climate Action, Phenotype, Arctic, Seasons, VDP::Matematikk og Naturvitenskap: 400::Zoologiske og botaniske fag: 480

Abstract

Rapid climate warming is altering Arctic and alpine tundra ecosystem structure and function, including shifts in plant phenology. While the advancement of green up and flowering are well-documented, it remains unclear whether all phenophases, particularly those later in the season, will shift in unison or respond divergently to warming. Here, we present the largest synthesis to our knowledge of experimental warming effects on tundra plant phenology from the International Tundra Experiment. We examine the effect of warming on a suite of season-wide plant phenophases. Results challenge the expectation that all phenophases will advance in unison to warming. Instead, we find that experimental warming caused: (1) larger phenological shifts in reproductive versus vegetative phenophases and (2) advanced reproductive phenophases and green up but delayed leaf senescence which translated to a lengthening of the growing season by approximately 3%. Patterns were consistent across sites, plant species and over time. The advancement of reproductive seasons and lengthening of growing seasons may have significant consequences for trophic interactions and ecosystem function across the tundra., Nature Communications, 12 (1), ISSN:2041-1723

Published

2021

8. NDVI Changes Show Warming Increases the Length of the Green Season at Tundra Communities in Northern Alaska: A Fine-Scale Analysis

Author

Craig E. Tweedie, Steven F. Oberbauer, Robert D. Hollister, Jacob A. Harris, Jeffrey M. Welker, Katlyn R. Betway, Jeremy L. May, and William A. Gould

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, ved/biology.organism_classification_rank.species, Plant Science, lcsh:Plant culture, Normalized Difference Vegetation Index, Atmospheric sciences, Graminoid, phenology, 010603 evolutionary biology, 01 natural sciences, Shrub, medicine, lcsh:SB1-1110, experimental warming, Original Research, 0105 earth and related environmental sciences, Biomass (ecology), seasonality, Phenology, ved/biology, Primary production, International Tundra Experiment, Seasonality, medicine.disease, Tundra, climate change, Arctic, Arctic shrubs, Environmental science

Abstract

A warming Arctic has been associated with increases in aboveground plant biomass, specifically shrubs, and changes in vegetation cover. However, the magnitude and direction of changes in NDVI have not been consistent across different tundra types. Here we examine the responsiveness of fine-scale NDVI values to experimental warming at eight sites in northern Alaska, United States. Warming in our eight sites ranged in duration from 2‑23 seasons. Dry, wet and moist tundra communities were monitored for canopy surface temperatures and NDVI in ambient and experimentally-warmed plots at near-daily frequencies during the summer of 2017 to assess the impact of the warming treatment on the magnitude and timing of greening. Experimental warming increased canopy-level surface temperatures across all sites (+0.47 to +3.14˚C), with the strongest warming effect occurring during June and July and for the southernmost sites. Green-up was accelerated by warming at six sites, and autumn senescence was delayed at five sites. Warming increased the magnitude of peak NDVI values at five sites, decreased it at one site, and at two sites it did not change. Warming resulted in earlier peak NDVI at three sites and no significant change in the other sites. Shrub and graminoid cover was positively correlated with the magnitude of peak NDVI (r=0.37 to 0.60) while cryptogam influence was mixed. The magnitude and timing of peak NDVI showed considerable variability across sites. Warming extended the duration of the summer green season at most sites due to accelerated greening in the spring and delayed senescence in the autumn. We show that in a warmer Arctic (as simulated by our experiment) the timing and total period of carbon gain may change. Our results suggest these changes are dependent on community composition and abundance of specific growth forms and therefore will likely impact net primary productivity and trophic interactions.

Published

2020

9. Local snow melt and temperature – but not regional sea-ice – explain variation in spring phenology in coastal Arctic tundra

Author

Janet S. Prevéy, Robert D. Hollister, Niels Martin Schmidt, Richard E. Ennos, Jakob J. Assmann, Greg H. R. Henry, Albert B. Phillimore, Isla H. Myers-Smith, and Anne D. Bjorkman

Subjects

0106 biological sciences, Canada, 010504 meteorology & atmospheric sciences, Environmental change, Greenland, Climate change, 010603 evolutionary biology, 01 natural sciences, phenology, vegetation, Snow, Sea ice, Environmental Chemistry, Ice Cover, Arctic tundra, Tundra, 0105 earth and related environmental sciences, General Environmental Science, Global and Planetary Change, geography, geography.geographical_feature_category, spring, Ecology, Arctic Regions, Phenology, Temperature, temperature, Global change, sea ice, climate change, Snowmelt, Environmental science, snow melt, Seasons, Physical geography, human activities, Alaska

Abstract

The Arctic is undergoing dramatic environmental change with rapidly rising surface temperatures, accelerating sea ice decline and changing snow regimes, all of which influence tundra plant phenology. Despite these changes, no globally consistent direction of trends in spring phenology has been reported across the Arctic. While spring has advanced at some sites, spring has delayed or not changed at other sites, highlighting substantial unexplained variation. Here, we test the relative importance of local temperatures, local snow melt date and regional spring drop in sea ice extent as controls of variation in spring phenology across different sites and species. Trends in long-term time series of spring leaf-out and flowering (average span: 18 years) were highly variable for the 14 tundra species monitored at our four study sites on the Arctic coasts of Alaska, Canada and Greenland, ranging from advances of 10.06 days per decade to delays of 1.67 days per decade. Spring temperatures and the day of spring drop in sea ice extent advanced at all sites (average 1°C per decade and 21 days per decade, respectively), but only those sites with advances in snow melt (average 5 days advance per decade) also had advancing phenology. Variation in spring plant phenology was best explained by snow melt date (mean effect: 0.45 days advance in phenology per day advance snow melt) and, to a lesser extent, by mean spring temperature (mean effect: 2.39 days advance in phenology per °C). In contrast to previous studies examining sea ice and phenology at different spatial scales, regional spring drop in sea ice extent did not predict spring phenology for any species or site in our analysis. Our findings highlight that tundra vegetation responses to global change are more complex than a direct response to warming and emphasize the importance of snow melt as a local driver of tundra spring phenology.

Published

2019

10. Arctic plant responses to changing abiotic factors in northern Alaska

Author

Steven F. Oberbauer, Robert D. Hollister, Craig E. Tweedie, and Robert T. S. Barrett

Subjects

Abiotic component, Arctic Regions, Ecology, Phenology, Climate Change, Reproduction, Temperature, Climate change, Plant Science, Biology, Tundra, Magnoliopsida, Arctic, Snowmelt, Soil water, Genetics, Thaw depth, Alaska, Ecology, Evolution, Behavior and Systematics

Abstract

Premise of the study Understanding the relationship between plants and changing abiotic factors is necessary to document and anticipate the impacts of climate change. Methods We used data from long-term research sites at Barrow and Atqasuk, Alaska, to investigate trends in abiotic factors (snow melt and freeze-up dates, air and soil temperature, thaw depth, and soil moisture) and their relationships with plant traits (inflorescence height, leaf length, reproductive effort, and reproductive phenology) over time. Key results Several abiotic factors, including increasing air and soil temperatures, earlier snowmelt, delayed freeze-up, drier soils, and increasing thaw depths, showed nonsignificant tendencies over time that were consistent with the regional warming pattern observed in the Barrow area. Over the same period, plants showed consistent, although typically nonsignificant tendencies toward increasing inflorescence heights and reproductive efforts. Air and soil temperatures, measured as degree days, were consistently correlated with plant growth and reproductive effort. Reproductive effort was best predicted using abiotic conditions from the previous year. We also found that varying the base temperature used to calculate degree days changed the number of significant relationships between temperature and the trait: in general, reproductive phenologies in colder sites were better predicted using lower base temperatures, but the opposite held for those in warmer sites. Conclusions Plant response to changing abiotic factors is complex and varies by species, site, and trait; however, for six plant species, we have strong evidence that climate change will cause significant shifts in their growth and reproductive effort as the region continues to warm.

Published

2015

11. Short-Term Impacts of the Air Temperature on Greening and Senescence in Alaskan Arctic Plant Tundra Habitats

Author

Jeffrey M. Welker, William A. Gould, Craig E. Tweedie, N. C. Healey, Robert D. Hollister, Jeremy L. May, Hella Ellen Ahrends, and Steven F. Oberbauer

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Science, Growing season, Climate change, Mobile Instrumented Sensor Platform, Normalized Difference Vegetation Index, Atmospheric sciences, Graminoid, phenology, 010603 evolutionary biology, 01 natural sciences, 0105 earth and related environmental sciences, Phenology, Plant community, arctic shrubs, climate change, 15. Life on land, Tundra, Arctic, 13. Climate action, General Earth and Planetary Sciences, Environmental science, Forb

Abstract

Climate change is warming the temperatures and lengthening the Arctic growing season with potentially important effects on plant phenology. The ability of plant species to acclimate to changing climatic conditions will dictate the level to which their spatial coverage and habitat-type dominance is different in the future. While the effect of changes in temperature on phenology and species composition have been observed at the plot and at the regional scale, a systematic assessment at medium spatial scales using new noninvasive sensor techniques has not been performed yet. At four sites across the North Slope of Alaska, changes in the Normalized Difference Vegetation Index (NDVI) signal were observed by Mobile Instrumented Sensor Platforms (MISP) that are suspended over 50 m transects spanning local moisture gradients. The rates of greening (measured in June) and senescence (measured in August) in response to the air temperature was estimated by changes in NDVI measured as the difference between the NDVI on a specific date and three days later. In June, graminoid- and shrub-dominated habitats showed the greatest rates of NDVI increase in response to the high air temperatures, while forb- and lichen-dominated habitats were less responsive. In August, the NDVI was more responsive to variations in the daily average temperature than spring greening at all sites. For graminoid- and shrub-dominated habitats, we observed a delayed decrease of the NDVI, reflecting a prolonged growing season, in response to high August temperatures. Consequently, the annual C assimilation capacity of these habitats is increased, which in turn may be partially responsible for shrub expansion and further increases in net summer CO2 fixation. Strong interannual differences highlight that long-term and noninvasive measurements of such complex feedback mechanisms in arctic ecosystems are critical to fully articulate the net effects of climate variability and climate change on plant community and ecosystem processes.

Published

2017

12. PLANT RESPONSE TO TEMPERATURE IN NORTHERN ALASKA: IMPLICATIONS FOR PREDICTING VEGETATION CHANGE

Author

Robert D. Hollister, P. J. Webber, and Christian Bay

Subjects

Arctic, Ecology, Phenology, Global warming, Environmental science, Climate change, Context (language use), Vegetation, Energy budget, Ecology, Evolution, Behavior and Systematics, Tundra

Abstract

The response of plants to temperature has gained renewed interest as researchers speculate on the biotic response to climate change. It is of particular interest in the Arctic, due to recent warming trends and anticipated continued warming for the region. This long-term, multispecies study confirms that changes in temperature affect the functioning of plants in their natural environment. It also demonstrates that the influence of temperature should be considered in the context of natural variability within a given location. The study examined natural temperature gradients, interannual climate variation, and experimental warming at sites near Barrow (71°18′ N, 156°40′ W) and Atqasuk (70°29′ N, 157°25′ W) in northern Alaska, USA. At each of the four sites, 24 plots were experimentally warmed for 5–7 years with small, open-top chambers, and plant growth and phenology were monitored; an equal number of unmanipulated control plots were monitored. The response of seven traits from 32 plant species occurring in ...

Published

2005

13. RESPONSES OF TUNDRA PLANTS TO EXPERIMENTAL WARMING:META-ANALYSIS OF THE INTERNATIONAL TUNDRA EXPERIMENT

Author

P. Mølgaard, Ørjan Totland, A. M. Arft, Michael H. Jones, Juha M. Alatalo, Felix Gugerli, Philip A. Wookey, Clare H. Robinson, Esther Lévesque, Robert D. Hollister, Mikael Stenström, P. L. Turner, Mark R. T. Dale, Ingibjörg S. Jónsdóttir, P. J. Webber, M. S. Bret-Harte, G. M. Marion, Urban Nordenhäll, Gregory H. R. Henry, Anna Stenström, Ulf Molau, L. J. Walker, M. Diemer, V. Raszhivin, Marilyn D. Walker, Jeffrey M. Welker, Kari Laine, Jessica Gurevitch, and Gregory Starr

Subjects

Eriophorum vaginatum, biology, Vegetative reproduction, Phenology, Ecology, media_common.quotation_subject, biology.organism_classification, Tundra, Competition (biology), Arctic, Cassiope tetragona, Salix arctica, Ecology, Evolution, Behavior and Systematics, media_common

Abstract

The International Tundra Experiment (ITEX) is a collaborative, multisite experiment using a common temperature manipulation to examine variability in species response across climatic and geographic gradients of tundra ecosystems. ITEX was designed specifically to examine variability in arctic and alpine species response to increased temperature. We compiled from one to four years of experimental data from 13 different ITEX sites and used meta-analysis to analyze responses of plant phenology, growth, and reproduction to experimental warming. Results indicate that key phenological events such as leaf bud burst and flowering occurred earlier in warmed plots throughout the study period; however, there was little impact on growth cessation at the end of the season. Quantitative measures of vegetative growth were greatest in warmed plots in the early years of the experiment, whereas reproductive effort and success increased in later years. A shift away from vegetative growth and toward reproductive effort and success in the fourth treatment year suggests a shift from the initial response to a secondary response. The change in vegetative response may be due to depletion of stored plant reserves, whereas the lag in reproductive response may be due to the formation of flower buds one to several seasons prior to flowering. Both vegetative and reproductive responses varied among life-forms; herbaceous forms had stronger and more consistent vegetative growth responses than did woody forms. The greater responsiveness of the herbaceous forms may be attributed to their more flexible morphology and to their relatively greater proportion of stored plant reserves. Finally, warmer, low arctic sites produced the strongest growth responses, but colder sites produced a greater reproductive response. Greater resource investment in vegetative growth may be a conservative strategy in the Low Arctic, where there is more competition for light, nutrients, or water, and there may be little opportunity for successful germination or seedling development. In contrast, in the High Arctic, heavy investment in producing seed under a higher temperature scenario may provide an opportunity for species to colonize patches of unvegetated ground. The observed differential response to warming suggests that the primary forces driving the response vary across climatic zones, functional groups, and through time.

Published

1999

14. Phenological response of tundra plants to background climate variation tested using the International Tundra Experiment

Author

Ørjan Totland, Ingibjörg S. Jónsdóttir, Gregory H. R. Henry, Toke T. Høye, Frith C. Jarrad, Steven F. Oberbauer, Kari Klanderud, Jeffery M. Welker, Ulf Molau, R T Slider, Melissa A. Dawes, Robert D. Hollister, Sarah C. Elmendorf, M. S. Bret-Harte, Julia A. Klein, Niels Martin Schmidt, Adrian V. Rocha, Gus Shaver, Anna Maria Fosaa, C-H Wahren, Christian Rixen, and Tiffany G. Troxler

Subjects

Internationality, Time Factors, Phenology, Ecology, Arctic Regions, Climate Change, Plant Development, Plant community, Articles, Flowers, Plants, Atmospheric sciences, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Tundra, Latitude, Plant Leaves, Greening, Arctic, Environmental science, Ecosystem, Seasons, Arctic vegetation, General Agricultural and Biological Sciences

Abstract

The rapidly warming temperatures in high-latitude and alpine regions have the potential to alter the phenology of Arctic and alpine plants, affecting processes ranging from food webs to ecosystem trace gas fluxes. The International Tundra Experiment (ITEX) was initiated in 1990 to evaluate the effects of expected rapid changes in temperature on tundra plant phenology, growth and community changes using experimental warming. Here, we used the ITEX control data to test the phenological responses to background temperature variation across sites spanning latitudinal and moisture gradients. The dataset overall did not show an advance in phenology; instead, temperature variability during the years sampled and an absence of warming at some sites resulted in mixed responses. Phenological transitions of high Arctic plants clearly occurred at lower heat sum thresholds than those of low Arctic and alpine plants. However, sensitivity to temperature change was similar among plants from the different climate zones. Plants of different communities and growth forms differed for some phenological responses. Heat sums associated with flowering and greening appear to have increased over time. These results point to a complex suite of changes in plant communities and ecosystem function in high latitudes and elevations as the climate warms.

Published

2013

15. Arctic plants are capable of sustained responses to long-term warming

Author

Robert D. Hollister, Robert T. Barrett, and National Science Foundation Office of Polar Programs

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, media_common.quotation_subject, ecology, arctic ecology, climate change, meta-analysis, Biology, Oceanography, 010603 evolutionary biology, 01 natural sciences, Competition (biology), lcsh:Oceanography, Nutrient, Earth and Planetary Sciences (miscellaneous), Environmental Chemistry, lcsh:GC1-1581, Arctic vegetation, tundra vegetation, Species traits, International Tundra Experiment, plant–climate interactions, warming response, lcsh:Environmental sciences, 0105 earth and related environmental sciences, General Environmental Science, media_common, lcsh:GE1-350, 2. Zero hunger, Herbivore, Ecology, Phenology, Vegetation, 15. Life on land, Tundra, Inflorescence, 13. Climate action

Abstract

Previous studies have shown that Arctic plants typically respond to warming with increased growth and reproductive effort and accelerated phenology, and that the magnitude of these responses is likely to change over time. We investigated the effects of long-term experimental warming on plant growth (leaf length) and reproduction (inflorescence height, reproductive phenology and reproductive effort) using 17–19 years of measurements collected as part of the International Tundra Experiment (ITEX) at sites near Barrow and Atqasuk, Alaska. During the study period, linear regressions indicated non-significant tendencies towards warming air temperatures at our study sites. Results of our meta-analyses on the effect size of experimental warming (calculated as Hedges’ d ) indicated species generally responded to warming by increasing inflorescence height, increasing leaf length and flowering earlier, while reproductive effort did not respond consistently. Using weighted least-squares regressions on effect sizes, we found a significant trend towards dampened response to experimental warming over time for reproductive phenology. This tendency was consistent, though non-significant, across all traits. A separate analysis revealed significant trends towards reduced responses to experimental warming during warmer summers for all traits. We therefore propose that tendencies towards dampened plant responses to experimental warming over time are the result of regional warming. These results show that Arctic plants are capable of sustained responses to warming over long periods of time but also suggest that, as the region continues to warm, factors such as nutrient availability, competition and herbivory will become more limiting to plant growth and reproduction than temperature. Keywords: Species traits; International Tundra Experiment; meta-analysis; plant–climate interactions; tundra vegetation; warming response. (Published: 5 May 2016) To access the supplementary material for this article, please see the supplementary file in the column to the right (under Article Tools). Citation: Polar Research 2016, 35 , 25405, http://dx.doi.org/10.3402/polar.v35.25405

Published

2016