Phytomass and phenology of three alpine snowpatch species across a natural snowmelt gradient

2007 ◽  
Vol 55 (4) ◽  
pp. 450 ◽  
Author(s):  
Susanna E. Venn ◽  
John W. Morgan
Keyword(s):  
Plant Species ◽  
Spatial Scales ◽  
Growing Season ◽  
Plant Distribution ◽  
High Mountain ◽  
Flower Bud ◽  
Mountain Areas ◽  
Winter Snow ◽  
Landscape Scales

Alpine snowpatch vegetation in Australia is restricted to high mountain areas and occurs in locations where winter snow persists longest into the summer. The timing of annual snowmelt is considered an important determinant of vegetation patterns in alpine areas because it affects the length of the growing season for plant species at landscape scales. There are few studies in Australia that have examined the effects of the date of snowmelt on the performance of plant species at small spatial scales. The phytomass and phenology of three common snowpatch species (Celmisia pugioniformis, Luzula acutifolia, Poa fawcettiae) was examined during one growing season across a natural snowmelt gradient to examine their response to time of snow release. Peak phytomass was significantly higher in early than late-melting zones for L. acutifolia and marginally higher there for C. pugioniformis. P. fawcettiae, however, produced higher mean peak phytomass in late-melting zones where soil was initially wetter in the growing season. Flower buds of L. acutifolia were evident as the snow melted, and flowering occurred at the same time in all areas of the snowpatch. The number of days from the date of snowmelt to the date of the first observed flower bud in C. pugioniformis and P. fawcettiae was 22–25 days shorter in late-melting areas than in early melting areas. For both of these species, flowering and subsequent seed set occurred simultaneously across the snowpatch regardless of the date of the initial snowmelt, suggesting that photoperiod controls flowering in these species. Our study suggests that the predicted declines in snow cover in Australia in coming decades may affect the phytomass of species that are currently constrained by late-lying snow. This, in turn, may affect their long-term patterns of distribution. If plants respond to photoperiod for flowering, as seems to be important here for C. pugioniformis and P. fawcettiae, it is unlikely that the periods following earlier than usual snowmelt will be fully utilised by these species. Any attempts at predicting or modelling future alpine plant distribution on the basis of warming scenarios may therefore need to account for photoperiod constraints on flowering as well changes in phytomass production.

Communicating Climate Change to broad public through Educations - Project KlimaAlps

2021 ◽  
Author(s):  
Cornelia Baumann ◽  
Inga Beck
Keyword(s):  
Climate Change ◽  
Scientific Information ◽  
Environmental Research ◽  
Background Information ◽  
High Mountain ◽  
Research Station ◽  
Human Beings ◽  
Mountain Areas ◽  
The Alps

<p>Education is key in order to create a generation that thinks and acts sustainable and that considers nature as one of the most important good.Within the three years Interreg Project ‘KlimaAlps’ (www.klimaalps.eu) – making climate change visible - one major task is the establishment of a training for educators, to become a certified ‘Climate-Pedagogue’ for the alpine region. The ‘Climate-Pedagogue’-training contains background information of climate change in the Alps and a variety of innovative educational tools and methods. It covers aspects of the high mountain areas, rivers and lakes, human beings, agriculture as well as moors.  The project is managed by the ‘Energiewende Oberland’; five additional partners from Austria and Bavaria are responsible for e. g. a high quality of the taught scientific information (Environmental Research Station Schneefernerhaus), the didactical input (University of Innsbruck, Department of Geography), the outreach activities and the implementation (Naturpark Karwendel, Klimabündnis Oberösterreich, Landratsamt Garmisch-Partenkirchen). During the last one and half years, the concept for the ‘Climate-Pedagogue’- training was worked out in cooperation with other environmental facilities and in March 2021 the first lectures of a pilot run with over 30 selected participants were held. In total there will be two runs in 2021 in order to evaluate the recent version of the training as good as possible. The next and long-term steps will be the firm establishment of a chargeable ‘Climate-Pedagogue’ – Training for every interested person for at least the coming ten years, as well as the strengthening and growing of the network. The presentation will give a short overview about the entire project as well as details about the ‘Climate-Pedagogue’ – Training and some first impressions of the already hold lectures in 2021.</p>

scholarly journals Changes in Thermal Conditions in the High Mountain Areas and Contemporary Warming in the Central Europe

2010 ◽  
Vol 14 (1) ◽  
pp. 59-70 ◽  
Author(s):  
Elwira Żmudzka
Keyword(s):  
Thermal Characteristics ◽  
Thermal Conditions ◽  
Seasonal Distribution ◽  
High Mountain ◽  
Tatra Mountains ◽  
Upward Trend ◽  
Mountain Areas ◽  
Weather Stations ◽  
The Tatra Mountains

Abstract The purpose of the report is to determine trends in thermal conditions in the Polish part of the Tatra Mountains. The results of studies were compared with the results of analogous analyses, carried out for the area of lowland Poland. The study makes use of the data from the weather stations in Zakopane and on Kasprowy Wierch Mt. from the years 1951-2006, mainly from 1966-2006. The thermal conditions in lowland Poland was determined on the basis of the area-averaged time series (45 stations). Various thermal characteristics were considered. The increase of the rate of upward trend in temperature at the turn of the 21st century, as well as the change of the seasonal distribution of the warming in comparison with the preceding long-term periods, have been documented. Symptoms of increase of the thermal continentality have also been observed.

A high-resolution multi-phase thermo-geophysical permafrost rock model to verify long-term ERT monitoring at the Zugspitze (German/Austrian Alps)

2021 ◽  
Author(s):  
Tanja Schroeder ◽  
Michael Krautblatter
Keyword(s):  
Electrical Resistivity ◽  
Energy Balance ◽  
Thermal Regime ◽  
Thermal Evolution ◽  
High Mountain ◽  
Permafrost Degradation ◽  
Complex Topography ◽  
Mountain Areas ◽  
Permafrost Rock

<div> <p><span>In the context of climate change, permafrost degradation is a key variable in understanding rock slope failures in high mountain areas. Permafrost degradation imposes a variety of environmental, economic and humanitarian impacts on infrastructure and people in high mountain areas. Therefore, new high-quality monitoring and modelling strategies are needed.</span></p> </div><div> <p><span>We developed a new, numerical, thermo-geophysical rock permafrost model (TGRPM) to assess spatial-temporal variations of the ground thermal regime in steep permafrost rock walls on the basis of 13-years of Electrical Resistivity Tomography (ERT) monitoring of permafrost at the Zugspitze. TGRPM is a simple to understand and workable numerical 2D MATLAB-model, which is adaptable to different topographic and sub-surface conditions, and further relies on a minimum of input-data to assess the surface energy balance and the ground thermal regime. It simulates the thermal response for permafrost rock walls, including their complex topography, to climate forcing over multiple years. It aims to assess seasonal and long-term permafrost development in steep alpine rock walls, as well as serving as a straightforward calculation routine, which is solely based on physical processes and does not require any fitting of certain parameters. </span></p> </div><div> <p><span>At first, the model was tested against direct temperature measurements from the LfU-borehole at the Zugspitze summit to prove its accuracy. Then, it is run against a 13-year ERT data-set from the Zugspitze Kammstollen to validate the ERT measurements.</span></p> </div><div> <p><span>Here, we show the first thermo-geophysical model referencing thermal evolution in a permafrost rock wall with temperature-calibrated ERT. The TGRPM successfully computes the thermal evolution within the Zugspitze mountain ridge from a 2D coupled energy balance and heat conduction scheme in complex topography. It furthermore validates the temperature-resistivity relationship by Krautblatter et al. (2010) for natural rock walls reaching a correlation of 85 to 95 % between measured, ERT-derived and modelled temperatures.</span></p> </div><div><span>Krautblatter, M., Verleysdonk, S., Flores-Orozco, A. & Kemna, A. (2010): Temperature-calibrated imaging of seasonal changes in permafrost rock walls by quantitative electrical resistivity </span><span>tomography </span>(Zugspitze, German/Austrian Alps). <em>J. Geophys. Res. </em>115: F02003.</div>

scholarly journals Effects of Aphid Density and Plant Taxa on Predatory Ladybeetle Abundance at Field and Landscape Scales

Insects ◽  
2020 ◽  
Vol 11 (10) ◽  
pp. 695
Author(s):  
Hongsheng Pan ◽  
Bing Liu ◽  
Coline C. Jaworski ◽  
Long Yang ◽  
Yongqiang Liu ◽  
...  
Keyword(s):  
Plant Species ◽  
Local Field ◽  
Growing Season ◽  
Landscape Scale ◽  
Agricultural Landscapes ◽  
Field Scale ◽  
Diverse Range ◽  
Positive Correlation ◽  
Regional Landscape ◽  
Landscape Scales

In agroecosystems, predatory ladybeetles play an important role in restraining aphid population growth and suppressing aphid populations. They can adapt to various habitats and make use of various aphid species associated with multiple host plants during their life cycle. Agricultural landscapes in China are composed of a mosaic of small fields with a diverse range of crops, and how ladybeetles make use of host plant diversity in such landscapes has rarely been documented. In this study, we examined the relationship between aphid densities and ladybeetle densities in two different settings: (i) on the majority of plant species (including crops, trees, and weeds) at a local field scale in 2013 and 2014, and (ii) in paired cotton and maize crop fields at a regional landscape scale in 2013. Overall, we found that aphid abundance determined predatory ladybeetle abundance at both the local field and landscape scales, and there was a positive correlation between aphid densities and ladybeetle densities. However, plant taxa had no significant influence on the predatory ladybeetle abundance at the local field scale. In addition, the effect of aphids on ladybeetles abundance was influenced by the crop type and growing season at the regional landscape scale. There was a significant positive correlation between aphids and ladybeetles populations on cotton only in July and August, whereas the correlation was significant for maize throughout the whole growing season. We also conducted an analysis of the stable carbon isotope ratios of the adult ladybeetles caught in cotton and maize fields (C3 and C4 crops, respectively) in a regional landscape-scale survey in 2013. The δ13Cvalue indicated that most prey aphids for ladybeetles originated from crops where aphids are abundant (cotton in June and July; both maize and cotton in August).These findings improved our understanding of the migration and dispersal of ladybeetles among different habitats and plant species and provided insight into the promotion of the regional conservation and pest control of natural enemies in northern China.

The high mountain vegetation of Australia

1957 ◽  
Vol 5 (2) ◽  
pp. 173 ◽  
Author(s):  
AB Costin
Keyword(s):  
Land Use ◽  
High Mountain ◽  
Climatic Data ◽  
Mountain Areas ◽  
Winter Snow ◽  
Eastern Australia ◽  
Australian Alps ◽  
Mountain Environment ◽  
Mountain Vegetation ◽  
Almost All

An account is given of the high mountain vegetation of the Australian Alps. This vegetation is naturally defined as that situated above the level of the winter snow-line (4500–5000 ft); it occupies an area in south-eastern Australia of about 2000 sq. miles. The high mountain environment can be divided into subalpine and alpine tracts, on the basis of average duration of the winter snow cover and related effects. Relevant climatic data are given, together with information on physiography, geology, flora, fauna, soils, and land use. The plant communities identified earlier in the Snowy Mountains area are found to provide a generalIy satisfactory basis for the rest of the high mountain areas. The various fjaeldmark, alpine herbfield, sod tussock grassland, heath, subalpine woodland, and bog and fen alliances are enumerated, with details of distribution and rariation in Australia and comparisons with homologous vegetation in Europe. Five broad ecological types of high mountain are recognized and the characteristic associations of communities are described. Almost all of the Australian high mountain vegetation has been modified by land use. Few of the existing communities are regarded as stable and the direction of change will depend largely on how they are henceforth managed by man.

scholarly journals Influence of geodynamic processes on the geoecological state of high mountain areas

2020 ◽  
pp. 70-100
Author(s):  
Х.О. Чотчаев ◽  
О.Г. Бурдзиева ◽  
В.Б. Заалишвили
Keyword(s):  
Seismic Waves ◽  
Abiotic Factors ◽  
Active Faults ◽  
Gravitational Energy ◽  
High Mountain ◽  
Mountain Areas ◽  
Geophysical Fields ◽  
Geodynamic Processes ◽  
The Impact

Научно обоснованный прогноз геоэкологической эволюции территорий на основе анализа причинно-следственной зависимости эндогенных и экзогенных процессов является актуальной задачей обеспечения безопасности рекреантов и планирования долгосрочного развития высокогорных туристско-рекреационных комплексов. Цель исследований – долгосрочной прогноз геоэкологической эволюции территории на основе факторов геодинамического развития и их признаков в геофизических полях. Для достижения поставленной цели решались следующие задачи: анализ современных представлений о влиянии эндогенных геодинамических процессов на изменения природной среды горных территорий и определение геодинамической концепции геоэкологической зависимости; методологическое обоснование проявлений геофизических полей-индикаторов тектономагматических процессов и выбор методов их исследования, выделение зон активных разломов и неотектонических проявлений. Использованы материалы исследований методами обменных волн землетрясений, гравимагнитометрии, микросейсмического зондирования, электротомографии, преломленных сейсмических волн, геолокации. В качестве результатов исследований делается вывод, что геоэкологические изменения вызваны неотектоникой трещинного типа в приледниковых зонах активных глубинных разломов из-за неравномерного воздымания отдельных участков территории при горообразовании, обуславливающего напряженно-деформированное состояние среды, концентрацию гравитационной энергии и последующее разрушение коренных пород приледниковых зон. Установлено, что механические, физические и геохимические поля, как неотъемлемые признаки-индикаторы проявлений и основа методологических обоснований исследований геодинамических процессов, оказывают долговременное влияние на породы на всех уровнях породообразования, формируя современную кору выветривания, и обуславливая интенсивное накопление четвертичных отложений. Определен режим среднестатической геоэкологической эволюции территории, который определяется соотношением скоростей прироста гор и темпов денудации. Делается вывод, что комплекс сопутствующих признаков – индикаторов представляют собой абиотические факторы геоэкологической среды, особого биотопа, где зарождается определенная популяция биоценоза с эндемической зависимостью к этим условиям A scientifically established forecast of the geoecological evolution of areas based on the analysis of the causal relationship of endogenous and exogenous processes is a relevant task of ensuring the safety of vacationers and planning the long-term development of high-mountain tourist and recreational complexes. Aim. The aim of the research is a long-term forecast of the geoecological evolution of the area based on the factors of geodynamic development and their signs in geophysical fields. To achieve this goal, the following tasks were solved: analysis of modern ideas about the impact of endogenous geodynamic processes on changes in the natural environment of mountain areas and the definition of the geodynamic concept of geoecological dependence; methodological substantiation of the manifestations of geophysical fields-indicators of tectonomagmatic processes and the choice of methods for their study, identification of zones of active faults and neotectonic manifestations. Methods. Materials of research by methods of converted waves of earthquakes, gravimagnetometry, microseismic sounding, electro-tomography, refracted seismic waves, geolocation were used. Results. As a result of the research, it is concluded that geoecological changes are caused by fracture neotectonics in the periglacial zones of active deep faults due to uneven uplift of certain parts of the territory during mountain building, which causes the stress-strain state of the environment, the concentration of gravitational energy and the subsequent destruction of the bedrock of the periglacial zones. It has been determined that mechanical, physical and geochemical fields, as integral indicators of manifestations and the basis of methodological substantiation of studies of geodynamic processes, have a long-term effect on rocks at all levels of rockforming, creating the modern weathering crust, and causing an intensive accumulation of Quaternary sediments. The mode of average static geoecological evolution of the area is defined. It is determined by the ratio of the growth rates of mountains and the rates of denudation. One can draw a conclusion that the complex of accompanying signs-indicators is abiotic factors of geoecological environment, a special biotope, where a certain population of biocenosis with endemic dependence to these conditions arises

New multi-phase thermo-geophysical model: Validate ERT-monitoring & assess permafrost evolution in alpine rock walls (Zugspitze, German/Austrian Alps)

2020 ◽  
Author(s):  
Tanja Schroeder ◽  
Riccardo Scandroglio ◽  
Verena Stammberger ◽  
Maximilian Wittmann ◽  
Michael Krautblatter
Keyword(s):  
Electrical Resistivity ◽  
Heat Fluxes ◽  
High Mountain ◽  
Permafrost Degradation ◽  
Mountain Areas ◽  
Rock Wall ◽  
Permafrost Rock ◽  
Geophysical Model ◽  
Multi Phase

<p><span>In the context of climate change, permafrost degradation is a key variable in understanding rock slope failures in high mountain areas. Permafrost degradation imposes a variety of environmental, economic and humanitarian impacts on infrastructure and people in high mountain areas. Therefore, new high-quality monitoring and modelling strategies are needed.</span></p><p><span>Electrical Resistivity Tomography (ERT) is the predominant permafrost monitoring technique in high mountain areas. Its high temperature sensitivity for frozen vs. unfrozen conditions, combined with the resistivity-temperature laboratory calibration on Wettersteinkalk (Zugspitze) (Krautblatter et al. 2010) gives us quantitative information on site-specific rock wall temperatures (Magnin <em>et al.</em> 2015). Long-term ERT-Measurements (2007/2014 – now) were taken at the Kammstollen along the northern Zugspitze rock face. Two high-resistivity bodies along the investigation area reach resistivity values ≥10<sup>4.5</sup></span>Ω<span>m (</span><span>∼</span><span>−0.5 </span><span>°</span><span>C), indicating frozen rock, displaying a core section with resistivities ≥10<sup>4.7</sup></span>Ω<span>m (</span><span>∼</span><span>−2 </span><span>°</span><span>C) (Krautblatter <em>et al.</em>, 2010). We can differentiate seasonal variability, seen by laterally aggrading and degrading marginal sections (Krautblatter <em>et al.</em>, 2010) and singular effects due to environmental factors and extreme weather events.</span></p><p><span>Here, we present a new local high-resolution numerical, process-orientated thermo-geophysical model (TGM) for steep permafrost rock walls. The model links apparent resistivities, the ground thermal regime and meteorological forcings as seasonality and long-term climate change to validate the ERT and project future conditions. The TGM comprises a surface energy balance model, conductive energy transport, turbulent and seasonal heat fluxes (sensible, latent, melt and rain heat fluxes) including phase-change, as well as a multi-phase rock wall composition.</span></p><p><span>Finally, we can reproduce the natural temperature field in the rock wall, assess the spatial-temporal permafrost evolution in alpine rock walls, validate the ERT measurements via the new TGM and the applicability of the laboratory derived resistivity-temperature relationship by Krautblatter et al. (2010) for natural rock-wall conditions.</span></p><p><span> </span></p><p><span>Krautblatter, M., Verleysdonk, S., Flores-Orozco, A. & Kemna, A. (2010): Temperature- calibrated imaging of seasonal changes in permafrost rock walls by quantitative electrical resistivity </span><span>tomography</span><span> (Zugspitze, German/Austrian Alps). <em>J. Geophys. Res. </em>115: F02003.</span></p><p><span>Magnin, F., Krautblatter, M., Deline, P., Ravanel, L., Malet, E., Bevington, A. (2015): Determination of warm, sensitive permafrost areas in near-vertical rockwalls and evaluation of distributed models by electrical resistivity tomography. <em>J. Geophys. Res. Earth Surf.</em>, 120, 745-762.</span></p>

Using Long-Term Population Monitoring Data to Prioritize Conservation Action among Rare Plant Species

2019 ◽  
Vol 39 (2) ◽  
pp. 169 ◽  
Author(s):  
Holly L. Bernardo ◽  
Pati Vitt ◽  
Rachel Goad ◽  
Susanne Masi ◽  
Tiffany M. Knight
Keyword(s):  
Plant Species ◽  
Population Monitoring ◽  
Monitoring Data ◽  
Rare Plant ◽  
Conservation Action ◽  
Rare Plant Species

scholarly journals Responses of Vertebrate Wildlife to Oil and Natural Gas Development: Patterns and Frontiers

2021 ◽  
Author(s):  
A. D. Chalfoun
Keyword(s):  
Natural Gas ◽  
Anthropogenic Activities ◽  
Spatial Scales ◽  
Habitat Type ◽  
Population Level ◽  
Low Frequencies ◽  
Natural Gas Development ◽  
The Usa ◽  
Oil And Natural Gas

Abstract Purpose of Review Anthropogenic activities can lead to the loss, fragmentation, and alteration of wildlife habitats. I reviewed the recent literature (2014–2019) focused on the responses of avian, mammalian, and herpetofaunal species to oil and natural gas development, a widespread and still-expanding land use worldwide. My primary goals were to identify any generalities in species’ responses to development and summarize remaining gaps in knowledge. To do so, I evaluated the directionality of a wide variety of responses in relation to taxon, location, development type, development metric, habitat type, and spatiotemporal aspects. Recent Findings Studies (n = 70) were restricted to the USA and Canada, and taxonomically biased towards birds and mammals. Longer studies, but not those incorporating multiple spatial scales, were more likely to detect significant responses. Negative responses of all types were present in relatively low frequencies across all taxa, locations, development types, and development metrics but were context-dependent. The directionality of responses by the same species often varied across studies or development metrics. Summary The state of knowledge about wildlife responses to oil and natural gas development has developed considerably, though many biases and gaps remain. Studies outside of North America and that focus on herpetofauna are lacking. Tests of mechanistic hypotheses for effects, long-term studies, assessment of response thresholds, and experimental designs that isolate the effects of different stimuli associated with development, remain critical. Moreover, tests of the efficacy of habitat mitigation efforts have been rare. Finally, investigations of the demographic effects of development across the full annual cycle were absent for non-game species and are critical for the estimation of population-level effects.

Sign in / Sign up

Export Citation Format

Share Document