Your search keyword '"GLACIAL climates"' showing total 2,856 results

1. Formation and breach of the giant Cuola landslide dam and their impacts on the landscape evolution of river valley in the Jinsha River, southeastern Tibet.

Author

Zhou, Xiaopeng, Deng, Jianhui, Zhao, Siyuan, Li, Hua, Cui, Haonan, Ye, Chenglin, and Hu, Wanyu

Subjects

*LANDSLIDE dams, *WATERSHEDS, *VALLEYS, *GLACIAL climates, *FAULT zones, *LANDSLIDES

Abstract

The giant Cuola landslide is one of the largest and highest landslide dams in the upper reaches of the Jinsha River, which brought about a substantial influence on the geomorphological evolution of the Jinsha River valley. Through field investigations, UAV photogrammetry, OSL, and 10Be dating methods, the topographic and geological characteristics of the Cuola landslide dam were examined, and the evolution features of formation and failure were investigated as well. The results indicate that the Cuola landslide, with a volume of ~ 4 × 108 m3 and an age of ~ 50.9 ka BP, was primarily due to a seismic event, and the major failure mode of the ~ 1590-m-high source area on the left bank was attributable to a wedge sliding. The landslide body slid into the valley and climbed ~ 540 m up the right bank with a long runout of 3740 m. The relict landslide deposits demonstrate a large-scale natural dam with a height of 272 m, a length of 1780 m, and a width of 1940 m, which completely blocked the river, and formed a dammed lake with an inundation length of 190 km and an impoundment volume of 10.817 km3. The longevity of the landslide dam was discussed in terms of glacial climate, dam morphology, and material characteristics, and fault dislocation was deduced to induce the overtopping dam break at ~ 4 ka BP. The overflowing water preferentially undercut the weak zone created by fault displacement within the dam until the onset of the final breach, facilitated by the warm climatic conditions of Holocene Climatic Optimum. The findings in this study illustrate the dramatic longevity of a natural dam produced by a giant landslide in one of the most deeply incised valleys in the world and provide a conceptual model for a better understanding of landslide-induced landscape evolution of high-relief river catchments. [ABSTRACT FROM AUTHOR]

Published

2024

2. Tracking the Filling, Outburst Flood and Resulting Subglacial Water Channel From a Large Canadian Arctic Subglacial Lake.

Author

Gray, Laurence, Lauzon, Benoît, Copland, Luke, Van Wychen, Wesley, Dow, Christine, Kochtitzky, Will, and Alley, Karen E.

Subjects

*ENDORHEIC lakes, *SUBGLACIAL lakes, *GLACIAL climates, *DIGITAL elevation models, *WATER pressure, *ICE

Abstract

We use digital elevation models (DEMs) and ICESat‐2 data to study the filling and outflow from a large subglacial lake under Manson Icefield in the Canadian Arctic. When full, the lake is ∼17 × 3 km with an area of 52 km2. Early in 2021 the ice surface over the center of the lake sank by >140 m implying a subglacial outburst flood of ∼4 km3. Rapid outflow occurred over ∼30 days at an average rate of ∼1,500 m3s−1 resulting in the formation of a single ∼15 km subglacial outflow path detectable from post‐outflow surface depression. The shape of the surface depression, 600–800 m wide by 2–4 m deep, reflects the shape of the subglacial channel prior to closure. Downstream ice movement appears unaffected by the outflow. After outflow ends the surface depression persisted over weeks, apparently dependent on the difference between water and overburden pressures. Plain Language Summary: Using satellite observations, we discovered a large lake under the Manson Icefield in the Canadian Arctic. Early in 2021 the ice surface over the center of the lake sank by around 140 m implying a total subglacial water outflow of around 4 km3, the largest reported outside of Iceland and Antarctica. Most of this water drained from the subglacial lake within 30 days melting some of the ice along the outflow path. For the first time we map the position and size of the subglacial output channel between the downstream end of the lake and the ocean using post‐outflow surface depression as the ice sank downward to close the channel after the water outflow. These results help in understanding the ways in which the presence, movement, and volume of water beneath glaciers influence ice movement and climate related glacial ice loss. Key Points: Using satellite height change data we document the discovery of a 52 km2 subglacial lake under the Manson Icefield, Nunavut, CanadaThe lake filled for around 14 years until early 2021 when the level in the center of the lake dropped by 130 m over 30 daysThe outflow volume was around 4 cubic kilometers and created a wide and shallow subglacial channel that could be tracked for over 15 km [ABSTRACT FROM AUTHOR]

Published

2024

3. Deciphering the Variations and Mechanisms of Global Land Monsoons during Marine Isotope Stage 3.

Author

Zhang, Jinzhe, Yan, Qing, Jiang, Nanxuan, and Guo, Chuncheng

Subjects

*ATLANTIC meridional overturning circulation, *ATMOSPHERIC models, *GLACIAL climates, *MONSOONS, *BUDGET

Abstract

Marine Isotope Stage 3 (MIS 3) is characterized by significant millennial-scale climatic oscillations between cold stadials and mild interstadials, which presents a valuable case for understanding hydrological response to abrupt climate change. Through a set of coupled model simulations, our results broadly show an antiphased interhemispheric change in land monsoonal precipitation during the present-day relative to MIS 3 interstadial and the stadial–interstadial transition, with a general decrease in the Northern Hemisphere but an increase in the Southern Hemisphere. The antiphased pattern is largely caused by the change in orbital insolation during the present-day relative to MIS 3 interstadial, whereas by the weakened Atlantic meridional overturning circulation during the interstadial–stadial transition. However, there are obvious discrepancies in precipitation response and underlying mechanisms among individual monsoon domains and across different periods. Based on the moisture budget analysis, we indicate that the dynamic factor mainly explains the decreased monsoonal rainfall in the Northern Hemisphere during the present-day relative to the MIS 3 interstadial, whereas the thermodynamic term is largely responsible for the increased precipitation in the Southern Hemisphere. In contrast, the dynamic factor plays an important role in the variation of precipitation over all the monsoon zones from the MIS 3 interstadial to stadial states, with the thermodynamic term mainly contributing to the decreased tropical monsoonal precipitation in the colder Northern Hemisphere. Our results help improve the understanding of global monsoon variations under intermediate glacial climate conditions and shed light on their behaviors under potentially rapid climate change in the future. [ABSTRACT FROM AUTHOR]

Published

2024

4. Genetic Structure of Monochamus alternatus (Hope) in Qinling‐Daba Mountains and Expansion Trend: Implications for Pest Prevention and Management.

Author

Qi, Jingyu, Nan, Junke, Zhao, Xiaogu, Liang, Chaoqiong, Fan, Jiangbin, and He, Hong

Subjects

*CONIFER wilt, *POPULATION differentiation, *ECOLOGICAL models, *PINEWOOD nematode, *GLACIAL climates, *PHYLOGEOGRAPHY

Abstract

Pine wilt disease (PWD), caused by Bursaphelenchus xylophilus, severely threatens global pine forests. Monochamus alternatus is the primary vector of B. xylophilus in East Asia. Understanding the population structure and evolutionary forces of vector insects is critical for establishing effective PWD management strategies. The present work explores the genetic structure and phylogenetic relationships of 20 populations of M. alternatus from the Qinling‐Daba Mountains (QDM) in China using the mitochondria DNA dataset, supplemented by ecological niche modeling (ENM). All M. alternatus populations were categorized into three phylogeographic clusters (Clade A, Clade B, and Clade C), with Clade A and Clade B corresponding to the western and eastern QDM, respectively. The results of divergence time estimation concur with environmental changes induced by Quaternary glacial climate oscillations in QDM of China. M. alternatus populations exhibited significant genetic differentiation, with expansion in their population size. Ecological niche modeling (ENM) demonstrated that precipitation and temperature significantly influence the distribution of M. alternatus and the species is anticipated to grow into higher latitude and higher altitude regions in the future. In a nutshell, exploring the genetic structure and evolutionary dynamics of M. alternatus can provide valuable insights into the prevention and occurrence of B. xylophilus. These findings also serve as a reference for research on population differentiation and phylogeography of other species in QDM and adjacent areas. [ABSTRACT FROM AUTHOR]

Published

2024

5. Flooding (or breaching) of inter-connected proglacial lakes by cascading overflow in the arid region of Western Mongolia (Mt. Tsambagarav, Mongolian Altai).

Author

Demberel, Otgonbayar, Dash, Chinmay, Dugersuren, Battsetseg, Bayarmaa, Munkhbat, Seong, Yeong Bae, Chakraborty, Elora, Dorjsuren, Batsuren, Singh, Atul, and Ganhuyag, Nemekhbayar

Subjects

GLACIAL lakes, GLACIAL climates, METEOROLOGICAL satellites, EMERGENCY management, ARID regions, ALPINE glaciers

Abstract

This study investigates the glacial lake outburst flood (GLOF) hazards in the Tsambagarav mountain range in Western Mongolia, focusing on the Khukhnuruu Valley and its interconnected proglacial lakes. Over the last 30 years, significant glacier retreats, driven by rising temperatures and changing precipitation patterns, have led to the formation and expansion of several proglacial lakes. Fieldwork combined with satellite data and meteorological analysis was used to assess the dynamics of glacier and lake area changes, with particular focus on the flood events of July 2021. The research reveals a substantial reduction in glacier area, particularly in the Khukhnuruu E complex, where glacier area decreased by 19.3%. The study highlights the influence of increasing temperatures and summer precipitation, which have accelerated ice melt, contributing to the expansion and eventual breaching of lakes. Additionally, lake area changes were influenced by the steepness of the terrain, with steeper slopes exacerbating peak discharge during floods. Of the studied seven lakes (Lake 1 to Lake 7), Lake 1 experienced the most dramatic reduction, with a decrease in area by 73.51% and volume by 84.84%, followed by Lake 7. This study underscores the region's vulnerability to climate-induced hazards and stresses the need for a comprehensive early warning system and disaster preparedness measures to mitigate future risks. [ABSTRACT FROM AUTHOR]

Published

2024

6. High benthic community respiration and ecosystem response to phytodetrital input in a subpolar fjord on the West Antarctic Peninsula.

Author

Cecchetto, Marta M., Smith, Craig R., Nunnally, Clifton C., and Sweetman, Andrew K.

Subjects

*GLOBAL warming, *GLACIAL melting, *GLACIAL climates, *CONTINENTAL shelf, *FJORDS

Abstract

Glaciomarine fjords dominate the coastal margin of the West Antarctic Peninsula. Studies in similar habitats in the Arctic have shown that benthic biodiversity and ecosystem functioning in inner and middle fjord basins are reduced by turbidity and sedimentation disturbance caused by climate warming–enhanced glacial melting. In contrast, the inner and middle fjord basins along the West Antarctic Peninsula are characterized as productivity and biodiversity hotspots, but benthic ecosystem functions remain unevaluated. In 2015–2016, we conducted sediment respiration and 13C pulse‐chase experiments to assess benthic ecosystem functions along a five‐station transect at ~ 500–600 m depths from the inner Andvord Bay fjord, through to Gerlache Strait, and onto the open continental shelf. Incubation samples from the inner and middle basins of Andvord Bay showed peaks in background seafloor respiration, benthic biomass, and uptake of labeled algal biomass compared to more outlying stations; the continental shelf exhibited the lowest levels of these variables, as well as dissolved inorganic carbon production. Macrofaunal community uptake was responsible for most of the C processing in the inner and middle parts of the fjord (> 45%) while dissolved inorganic carbon was the dominant repository of processed C near the fjord mouth and on the continental shelf (> 80%). The inner parts of Andvord Bay are hotspots of benthic C‐cycling and metabolism, in addition to biodiversity. Ongoing climate warming is likely to negatively impact these inner‐fjord hotspots by increasing meltwater input and sedimentation disturbance, yielding a reduction in the input and recycling of labile detritus at the seafloor in the inner‐middle fjord. [ABSTRACT FROM AUTHOR]

Published

2024

7. How can geomorphology facilitate a better understanding of glacier and ice sheet behaviour?

Author

Jones, Richard S., Miller, Lauren E., and Westoby, Matthew J.

Subjects

GLACIOLOGY, ICE sheets, GLACIAL climates, LANDFORMS, REMOTE sensing, GLACIERS, GEOMORPHOLOGY

Abstract

Glaciers and ice sheets are an integral part of Earth's system, advancing and retreating in response to changes in climate. Clues about the past, present and future behaviour of these ice masses are found throughout current and former glaciated landscapes. In this commentary, we outline recent scientific advances from a collection of articles in which geomorphological evidence is used to inform us about the behaviour of glaciers and ice sheets across a range of spatial (landform to continent) and temporal (seasons to millennia) scales. Through a diversity of approaches including field measurements, remote sensing and numerical modelling, these studies build on an extensive background literature to deepen our understanding of how ice flows, how glaciers and ice sheets respond to climate change, and of the processes of ice advance and retreat and the stability of the system. Further integration of knowledge across the fields of geomorphology and glaciology will have tangible benefits for managing the societal and environmental impacts of glacier change and for improved projections of sea‐level rise over the coming decades to centuries. [ABSTRACT FROM AUTHOR]

Published

2024

8. Carbon isotope budget indicates biological disequilibrium dominated ocean carbon storage at the Last Glacial Maximum.

Author

Omta, Anne Willem, Follett, Christopher L., Lauderdale, Jonathan M., and Ferrari, Raffaele

Subjects

LAST Glacial Maximum, ATMOSPHERIC carbon dioxide, GLACIAL climates, CARBON isotopes, ISOTOPIC signatures

Abstract

Understanding the causes of the ~90 ppmv atmospheric CO2 swings between glacial and interglacial climates is an important open challenge in paleoclimate research. Although the regularity of the glacial-interglacial cycles hints at a single driving mechanism, Earth System models require many independent physical and biological processes to explain the full observed CO2 signal. Here we show that biologically sequestered carbon in the ocean can explain an atmospheric CO2 change of 75 ± 40 ppmv, based on a mass balance calculation using published carbon isotopic measurements. An analysis of the carbon isotopic signatures of different water masses indicates similar regenerated carbon inventories at the Last Glacial Maximum and during the Holocene, requiring that the change in carbon storage was dominated by disequilibrium. We attribute the inferred change in carbon disequilibrium to expansion of sea-ice or change in the overturning circulation. Atmospheric CO2 was ~ 90 ppmv lower at the Last Glacial Maximum (LGM) than during the Holocene. Based on a carbon isotope budget, this study infers that at the LGM biological production pumped carbon into the deep ocean and sea ice kept it there. [ABSTRACT FROM AUTHOR]

Published

2024

9. Glacial AMOC shoaling despite vigorous tidal dissipation: vertical stratification matters.

Author

Chen, Yugeng, Song, Pengyang, Chen, Xianyao, and Lohmann, Gerrit

Subjects

ATLANTIC meridional overturning circulation, LAST Glacial Maximum, VERTICAL mixing (Earth sciences), GLACIAL climates, BOTTOM water (Oceanography)

Abstract

During the Last Glacial Maximum (LGM), tidal dissipation was about 3-fold higher than today, which could have led to a considerable increase in vertical mixing. This increase might have enhanced the glacial Atlantic Meridional Overturning Circulation (AMOC), contradicting the shoaled AMOC indicated by paleoproxies. Here, we conduct ocean model simulations to investigate the impact of background climate conditions and tidal mixing on the AMOC during the LGM. We successfully reproduce the stratified ocean characteristics of the LGM by accurately simulating the elevated salinity of the deep sea and the rapid temperature decrease in the ocean's upper layers. Our findings indicate that the shoaled glacial AMOC is mainly due to strong glacial-ocean stratification, regardless of enhanced tidal dissipation. However, glacial tidal dissipation plays a critical role in the intensification of Antarctic Bottom Water (AABW) during the LGM. Given the critical role of the AMOC in (de-)glacial climate evolution, our results highlight the complex interactions of ocean stratification and tidal dissipation that have been neglected so far. [ABSTRACT FROM AUTHOR]

Published

2024

10. The climate and vegetation of Europe, northern Africa, and the Middle East during the Last Glacial Maximum (21 000 yr BP) based on pollen data.

Author

Davis, Basil A. S., Fasel, Marc, Kaplan, Jed O., Russo, Emmanuele, and Burke, Ariane

Subjects

LAST Glacial Maximum, GLACIAL climates, DATA libraries, ATMOSPHERIC models, LAND cover, BIOMES

Abstract

Pollen data represent one of the most widely available and spatially resolved sources of information about the past land cover and climate of the Last Glacial Maximum (LGM; 21 000 yr BP). Previous pollen data compilations for Europe, the Mediterranean, and the Middle East, however, have been limited by small numbers of sites and poor dating control. Here we present a new compilation of pollen data from the region that improves on both the number of sites (63) and the quality of the chronological control. Data were sourced from both public data archives and published (digitized) diagrams. The analysis is presented based on a standardized pollen taxonomy and sum, with maps shown for the major pollen taxa and biomes and the total arboreal pollen (AP), and on quantitative reconstructions of forest cover and of winter, summer, and annual temperatures and precipitation. The reconstructions are based on the modern analogue technique (MAT) adapted using plant functional type (PFT) scores and with a modern pollen dataset taken from the latest Eurasian Modern Pollen Database (EMPD) (∼8000 samples). A site-by-site comparison of the MAT and the inverse modelling method shows little or no significant difference between the methods for the LGM, indicating that the presence of low-CO 2 conditions and no modern analogue during the LGM does not appear to have had a major effect on MAT transfer function performance. Previous pollen-based climate reconstructions using modern pollen datasets show a much colder and drier climate for the LGM than both inverse modelling and climate model simulations do, but our new results suggest much greater agreement. Differences between our latest MAT reconstruction and those in earlier studies can largely be attributed to bias in the small modern dataset previously used and to differences in the method itself (Brewer et al., 2008; Salonen et al., 2019). We also find that quantitative forest cover reconstructions show more forest than previously suggested by biome reconstructions but less forest than suggested by simply the percentage of arboreal pollen, although uncertainties remain large. Overall, we find that LGM climatic cooling and drying were significantly greater in winter than in summer but with large site-to-site variance that emphasizes the importance of topography and other local factors in controlling the climate and vegetation of the LGM. [ABSTRACT FROM AUTHOR]

Published

2024

11. Decoupled Hydroclimate of Central and Southwestern Iran Controlled by the Strength of Southerly‐Westerly Jets During Marine Isotope Stage 3.

Author

Soleimani, M., Baker, J. L., Nadimi, A., Dublyansky, Y., Koltai, G., and Spötl, C.

Subjects

*GLACIAL climates, *ATMOSPHERIC models, *CLIMATE change, *ISOTOPES, *STALACTITES & stalagmites, *CLIMATE extremes, *WESTERLIES

Abstract

The regional impact of abrupt glacial climate variability remains poorly constrained for arid southwestern Asia, particularly winter dynamics during Marine Isotope Stage 3, due to limited paleoarchives in the Middle East. Here, we present continuous speleothem records of δ18O and δ13C with robust chronologies for southwestern and central Iran, spanning ∼50–30 ka. Stable‐isotope signals in the two stalagmites are generally uncorrelated and do not exhibit a consistent response to Greenland stadials or interstadials; however, both show a positive δ18O excursion that coincides with Heinrich event 4. We explore the potential mechanisms for intermittent coupling of speleothem δ18O across Iran through isotope‐enabled atmospheric modeling outputs, from which we utilize the spatial δ18O gradient as a proxy for wintertime westerly versus southerly jet strength. Our results suggest that during Heinrich event 4 and several Greenland stadials, stronger westerly winds enhanced Mediterranean moisture contributions to both sites and reduced aridity in southern Iran. Plain Language Summary: Stalagmites are useful archives to reconstruct the climate of the past. In order to shed light on the past climate of western Asia and the response of this region to the rapid climate changes, here we present two stalagmites from central and southwestern Iran that span 50,000 to 30,000 yrs ago. Our findings suggest that during extreme cold events, the moisture originates mostly from the west, whereas out of these extraordinarily cold periods moisture comes mostly from the south. Key Points: Continuous high‐resolution speleothem record of climatic change in southwestern and central Iran between 50 and 30 kaDecoupled responses of stable‐isotope gradients in central and southern Iran to glacial climate variability, except during Heinrich event 4Decreased impact of southerly moisture sources and reinforced westerlies during extreme cold events [ABSTRACT FROM AUTHOR]

Published

2024

12. Diversification over deep and shallow temporal scales in the Holarctic genus Perpolita (Gastropoda: Gastrodontidae).

Author

Saito, Takumi, Nekola, Jeffrey C, Nováková, Markéta, Líznarová, Eva, Hirano, Takahiro, Horsáková, Veronika, and Horsák, Michal

Subjects

*LAST Glacial Maximum, *GLACIAL climates, *NUMBERS of species, *FOSSILS, *BIOGEOGRAPHY

Abstract

The Holarctic land snail genus Perpolita was used to explore the influence of past and current biogeography on diversification. The number of empirically-supported species was determined using a consensus between mtDNA sequence, nDNA sequence, conchology, and geographic and ecological range with five valid temperate-boreal species (Perpolita binneyana , Perpolita electrina , Perpolita hammonis , Perpolita petronella , and Perpolita radiatella) being recognized. Only P. petronella was unchanged in both nomenclature and diagnostic characteristics with the remainder requiring alterations. Perhaps the most important of these was elevation of P. radiatella to a valid species, with its populations having been previously lumped either under European P. hammonis or North American P. electrina. Divergence times of 18.7–10.0 Mya were suggested through genome-wide SNPs in combination with the fossil record, indicating a pre-Pleistocene origin for all Perpolita species. Using genetically-confirmed diagnostic shell characters, we accumulated > 2000 valid occurrences and used these to estimate appropriate modern and Last Glacial Maximum climate extents for all species. These models suggest that modern intra-specific gene pool diversity may generally reflect Pleistocene palaeoclimatology. [ABSTRACT FROM AUTHOR]

Published

2024

13. Divergence in Elymus sibiricus is related to geography and climate oscillation: A new look from pan‐chloroplast genome data.

Author

Xiong, Yi, Xiong, Yan‐Li, Jia, Xue‐Jie, Zhao, Jun‐Ming, Yan, Li‐Jun, Sha, Li‐Na, Liu, Lin, Yu, Qing‐Qing, Lei, Xiong, Bai, Shi‐Qie, and Ma, Xiao

Subjects

*CHLOROPLAST DNA, *WHOLE genome sequencing, *GLACIAL climates, *GENE flow, *GEOGRAPHY, *PHENOTYPIC plasticity

Abstract

Quaternary glacial climate oscillation and geographical isolation have significantly influenced the geographic distribution pattern and lineage evolution history of species. However, understanding how these factors specifically impact the genealogical structure of dominant Gramineous species in the Qinghai–Tibet Plateau (QTP) remains a subject of investigation. Elymus sibiricus L. (Gramineae), indigenous to the QTP and widely distributed in Eurasia, exhibits remarkable environmental adaptation and phenotypic diversity, making it an ideal candidate for phylogeographic studies. Based on the analysis of 175 complete chloroplast genome sequences, our results indicated that the ancestors of E. sibiricus originated from the QTP and underwent a complex migration history. After the speciation of E. sibiricus, several geo‐groups exhibited independent differentiation, showing minimal gene flow among them. The current phylogeographic patterns of E. sibiricus are a result of frequent climate alternations and the cold climate during the Quaternary glacial, as well as the presence of several geographical barriers that have restricted the gene flow among different geo‐groups. Our research has revealed for the first time that E. sibiricus has a multilineage origin, and its maternal donors are not limited to a single species. Furthermore, the high quality and mapping depth of the variant file provided reliable data for analyzing the patterns based on raw sequencing data. These findings enhance our understanding of the relationship between plant differentiation and climatic and geographical factors of Eurasia. [ABSTRACT FROM AUTHOR]

Published

2024

14. Evidence for Admixture and Rapid Evolution During Glacial Climate Change in an Alpine Specialist.

Author

Weng, Yi-Ming, Kavanaugh, David H, and Schoville, Sean D

Subjects

CLIMATE change adaptation, GENETIC drift, GROUND beetles, GLACIAL climates, GENETIC variation, ABIOTIC stress

Abstract

The pace of current climate change is expected to be problematic for alpine flora and fauna, as their adaptive capacity may be limited by small population size. Yet, despite substantial genetic drift following post-glacial recolonization of alpine habitats, alpine species are notable for their success surviving in highly heterogeneous environments. Population genomic analyses demonstrating how alpine species have adapted to novel environments with limited genetic diversity remain rare, yet are important in understanding the potential for species to respond to contemporary climate change. In this study, we explored the evolutionary history of alpine ground beetles in the Nebria ingens complex, including the demographic and adaptive changes that followed the last glacier retreat. We first tested alternative models of evolutionary divergence in the species complex. Using millions of genome-wide SNP markers from hundreds of beetles, we found evidence that the N. ingens complex has been formed by past admixture of lineages responding to glacial cycles. Recolonization of alpine sites involved a distributional range shift to higher elevation, which was accompanied by a reduction in suitable habitat and the emergence of complex spatial genetic structure. We tested several possible genetic pathways involved in adaptation to heterogeneous local environments using genome scan and genotype–environment association approaches. From the identified genes, we found enriched functions associated with abiotic stress responses, with strong evidence for adaptation to hypoxia-related pathways. The results demonstrate that despite rapid demographic change, alpine beetles in the N. ingens complex underwent rapid physiological evolution. [ABSTRACT FROM AUTHOR]

Published

2024

15. The Impact of Climate Change on Glacial Lake Outburst Floods.

Author

Gao, Jiajia, Du, Jun, Bai, Yuxuan, Chen, Tao, and Zhuoma, Yixi

Subjects

GLACIAL lakes, GLACIAL climates, EL Nino, CLIMATE change, LA Nina

Abstract

Glacial lake outburst floods (GLOF) hazards in alpine areas are increasing. The effects of climate change on GLOF hazards are unclear. This study examined 37 glacial lakes and climate data from 15 meteorological stations and explored the correlation between climate variations at different temporal scales. The results indicate that 19 GLOFs hazards occurred in El Niño (warm) years, 8 GLOFs hazards occurred in La Niña (cold) years, 3 GLOFs hazards occurred in cold/warm or warm/cold transition years, and 7 GLOFs hazards occurred in normal years. The higher the fluctuations, the higher the probability of GLOF hazards. Climatic conditions can be divided into three categories: extreme temperature and precipitation, as represented by the Guangxie Co GLOF; extreme precipitation, as represented by the Poge Co GLOF; and extreme temperature, as represented by the Tsho Ga GLOF. [ABSTRACT FROM AUTHOR]

Published

2024

16. Climate change-induced Glacial Lake Outburst Floods in Hunza Valley of Pakistan: an assessment of indigenous farming community perceptions and adaptation.

Author

Hussain, Wahid and Khan, Muhammad Ammad

Subjects

GLACIAL lakes, GLACIAL climates, PHYSIOLOGICAL adaptation, NATURAL disasters, TRADITIONAL knowledge, CLIMATE change, MOUNTAIN soils

Abstract

Climate change is an emerging challenge that is triggering natural variabilities and disasters globally. In Gilgit–Baltistan (GB) region of Pakistan, Glacial Lake Outburst Floods (GLOFs) have been occurring frequently due to glacier surges, increasing the vulnerability of mountain communities, particularly small farmers. This research aims to investigate the climate change-induced GLOFs of the Shishper glacier in Hunza valley of GB with the intent of studying the farming activities; local awareness and perceptions toward climate change; impacts of climate change and GLOFs on agriculture; and adaptation mechanisms based on indigenous knowledge. Mixed-methods research approach was employed for a field survey in two villages inhabited by farmers of the Burusho community. Quantitative data were gathered from a sample of 180 respondents by using a structured questionnaire, whereas field observation coupled with photography and spot interviews were undertaken to accumulate qualitative data. Results revealed that many farmers lost their fertile land, and their crops and fruit orchards were severely damaged as a result of the devastating effects of climate change and recent GLOFs in 2019 and 2020, resulting in low crop yield and agricultural income. Local communities typically respond to GLOFs through self-help strategies and indigenous methods to sustain their livelihoods. However, our findings suggest that current adaptation practices are insufficient in light of rising climate risks. Thus, there is an urgent need to assist mountain communities by providing maximum support and interventions to enhance their resilience to future GLOFs and to increase people's adaptive capacity by strengthening their socioeconomic conditions. [ABSTRACT FROM AUTHOR]

Published

2024

17. Last Glacial Maximum Climate and Glacial Scale Affected by the Monsoon Inferred from Reconstructing the Tianchi Area, Changbai Mountains, Eastern China.

Author

Zhao, He and Zhang, Wei

Subjects

GLACIAL climates, LAST Glacial Maximum, ATMOSPHERIC temperature, MONSOONS, CLIMATE change

Abstract

There are few studies on the climate and glacial scale in the mountains east of the Qinghai–Tibet Plateau. So, we used glacial features to determine the range of the area's paleoglaciers and the equilibrium line altitude (ELA) of theGlA modern and paleoglaciers in the Tianchi area of the Changbai Mountains. Then, the GlaRe toolbox 2015 () was used to reconstruct the surface of the paleoglaciers. The probable air temperature during the glacial advances of the LGM was calculated by applying the P-T and LR models. The results showed the following: (1) the change in ELA is 950 m in the Tianchi area of the Changbai Mountains; (2) glacial coverage in the Tianchi area of the Changbai Mountains during the LGM period was ~27.05 km2 and the glacial volume was ~9.94 km3; and (3) the mean temperature in the Tianchi area of the Changbai Mountains during the LGM was 6.6–9.0 °C lower than today's, and was the principal factor controlling the growth of glaciers. There is a difference in the climate change in monsoon-influenced mountains during the LGM, and this difference may be related to the precipitation in the mountains. [ABSTRACT FROM AUTHOR]

Published

2024

18. Surface buoyancy control of millennial-scale variations of the Atlantic meridional ocean circulation.

Author

Willeit, Matteo, Ganopolski, Andrey, Edwards, Neil R., and Rahmstorf, Stefan

Subjects

ATLANTIC meridional overturning circulation, BUOYANCY, OCEAN temperature, OCEAN circulation, GLACIAL climates, ICE sheets

Abstract

Dansgaard-Oeschger (DO) events are a pervasive feature of glacial climates. It is widely accepted that the associated changes in climate, which are most pronounced in the North Atlantic region, are caused by abrupt changes in the strength and/or latitude reach of the Atlantic meridional overturning circulation (AMOC), possibly originating from spontaneous transitions in the ocean-sea-ice-atmosphere system. Here we use an Earth System Model that produces DO-like events to show that the climate conditions under which millennial-scale AMOC variations occur are controlled by the surface ocean buoyancy flux. In particular, we find that the present day-like convection pattern with deep water formation in the Labrador and Nordic Seas becomes unstable when the buoyancy flux integrated over the northern North Atlantic turns from negative to positive. It is in the proximity of this point that the model produces transitions between different convection patterns associated with strong and weak AMOC states. The buoyancy flux depends on the surface freshwater and heat fluxes and on sea surface temperature through the temperature dependence of the thermal expansion coefficient of seawater. We find that larger ice sheets tend to stabilize convection by decreasing the net freshwater flux while CO2-induced cooling decreases buoyancy loss and destabilizes convection. These results help to explain the conditions under which DO events appear, and are a step towards an improved understanding of the mechanisms of abrupt climate changes. [ABSTRACT FROM AUTHOR]

Published

2024

19. Glacial Lake Changes and Risk Assessment in Rongxer Watershed of China–Nepal Economic Corridor.

Author

Zhang, Sihui, Nie, Yong, and Zhang, Huayu

Subjects

*GLACIAL lakes, *RISK assessment, *HAZARD mitigation, *GLACIAL climates, *ALPINE regions, *NEPAL Earthquake, 2015

Abstract

Glacial lake outburst floods (GLOFs) are one of the most severe disasters in alpine regions, releasing a large amount of water and sediment that can cause fatalities and economic loss as well as substantial damage to downstream infrastructures. The risk of GLOFs in the Himalayas is exacerbated by glacier retreat caused by global warming. Critical economic corridors, such as the Rongxer Watershed, are threatened by GLOFs, but the lack of risk assessment specific to the watershed hinders hazard prevention. In this study, we propose a novel model to evaluate the risk of GLOF using a combination of remote sensing observations, GIS, and hydrological models and apply this model to the GLOF risk assessment in the Rongxer Watershed. The results show that (1) the area of glacial lakes in the Rongxer Watershed increased by 31.19% from 11.35 km2 in 1990 to 14.89 km2 in 2020, and (2) 18 lakes were identified as potentially dangerous glacial lakes (PDGLs) that need to be assessed for the GLOF risk, and two of them were categorized as very high risk (Niangzongmajue and Tsho Rolpa). The proposed model was robust in a GLOF risk evaluation by historical GLOFs in the Himalayas. The glacial lake data and GLOF risk assessment model of this study have the potential to be widely used in research on the relationships between glacial lakes and climate change, as well as in disaster mitigation of GLOFs. [ABSTRACT FROM AUTHOR]

Published

2024

20. Paleo±Dust: quantifying uncertainty in paleo-dust deposition across archive types.

Author

Cosentino, Nicolás J., Torre, Gabriela, Lambert, Fabrice, Albani, Samuel, De Vleeschouwer, François, and Bory, Aloys J.-M.

Subjects

*DUST, *MINERAL dusts, *LAST Glacial Maximum, *GLACIAL climates, *HYDROLOGIC cycle, *MARINE sediments

Abstract

Mineral dust aerosol concentrations in the atmosphere varied greatly on glacial–interglacial timescales. The greatest changes in global dust activity occurred in response to changes in orbital parameters (which affect dust emission intensity through glacial activity) and the lifetime of dust in the atmosphere (caused by changes in the global hydrological cycle). Long-term changes in the surface dust deposition rate are registered in geological archives such as loess, peats, lakes, marine sediments, and ice. Data provided by these archives are crucial for guiding simulations of dust and for better understanding the natural global dust cycle. However, the methods employed to derive paleo-dust deposition rates differ markedly between archives and are subject to different sources of uncertainty. Here, we present Paleo ± Dust, an updated compilation of bulk and <10 µ m paleo-dust deposition rates with quantitative 1σ uncertainties that are inter-comparable among archive types. Paleo ± Dust incorporates a total of 285 pre-industrial Holocene (pi-HOL) and 209 Last Glacial Maximum (LGM) dust flux constraints from studies published until December 2022, including, for the first time, peat records. We also recalculate previously published dust fluxes to exclude data from the last deglaciation and thus obtain more representative constraints for the last pre-industrial interglacial and glacial end-member climate states. Based on Paleo ± Dust, the global LGM:pi -HOL ratio of <10 µ m dust deposition rates is 3.1 ± 0.7 (1σ). We expect Paleo ± Dust to be of use for future paleoclimate dust studies and simulations using Earth system models of high to intermediate complexity. Paleo ± Dust is publicly accessible at 10.1594/PANGAEA.962969 (Cosentino et al., 2024). [ABSTRACT FROM AUTHOR]

Published

2024

21. Genetic structure of two endangered shrubs in Central Asia and northwestern China and the implications for conservation.

Author

Zhuo, Li, Su, Zhihao, Zhao, Huixin, Jiang, Xiaolong, and Zhang, Lixin

Subjects

*SENIOR leadership teams, *GENETIC variation, *SINGLE nucleotide polymorphisms, *GLACIAL climates, *GERMPLASM, *ENDANGERED plants

Abstract

Helianthemum songaricum and H. ordosicum are two shrubs disjunctively distributed in Central Asia and northwestern China. For conservation purposes, we used genotyping by sequencing (GBS) to investigate the genetic diversity and genetic structure of their populations. Based on the GBS data, H. songaricum populations showed considerable genetic differences from H. ordosicum populations. Helianthemum songaricum populations also showed a stronger population genetic structure within the isolated valleys in the Tianshan Mountains than was seen in previous studies. We speculated that the two species may represent two cotemporal migration events between the Middle East and Central Asia/Ordos Plateau since the early Pliocene. Due to the intense uplift of the Tianshan Mountains in the late Pliocene, populations of H. songaricum were isolated in different valleys. Subsequently, the cold glacial climate during the Pleistocene intensified the in situ intraspecific differentiation of the species. Based on our single nucleotide polymorphism data, we propose habitat damage by anthropological activities, where the two species inhabit should be urgently prohibited by executive management. In addition, a nursery for germplasm resources should be urgently set up to culture adequate progenies for the purpose of expanding the populations. [ABSTRACT FROM AUTHOR]

Published

2024

22. Last Glacial Maximum climate and atmospheric circulation over the Australian region from climate models.

Author

Du, Yanxuan, Brown, Josephine R., and Sniderman, J. M. Kale

Subjects

ATMOSPHERIC circulation, ATMOSPHERIC models, GLACIAL climates, WESTERLIES, LAST Glacial Maximum, PRECIPITATION anomalies

Abstract

The Last Glacial Maximum (LGM; ∼21 kyr ago) was the most recent time that the Earth experienced global maximum ice volume and minimum eustatic sea level. The climate changes over the Australian region at the LGM remain uncertain, including the extent of cooling in the arid interior, changes in the regional atmospheric circulations such as the tropical monsoon and mid-latitude westerlies, and changes in the balance between precipitation and evaporation. In this study, 13 climate model simulations that were included in the Paleoclimate Modelling Intercomparison Project (PMIP) Phases 3 and 4 are used to investigate regional climate (temperature, precipitation, and wind) over Australia at the LGM. The model simulations are compared with existing proxy records and other modelling studies. All models simulate consistent annual and seasonal cooling over the Australian region (defined as 0–45° S, 110–160° E) at the LGM compared to pre-industrial, with a multi-model mean 2.9 °C decrease in annual average surface air temperature over land at the LGM compared to pre-industrial. Models simulate a range of LGM precipitation anomalies over the region. Simulated precipitation changes over tropical Australasia appear to be driven by changes in circulation and moisture transport, which vary greatly between models. Surface moisture balance calculated from precipitation minus evaporation shows little change over much of the Australian land area at the LGM. Changes in the strength and position of the mid-latitude westerlies are uncertain, with wide model disagreement. These results indicate that climate model simulations do not show a robust response in either tropical or mid-latitude circulation to LGM boundary conditions, suggesting that caution is required when interpreting model output in this region. Further analysis based on model evaluation and quantitative model–proxy comparison is required to better understand the drivers of LGM climate and atmospheric circulation changes in this region. [ABSTRACT FROM AUTHOR]

Published

2024

23. Surface mass balance and climate of the Last Glacial Maximum Northern Hemisphere ice sheets: simulations with CESM2.1.

Author

Bradley, Sarah L., Sellevold, Raymond, Petrini, Michele, Vizcaino, Miren, Georgiou, Sotiria, Zhu, Jiang, Otto-Bliesner, Bette L., and Lofverstrom, Marcus

Subjects

LAST Glacial Maximum, ICE sheets, GLACIAL climates, SEA ice, SNOW accumulation

Abstract

The Last Glacial Maximum (LGM, from ∼26 to 20 ka BP) was the most recent period with large ice sheets in Eurasia and North America. At that time, global temperatures were 5–7 ∘ C lower than today, and sea level ∼125 m lower. LGM simulations are useful to understand earth system dynamics, including climate–ice sheet interactions, and to evaluate and improve the models representing those dynamics. Here, we present two simulations of the Northern Hemisphere ice sheet climate and surface mass balance (SMB) with the Community Earth System Model v2.1 (CESM2.1) using the Community Atmosphere Model v5 (CAM5) with prescribed ice sheets for two time periods that bracket the LGM period: 26 and 21 ka BP. CESM2.1 includes an explicit simulation of snow/firn compaction, albedo, refreezing, and direct coupling of the ice sheet surface energy fluxes with the atmosphere. The simulated mean snow accumulation is lowest for the Greenland and Barents–Kara Sea ice sheets (GrIS, BKIS) and highest for British and Irish (BIIS) and Icelandic (IcIS) ice sheets. Melt rates are negligible for the dry BKIS and GrIS, and relatively large for the BIIS, North American ice sheet complex (NAISC; i.e. Laurentide, Cordilleran, and Innuitian), Scandinavian ice sheet (SIS), and IcIS, and are reduced by almost a third in the colder (lower temperature) 26 ka BP climate compared with 21 ka BP. The SMB is positive for the GrIS, BKIS, SIS, and IcIS during the LGM (26 and 21 ka BP) and negative for the NAISC and BIIS. Relatively wide ablation areas are simulated along the southern (terrestrial), Pacific and Atlantic margins of the NAISC, across the majority of the BIIS, and along the terrestrial southern margin of the SIS. The integrated SMB substantially increases for the NAISC and BIIS in the 26 ka BP climate, but it does not reverse the negative sign. Summer incoming surface solar radiation is largest over the high interior of the NAISC and GrIS, and minimum over the BIIS and southern margin of NAISC. Summer net radiation is maximum over the ablation areas and minimum where the albedo is highest, namely in the interior of the GrIS, northern NAISC, and all of the BKIS. Summer sensible and latent heat fluxes are highest over the ablation areas, positively contributing to melt energy. Refreezing is largest along the equilibrium line altitude for all ice sheets and prevents 40 %–50 % of meltwater entering the ocean. The large simulated melt for the NAISC suggests potential biases in the climate simulation, ice sheet reconstruction, and/or highly non-equilibrated climate and ice sheet at the LGM time. [ABSTRACT FROM AUTHOR]

Published

2024

24. The response of glaciers and glacial lakes to climate change in the Southeastern Tibetan Plateau over the past three decades.

Author

Dou, Xiangyang, Fan, Xuanmei, Wang, Xin, Fang, Chengyong, Lovati, Marco, and Zou, Chengbin

Subjects

GLACIAL lakes, GLACIAL climates, GLACIERS, RANDOM forest algorithms, CLIMATE change, CLIMATE change denial

Abstract

With global warming, changes in glaciers and glacial lakes on the Tibetan Plateau call for a serious inspection. The Southeastern Tibetan Plateau (SETP) is a typical monsoonal marine glacier area that is extremely vulnerable to climate change. It is affected by both humid and warm Indian Ocean currents. Outlines of glaciers and glacial lakes in SETP have been extracted from Landsat satellite images with an automatic extraction method based on image compositing with Google Earth Engine and Random Forest algorithm. Alongside the outlines, meteorological data have been collected from 1990 to 2021. The results show that since 1990 the glacier area of SETP has retreated by about 2165.33 km2 (~25.28%), the glacial lake area has increased by about 36.41 km2 (~21.45%), and their number has increased by 477 (~27.32%). The reliability and scientific validity of this study is proven by comparison with existing glacier inventories. By analyzing the meteorological data, the inverse correlation between the glacier area and temperature has been found. Despite decreases in cumulative precipitation, the glacial lake level rise and consequent area expansion have been observed. A fitting equation for the response pattern of glacier changes to temperature and precipitation change is presented and will provide a basis for future studies. [ABSTRACT FROM AUTHOR]

Published

2023

25. Tropical Precipitation Woes in the Community Earth System Model Version 2.

Author

Lofverstrom, Marcus and Zhu, Jiang

Subjects

*LAST Glacial Maximum, *INTERTROPICAL convergence zone, *GLACIAL climates, *CLIMATOLOGY, *ATMOSPHERIC models

Abstract

The newly developed paleo‐climate calibrated Community Earth System Model, version 2 (pCESM2) simulates a more realistic global temperature response to external forcing compared to the standard CESM2. Here we show that the code modifications in pCESM2 result in increased atmospheric convection and a northward shift of the Atlantic and eastern Pacific Intertropical Convergence Zones. These changes are exacerbated under Last Glacial Maximum forcing, resulting in tropical precipitation changes that are inconsistent with both proxy data evidence and simulations with other contemporary models. Similar model‐data disagreements are also present in the standard CESM2. Thus, more work is needed to improve the simulated Last Glacial Maximum hydroclimate response in CESM2. We further suggest that well‐constrained paleo climates should be given a larger emphasis in model development more broadly, as these climates can help identify issues with model parameterizations under altered forcing and thus improve the fidelity of simulations of past, present, and future climates. Plain Language Summary: Climate models are a central tool in modern climate science. The realism of any given model is however largely determined by a delicate calibration of the simulated physics in order to capture the observed features of the climate system. A recent study showed that the newly developed paleo‐climate calibrated Community Earth System Model, version 2 greatly improves the global temperature response in simulations of the Last Glacial Maximum compared to the standard model. This was achieved by altering properties of cloud processes in the model code. Here we show that the same changes that improve the overall model sensitivity help exaggerate issues with the distribution of tropical precipitation; similar precipitation issues are also present in the standard model. Understanding the connections between model sensitivity, cloud properties, and precipitation distribution is key for developing a model that can realistically simulate past, present, and future climates. Key Points: The Last Glacial Maximum climate simulated by the paleo‐climate calibrated Community Earth System Model, version 2 (CESM2) (pCESM2) is more realistic than the standard CESM2Both the pCESM2 and the standard CESM2 have large intertropical convergence zone precipitation biases under Last Glacial Maximum forcingSimulations of well‐constrained past climates can help inform model parameterizations and assess model performance [ABSTRACT FROM AUTHOR]

Published

2023

26. Late Pleistocene Evolution of Tides and Tidal Dissipation.

Author

Wilmes, S.‐B., Pedersen, V. K., Schindelegger, M., and Green, J. A. M.

Subjects

OCEANIC mixing, PLEISTOCENE Epoch, GLACIAL climates, ICE sheets, SEA ice, LAST Glacial Maximum

Abstract

Studies of the Last Glacial Maximum (LGM; 26.5–19 ka) tides showed strong enhancements in open ocean tidal amplitudes and dissipation rates; however, changes prior to the LGM remain largely unexplored. Using two different ice sheet and sea level reconstructions, we explicitly simulate the evolution of the leading semi‐diurnal and diurnal tidal constituents (M2, S2, K1, and O1) over the last glacial cycle with a global tide model. Both sets of simulations show that global changes, dominated by the Atlantic, take place for the semi‐diurnal constituents, while changes for the diurnal constituents are mainly regional. Irrespective of the reconstruction, open ocean dissipation peaks during the sea level lowstands of MIS 2 (∼20 ka) and MIS 4 (∼60 ka), although dissipation values prior to MIS 2 are sensitive to differences in reconstructed ice sheet extent. Using the statistically significant relationship between global mean sea level and dissipation, we apply regression analysis to infer open ocean and shelf dissipation, respectively, over the last four glacial cycles back to 430 ka. Our analysis shows that open ocean tidal energy was probably increased for most of this period, peaking during glacial maxima, and returning to near‐present‐day values during interglacials. Due to tidal resonance during glacial phases, small changes in bathymetry could have caused large changes in tidal amplitudes and dissipation, emphasizing the need for accurate ice margin reconstructions. During glacial phases, once global mean sea level decreased by more than ∼100 m, the amount of open ocean tidal energy available for ocean mixing approximately doubled. Key Points: Tides over the last glacial cycle are explicitly modeled, and tidal dissipation ranging back to 430 ka is inferred with regression analysisEnhanced open ocean dissipation (1.8–2.5 × 5 present day) occurred during glacial maxima, and near‐present‐day values during interglacialsPeak glacial M2 tidal dynamics are very sensitive to changes in ice sheet extent, which may influence ocean mixing and glacial climate [ABSTRACT FROM AUTHOR]

Published

2023

27. Unraveling the complexities of the Last Glacial Maximum climate: the role of individual boundary conditions and forcings.

Author

Shi, Xiaoxu, Werner, Martin, Yang, Hu, D'Agostino, Roberta, Liu, Jiping, Yang, Chaoyuan, and Lohmann, Gerrit

Subjects

LAST Glacial Maximum, ATLANTIC meridional overturning circulation, GLACIAL climates, EL Nino, ICE sheets

Abstract

In order to quantify the relative importance of individual boundary conditions and forcings, including greenhouse gases, ice sheets, and Earth's orbital parameters, on determining Last Glacial Maximum (LGM) climate, we have performed a series of LGM experiments using a state-of-the-art climate model AWI-ESM, in which different combinations of boundary conditions and forcings have been applied following the protocol of Paleoclimate Modelling Intercomparison Project phase 4 (PMIP4). In good agreement with observational proxy records, a general colder and drier climate is simulated in our full-forced LGM experiment as compared to the present-day simulation. Our simulated results from non-full-forced sensitivity simulations reveal that both the greenhouse gases and ice sheets play a major role in defining the anomalous LGM surface temperature compared to today. Decreased greenhouse gases in LGM as compared to present day leads to a non-uniform global cooling with polar amplification effect. The presence of LGM ice sheets favors a warming over the Arctic and northern Atlantic oceans in boreal winter, as well as a cooling over regions with the presence of ice sheets. The former is induced by a strengthening in the Atlantic meridional overturning circulation (AMOC) transporting more heat to high latitudes, whilst the latter is due to the increased surface albedo and elevation of ice sheets. We find that the Northern Hemisphere monsoon precipitation is influenced by the opposing effects of LGM greenhouse gases and ice sheets. Specifically, the presence of ice sheets leads to significant drying in the Northern Hemisphere monsoon regions, while a reduction in greenhouse gases results in increased monsoon rainfall. Based on our model results, continental ice sheets exert a major control on atmospheric dynamics and the variability of El Niño–Southern Oscillation (ENSO). Moreover, our analysis also implies a nonlinearity in climate response to LGM boundary conditions and forcings. [ABSTRACT FROM AUTHOR]

Published

2023

28. Genomic analysis reveals a cryptic pangolin species.

Author

Tong-Tong Gu, Hong Wu, Feng Yang, Gaubert, Philippe, Heighton, Sean P., Yeyizhou Fu, Ke Liu, Shu-Jin Luo, Hua-Rong Zhang, Jing-Yang Hu, and Li Yu

Subjects

*GENOMICS, *GENETIC load, *GLACIAL climates, *EFFECT of human beings on climate change, *ENDANGERED species

Abstract

Eight extant species of pangolins are currently recognized. Recent studies found that two mitochondrial haplotypes identified in confiscations in Hong Kong could not be assigned to any known pangolin species, implying the existence of a species. Here, we report that two additional mitochondrial haplotypes identified in independent confiscations from Yunnan align with the putative species haplotypes supporting the existence of this mysterious species/population. To verify the new species scenario we performed a comprehensive analysis of scale characteristics and 138 whole genomes representing all recognized pangolin species and the cryptic new species, 98 of which were generated here. Our morphometric results clearly attributed this cryptic species to Asian pangolins (Manis sp.) and the genomic data provide robust and compelling evidence that it is a pangolin species distinct from those recognized previously, which separated from the Philippine pangolin and Malayan pangolin over 5 Mya. Our study provides a solid genomic basis for its formal recognition as the ninth pangolin species or the fifth Asian one, supporting a new taxonomic classification of pangolins. The effects of glacial climate changes and recent anthropogenic activities driven by illegal trade are inferred to have caused its population decline with the genomic signatures showing low genetic diversity, a high level of inbreeding, and high genetic load. Our finding greatly expands current knowledge of pangolin diversity and evolution and has vital implications for conservation efforts to prevent the extinction of this enigmatic and endangered species from the wild. [ABSTRACT FROM AUTHOR]

Published

2023

29. Micrometeorological Analysis and Glacier Ablation Simulation in East Kunlun.

Author

Wang, Weisheng, Sun, Meiping, Che, Yanjun, Yao, Xiaojun, Zhang, Mingjun, and Niu, Shuting

Subjects

ALPINE glaciers, ABLATION (Glaciology), TEMPERATURE lapse rate, GLACIAL climates, METEOROLOGICAL stations, EXTREME environments, WESTERLIES

Abstract

Worldwide, there are great challenges for meteorological monitoring and glacier ablation monitoring in high-altitude mountain areas. It is often difficult to capture fine-scale climate and glacial changes in high-altitude mountainous areas due to the harsh natural environment and the extreme lack of observational sites. Based on high-altitude meteorological stations erected on the eastern shore of Aqikkule Lake (AQK) and at the terminus of Shenshechuan Glacier (SSG), as well as on mass balance data from SSG, the characteristics and correlation of temperature, solar radiation, relative humidity, precipitation, wind speed and direction of the two regions, and the mass balance in the ablation area of SSG from 30 May 2022 to 18 May 2023 were analyzed, and the average melting depth of SSG was simulated. The results indicate the following: (1) The average annual temperature of AQK and the terminus of SSG is −3.7 °C and −7.7 °C, respectively, and the vertical lapse rate of temperature in the summer half of the year is greater than that in the winter half of the year. Precipitation timing has a great influence on daily temperature differences. (2) Precipitation in both places is concentrated in summer; the glaciers in this area are of the summer recharge type, and precipitation has a significant reducing effect on the solar incident radiation and increases the relative humidity in this region. (3) AQK and SSG both have local circulation development, in the area of AQK all year round due to the lake effect, while the terminus of SSG only has the development of valley winds in the summer, being controlled in the winter by the westerly wind belt. (4) The average mass balance value of the ablation area of SSG was −1786 mm as measured by the range poles method. The average annual ablation depth of SSG simulated by using the empirical formula was 587–597 mm, which is not large compared with other glacier areas in the Tibetan Plateau, and it has the characteristics of typical continental-type glaciers. [ABSTRACT FROM AUTHOR]

Published

2023

30. Global reorganization of atmospheric circulation during Dansgaard–Oeschger cycles.

Author

Fohlmeister, Jens, Sekhon, Natasha, Columbu, Andrea, Vettoretti, Guido, Weitzel, Nils, Rehfeld, Kira, Veiga-Pires, Cristina, Ben-Yami, Maya, Marwan, Norbert, and Boers, Niklas

Subjects

*ATMOSPHERIC circulation, *CLIMATE change, *ATMOSPHERIC models, *ICE cores, *GLACIAL climates

Abstract

Ice core records from Greenland provide evidence for multiple abrupt cold–warm– cold events recurring at millennial time scales during the last glacial interval. Although climate variations resembling Dansgaard–Oeschger (DO) oscillations have been identified in climate archives across the globe, our understanding of the climate and ecosystem impacts of the Greenland warming events in lower latitudes remains incomplete. Here, we investigate the influence of DO-cold-to-warm transitions on the global atmospheric circulation pattern. We comprehensively analyze δ18O changes during DO transitions in a globally distributed dataset of speleothems and set those in context with simulations of a comprehensive high-resolution climate model featuring internal millennial-scale variations of similar magnitude. Across the globe, speleothem δ18O signals and model results indicate consistent large-scale changes in precipitation amount, moisture source, or seasonality of precipitation associated with the DO transitions, in agreement with northward shifts of the Hadley circulation. Furthermore, we identify a decreasing trend in the amplitude of DO transitions with increasing distances from the North Atlantic region. This provides quantitative observational evidence for previous suggestions of the North Atlantic region being the focal point for these archetypes of past abrupt climate changes. [ABSTRACT FROM AUTHOR]

Published

2023

31. Antarctic evidence for an abrupt northward shift of the Southern Hemisphere westerlies at 32 ka BP.

Author

Venugopal, Abhijith U., Bertler, Nancy A. N., Severinghaus, Jeffrey P., Brook, Edward J., Cortese, Giuseppe, Lee, James E., Blunier, Thomas, Mayewski, Paul A., Kjær, Helle A., Carter, Lionel, Weber, Michael E., Levy, Richard H., Pyne, Rebecca L., and Vandergoes, Marcus J.

Subjects

ICE cores, UPWELLING (Oceanography), ATMOSPHERIC carbon dioxide, GLACIAL climates, ANTARCTIC ice, WESTERLIES

Abstract

High-resolution ice core records from coastal Antarctica are particularly useful to inform our understanding of environmental changes and their drivers. Here, we present a decadally resolved record of sea-salt sodium (a proxy for open-ocean area) and non-sea salt calcium (a proxy for continental dust) from the well-dated Roosevelt Island Climate Evolution (RICE) core, focusing on the time period between 40–26 ka BP. The RICE dust record exhibits an abrupt shift towards a higher mean dust concentration at 32 ka BP. Investigating existing ice-core records, we find this shift is a prominent feature across Antarctica. We propose that this shift is linked to an equatorward displacement of Southern Hemisphere westerly winds. Subsequent to the wind shift, data suggest a weakening of Southern Ocean upwelling and a decline of atmospheric CO2 to lower glacial values, hence making this shift an important glacial climate event with potentially important insights for future projections. Antarctic ice core records provide insights into past environmental conditions. Here, an abrupt, synchronous increase in dust from ice cores in Antarctica is identified that suggests a sudden equatorward shift of westerly winds and coincides with a reduction in atmospheric CO2. [ABSTRACT FROM AUTHOR]

Published

2023

32. Global Climate Classification and Comparison to Mid-Holocene and Last Glacial Maximum Climates, with Added Aridity Information and a Hypertropical Class.

Author

Hanberry, Brice B.

Subjects

GLACIAL climates, CLIMATE change detection, GLOBAL environmental change, LAST Glacial Maximum, TROPICAL conditions, CLIMATE change

Abstract

Climate classifications supply climate visualization with inference about general vegetation types. The Köppen classification system of thermal classes and an arid class is widely used, but options are available to strengthen climate change detection. For this study, I incorporated temperature and aridity information into all climate classes to isolate climate change, added a hypertropical class to better detect warming and drying in tropical zones, and developed a consistent ruleset of thermal classes with one temperature variable for streamlined application, yet maintained primary Köppen thermal classes. I compared climate currently to 6000 years ago (ka; Mid-Holocene) and 22 ka (Last Glacial Maximum) worldwide. Growing degree days > 0 °C was the most efficient variable for modeling thermal classes. Climate classes based on growing degree days matched 86% of Köppen thermal classes. Current climate shared 80% and 23% of class assignments with the Mid-Holocene and Last Glacial Maximum, respectively, with dry conditions shifting to the tropical and hypertropical classes under current climate. Contributing to our understanding of global environmental change, this classification demonstrated that the hypertropical class experienced the greatest change in area since 6 ka and the second greatest change in area since 22 ka, and the greatest increase in percentage arid classes during both intervals. The added hypertropical class with aridity information delivered sensitive detection of warming and drying for relevant climate classes under climate change. [ABSTRACT FROM AUTHOR]

Published

2023

33. Holocene deglaciation of the northern Fildes Peninsula, King George Island, Antarctica.

Author

Oliva, Marc, Palacios, David, Fernández‐Fernández, José M., Fernandes, Marcelo, Schimmelpfennig, Irene, Vieira, Gonçalo, Antoniades, Dermot, Pérez‐Alberti, Augusto, and García‐Oteyza, Julia

Subjects

GLACIAL melting, LITTLE Ice Age, LAST Glacial Maximum, HOLOCENE Epoch, GLACIAL climates, ENVIRONMENTAL history

Abstract

The timing and magnitude of Holocene glacial oscillations in most currently ice‐free areas of Antarctica remain unknown. This work focuses on the recent deglaciation in the northern sector of the Fildes Peninsula, King George Island, northern Antarctic Peninsula. The ice cap covering ca. 90% of the island has receded since the Last Glacial Maximum and exposed ca. 29 km2 of ice‐free land. We reconstruct its glacial history based on a dataset of 12 36Cl exposure ages obtained through cosmic‐ray exposure (CRE) dating of moraine boulders, polished surfaces and erratic boulders surrounding the peninsula's northern plateau. Results reveal that the deglaciation of the northern Fildes Peninsula took place during the Holocene Thermal Maximum at 7–6 ka, when warm conditions promoted a massive glacial retreat. The present arrangement of ice‐free areas was in place by 6 ka. Small cirque moraines suggest the subsequent occurrence of favourable climate conditions for glacial expansion fed by intense snow deflation at 4.6 and 1 ka at the foot of the northern plateau. The deglaciation pattern of the Fildes Peninsula resulted from the combined shrinkage of different ice masses, rather than of the long‐term retreat of the King George Ice Cap. No evidence of glacier expansion during more recent cold periods (i.e. the Little Ice Age) was found. These results fit well with regional deglacial histories inferred from lacustrine sediments and raised beaches and complement the existing chronological framework to help better understand the peninsula's Holocene geoecological dynamics. [ABSTRACT FROM AUTHOR]

Published

2023

34. Surface mass balance and climate of the Last Glacial Maximum northern hemisphere ice sheets: simulations with CESM2.1.

Author

Bradley, Sarah Louise, Sellevold, Raymond, Petrini, Michele, Vizcaino, Miren, Georgiou, Sotiria, Zhu, Jiang, Otto-Bliesner, Bette L., and Lofverstrom, Marcus

Subjects

LAST Glacial Maximum, ICE sheets, GLACIAL climates, SEA ice, SOLAR radiation

Abstract

The Last Glacial Maximum (LGM, from ~26 to 20 ka BP) was the most recent period with large ice sheets in Eurasia and North America. At that time, global temperatures were 5–7 °C colder than today, and sea level ~125 m lower. LGM simulations are useful to understand Earth System dynamics including climate-ice sheet interactions, and to evaluate and improve the models representing those. Here, we present two simulations of the Northern Hemisphere ice sheet climate and surface mass balance with the CESM2.1(CAM5) with prescribed ice sheets for two time periods that bracket the LGM period: 26 ka and 21 ka BP. CESM2.1 includes explicit simulation of snow/firn compaction, albedo, refreezing, and direct coupling of ice sheet surface energy fluxes with the atmosphere. The simulated mean snowfall accumulation is lowest for the Greenland and Barents-Kara Sea Ice Sheets (GrIS, BKIS) and highest for British and Irish (BIIS) and Icelandic (IcIS) ice sheets. Melt rates are negligible for the dry BKIS and GrIS, and relatively large for the BIIS, NAISC, SIS and IcIS, and are reduced by almost a third in the colder 26 ka BP climate compared with 21 ka BP. The surface mass balance (SMB) is positive for the GrIS, BKIS, SIS and IcIS during the LGM (26 ka and 21 ka BP), and negative for the NAISC and BIIS. Relatively wide ablation areas are simulated along the southern (terrestrial), Pacific and Atlantic margins of the NAISC, across all of the BIIS surface, and along the terrestrial southern margin of the SIS. For 26 ka BP climate the integrated SMB substantially increases for the NAISC and BIIS, but it does not reverse the negative sign. Summer incoming solar radiation at the surface is largest over the high interior of the NAISC and GrIS, and minimum over the BIIS and southern margin of NAISC. Summer net radiation is maximum over the ablation areas and minimum where the albedo is highest, namely in the interior of the GrIS, northern NAISC and all of the BKIS. Summer sensible and latent heat fluxes are highest over the ablation areas, positively contributing to melt energy. Refreezing is largest along the equilibrium line for all ice sheets, and prevents 40–50 % of meltwater entering the ocean. Our SMB results are in qualitative agreement with the climatic variability across the different northern hemisphere ice sheets. The large, simulated melt for the NAISC suggests potential biases in the climate simulation, ice sheet reconstruction, and/or highly non-equilibrated climate and ice sheet at the LGM time. [ABSTRACT FROM AUTHOR]

Published

2023

35. Paleo±Dust: Quantifying uncertainty in paleo-dust deposition across archive types.

Author

Cosentino, Nicolás Juan, Torre, Gabriela, Lambert, Fabrice, Albani, Samuel, Vleeschouwer, François De, and Bory, Aloys

Subjects

DUST, MINERAL dusts, LAST Glacial Maximum, GLACIAL climates, HYDROLOGIC cycle, MARINE sediments

Abstract

Mineral dust aerosol concentrations in the atmosphere varied greatly on glacial-interglacial timescales. The greatest changes in global dust activity occurred in response to changes in orbital parameters that affect dust emission intensity through glacial activity, and dust lifetime in the atmosphere through changes in the global hydrological cycle. Long-term changes in surface dust deposition rate are registered in geological archives such as loess, peats, lakes, marine sediments, and ice. Data provided by these archives is crucial for guiding simulations of dust, and for better understanding the natural global dust cycle. However, the methods employed to derive paleo-dust deposition rates differ markedly between archives and are subject to different sources of uncertainty. Here, we present Paleo±Dust, an updated compilation of bulk and <10-µm paleo-dust deposition rate with quantitative 1-σ uncertainties that are inter-comparable among archive types. Paleo±Dust incorporates a total of 284 pre-industrial Holocene (pi-HOL) and 208 Last Glacial Maximum (LGM) dust flux constraints from studies published until December 2022, including for the first time peat records. We also recalculate previously published dust fluxes to exclude data from the last deglaciation and thus obtain more representative constraints for the last pre-industrial interglacial and glacial end-member climate states. Based on Paleo±Dust, the global LGM:pi-HOL ratio of <10-µm dust deposition rate is 3.1 ± 0.8 (1σ). We expect Paleo±Dust to be of use for future paleoclimate dust studies and simulations using Earth system models of high to intermediate complexity. [ABSTRACT FROM AUTHOR]

Published

2023

36. Contemporary biodiversity pattern is affected by climate change at multiple temporal scales in steppes on the Mongolian Plateau.

Author

Li, Zijing, Li, Zhiyong, Tong, Xuze, Dong, Lei, Zheng, Ying, Zhang, Jinghui, Miao, Bailing, Wang, Lixin, Zhao, Liqing, Wen, Lu, Han, Guodong, Li, Frank Yonghong, and Liang, Cunzhu

Subjects

LAST Glacial Maximum, CLIMATE change, GLACIAL climates, BIODIVERSITY, GRASSLANDS, STEPPES, ECOSYSTEMS

Abstract

Present and historical climate conditions jointly determine contemporary biodiversity patterns and ecosystem functions. However, it remains unclear how contemporary climate and paleoclimate changes together affect the three dimensions of biodiversity (i.e., taxonomic diversity, functional diversity and phylogenetic diversity) and their relationship with ecosystem functions. Here, we assess the impact of current climate, paleoclimate and its anomalies on contemporary biodiversity and ecosystem functions. We estimated the taxonomic, functional and phylogenetic diversity of grassland on the Mongolian Plateau using vegetation survey data and trait information. We then used random forest and structural equation models to assess the relative importance of the present, the Mid-Holocene and the Last Glacial Maximum climate as well as paleoclimate changes as determinants of diversity and aboveground biomass. Our results showed that paleoclimate changes and modern climate jointly determined contemporary biodiversity patterns, while community biomass was mainly affected by modern climate, namely the aridity index. Modern aridity and temperature were two major influences on all three dimensions of biodiversity. Mid-Holocene climate anomalies had a strong effect on species richness and phylogenetic diversity, while functional diversity had mainly been affected by temperature anomalies since the Last Glacial Maximum. These findings suggest that contemporary biodiversity patterns may be affected by processes at divergent temporal scales. Our results show that simultaneously exploring the response of the three dimensions of biodiversity in different periods of climate change and the theoretical framework for its impact on community biomass is helpful to provide a more comprehensive understanding of patterns of biodiversity and its relationship with ecosystem functions. [ABSTRACT FROM AUTHOR]

Published

2023

37. The deglaciation of Upernavik trough, West Greenland, and its Holocene sediment infill: processes and provenance.

Author

Weiser, Jens, Titschack, Jürgen, and Hebbeln, Dierk

Subjects

*GLACIAL climates, *HOLOCENE Epoch, *GREENLAND ice, *SEDIMENTS, *ICE sheets

Abstract

Under glacial climates, continental ice sheets such as, e.g., the Greenland Ice Sheet, extended onto the continental shelves and often carved out deep cross‐shelf troughs. The sedimentary infill of such troughs commonly is a product of the complex interactions between the ice sheets, largely driving sediment input into the ocean, and the surrounding water masses. Off West Greenland, research has focused on the Disko and Uummannaq troughs, leaving the northerly adjacent Upernavik trough relatively understudied. Hence, neither the chronology of deglaciation nor the details of its postglacial infill are sufficiently well understood. Here, we combine computed tomography image‐derived information with geochemical and granulometric data from four sediment cores recovered from the Upernavik trough that point to (i) deglaciation of the mid‐shelf probably around 13.4 cal. ka BP that was most likely driven by a northward advection of warmer Atlantic waters during the Bølling–Allerød, (ii) the presence of widespread mass wasting around 8 cal. ka BP on the inner shelf and (iii) the complex interplay between various modes of sediment input, transport and deposition under hemipelagic sedimentation afterwards. While this interplay complicates provenance studies, we identify two major sediment delivery mechanisms that control transport and deposition from four sediment source areas. Through the Early Holocene the relative contributions of sediments from the various sources changed from a predominantly local origin to more southerly sources, mainly driven by decreasing input from the local sources. The integration of relative sediment source contributions with varying sedimentation rates challenges previous studies postulating intensified sediment delivery from the south through a greater influence of the West Greenland Current and highlights the need for the integration of sediment input and transport mechanisms into provenance studies in the area. [ABSTRACT FROM AUTHOR]

Published

2023

38. Stable stadial and interstadial states of the last glacial's climate identified in a combined stable water isotope and dust record from Greenland.

Author

Riechers, Keno, Rydin Gorjão, Leonardo, Hassanibesheli, Forough, Lind, Pedro G., Witthaut, Dirk, and Boers, Niklas

Subjects

*GLACIAL climates, *ICE cores, *STABLE isotopes, *GREENLAND ice, *ATMOSPHERIC circulation, *STOCHASTIC processes, *DUST, *GLACIERS

Abstract

During the last glacial interval, the Northern Hemisphere climate was punctuated by a series of abrupt changes between two characteristic climate regimes. The existence of stadial (cold) and interstadial (milder) periods is typically attributed to a hypothesised bistability in the glacial North Atlantic climate system, allowing for rapid transitions from the stadial to the interstadial state – the so-called Dansgaard–Oeschger (DO) events – and more gradual yet still fairly abrupt reverse shifts. The physical mechanisms driving these regime transitions remain debated. DO events are characterised by substantial warming over Greenland and a reorganisation of the Northern Hemisphere atmospheric circulation, which are evident from concomitant shifts in the δ18 O ratios and dust concentration records from Greenland ice cores. Treating the combined δ18 O and dust record obtained by the North Greenland Ice Core Project (NGRIP) as a realisation of a two-dimensional, time-homogeneous, and Markovian stochastic process, we present a reconstruction of its underlying deterministic drift based on the leading-order terms of the Kramers–Moyal equation. The analysis reveals two basins of attraction in the two-dimensional state space that can be identified with the stadial and interstadial regimes. The drift term of the dust exhibits a double-fold bifurcation structure, while – in contrast to prevailing assumptions – the δ18 O component of the drift is clearly mono-stable. This suggests that the last glacial's Greenland temperatures should not be regarded as an intrinsically bistable climate variable. Instead, the two-regime nature of the δ18 O record is apparently inherited from a coupling to another bistable climate process. In contrast, the bistability evidenced in the dust drift points to the presence of two stable circulation regimes of the last glacial's Northern Hemisphere atmosphere. [ABSTRACT FROM AUTHOR]

Published

2023

39. Dynamics of the Marine Dissolved Organic Carbon Reservoir in Glacial Climate Simulations: The Importance of Biological Production.

Author

Gilchrist, Maya D. and Matsumoto, Katsumi

Subjects

DISSOLVED organic matter, GLACIAL climates, MERIDIONAL overturning circulation, ATMOSPHERIC carbon dioxide, CLIMATE change, ATMOSPHERE, GLACIATION

Abstract

The marine dissolved organic carbon (DOC) reservoir rivals the atmospheric carbon inventory in size. Recent work has suggested that the size of the DOC reservoir may respond to variations in sea temperature and global overturning circulation strength. Moreover, mobilization of marine DOC has been implicated in paleoclimate events including Cryogenian glaciation and Eocene hyperthermals. Despite these suggestions, the dynamics of the marine DOC reservoir are poorly understood, and previous carbon cycle modeling has generally assumed this reservoir to be static. In this study, we utilize an Earth system model of intermediate complexity to assess the response of the marine DOC reservoir to various glacial boundary conditions. Our results indicate that the marine DOC reservoir is responsive to glacial perturbations and may shrink or expand on the order of 10–100 Pg C. In contrast to recent studies that emphasize the importance of DOC degradation in driving the mobility of DOC reservoir, our study indicates the importance of DOC production. In the experiment under full glacial boundary conditions, for example, a 19% drop in net primary production leads to an 81 Pg C reduction in the DOC pool, without which the atmospheric CO2 concentration would have been lower by approximately 38 ppm by dissolved inorganic carbon changes alone. Thus, DOC reservoir variability is necessary to fully account for the simulated changes in atmospheric CO2 concentration. Our findings based on glacial experiments are corroborated in a different set of simulations using freshwater flux to induce weakening of the Atlantic meridional overturning circulation. Plain Language Summary: There is a significant reservoir of dissolved organic carbon (DOC) in the ocean originating from the production and decay of microbes, nearly equal to the amount of carbon contained as carbon dioxide (CO2) in the atmosphere. Studies have suggested that the total amount of DOC in the ocean may respond to climate effects on ocean temperatures and circulation, and that releases of DOC from the ocean as CO2 to the atmosphere may have contributed to some climate change events in Earth's history. To date, however, little modeling work has been done to understand this suggestion. In this study, we used a computer model of the earth's ocean and atmosphere to simulate the response of marine DOC to climate conditions representing the height of Earth's last glacial period. We found that the total amount of marine DOC simulated in our model could vary in response to the specific climate conditions applied and the modeled impacts on ocean biological production. Importantly, we found that these changes in the DOC reservoir are sufficiently large that without it, changes in atmospheric CO2 levels cannot be fully understood. Our results suggest that understanding marine DOC is crucial in understanding global climate changes throughout Earth's history. Key Points: The marine dissolved organic carbon (DOC) reservoir is mobile in response to glacial climate forcing and rapid changes in the meridional overturning circulationChanges in the size of the DOC reservoir are primarily driven by changes in DOC production rather than DOC degradationMarine DOC cycling is directly related to atmospheric pCO2 over simulated climate change events [ABSTRACT FROM AUTHOR]

Published

2023

40. EPIAURIGNACIAN IN DUSTRY WITH SAGAIDAK-MURALOVKA-TYPE MICROLITHS INDUSTRY IN THE SOUTH OF EASTERN EUROPE AND EASTERN CENTRAL EUROPE AND ITS LITHIC ARTEFACT FOSSIL TYPES.

Author

Demidenko, Yuri E., Škrdla, Petr, Rios-Garaizar, Joseba, Bartík, Jaroslav, and Rychtaříková, Tereza

Subjects

MICROLITHOGRAPHY, FOSSILS, GLACIAL climates, ARCHAEOLOGY, STONE implements

Abstract

Copyright of Študijné Zvesti AU SAV is the property of Institute of Archaeology SAS and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

41. Warming-driven indirect effects on alpine grasslands: short-term gravel encroachment rapidly reshapes community structure and reduces community stability.

Author

Wu, Gao-Lin, Fang, Hui, Cui, Zeng, and Zhao, Jingxue

Subjects

*GLOBAL warming, *GRAVEL, *MOUNTAIN ecology, *MOUNTAIN meadows, *GLACIAL climates, *GLACIAL melting

Abstract

The community stability is the main ability to resist and be resilient to climate changes. In a world of climate warming and melting glaciers, alpine gravel encroachment was occurring universally and threatening hillside grassland ecosystem. Gravel encroachment caused by climate warming and glacial melting may alter community structure and community stability in alpine meadow. Yet, the effects of climate warming-induced gravel encroachment on grassland communities are unknown. Here, a 1-year short-term field experiment was conducted to explore the early stage drive process of gravel encroachment on community structure and stability at four different gravel encroachment levels 0%, 30%, 60%, and 90% gravel coverage at an alpine meadow on the Qinghai Tibetan Plateau, by analyzing the changes of dominant species stability and species asynchrony to the simulated gravel encroachment processes. Gravel encroachment rapidly changed the species composition and species ranking of alpine meadow plant community in a short period of time. Specifically, community stability of alpine meadow decreased by 61.78–79.48%, which may be due to the reduced dominant species stability and species asynchrony. Species asynchrony and dominant species stability were reduced by 2.65–17.39% and 46.51–67.97%, respectively. The results of this study demonstrate that gravel encroachment presents a severe negative impact on community structure and stability of alpine meadow in the short term, the longer term and comprehensive study should be conducted to accurate prediction of global warming-induced indirect effects on alpine grassland ecosystems. [ABSTRACT FROM AUTHOR]

Published

2023

42. Conservation and sustainable development of coastal species of horticultural importance: insights from genetic and environmental patterns at spatio-temporal scale.

Author

Banerjee, Achyut Kumar, Wang, Jiakai, Feng, Hui, Lin, Yuting, Liang, Xinru, Yin, Minghui, Peng, Hao, Li, Weixi, Li, Tengjiao, Guo, Wuxia, and Huang, Yelin

Subjects

CHLOROPLAST DNA, COASTAL development, PLEISTOCENE Epoch, SUSTAINABLE development, GENETIC variation, GLACIAL climates, SPATIO-temporal variation

Abstract

Understanding genetic patterns at the regional level and the environmental influence on them is important for the conservation and sustainable use of economically important plant species. In this study, we focused on Thespesia populnea, a coastal species valued for its ecological and economic benefits across its pantropical distribution range. We aimed to understand the phylogeographic pattern, the current spatial distribution of genetic diversity, and range dynamics of the species with changing environmental conditions to better inform conservation and development actions. We genotyped 482 individuals, collected from 33 natural populations, at five chloroplast DNA loci and identified the influence of historical processes on the contemporary population structure of the species in the Indo-West Pacific (IWP) region. Environmental niche modeling (ENM) was used to identify the species' glacial and future climate refugia. High genetic diversity at the species level was observed. Nearly one-third of the populations showed no polymorphism, possibly due to extinction-recolonization events induced by glacial sea-level changes, as evident from the analysis of demographic history. The evolutionary relationship between the haplotypes suggested a strong phylogeographic structure. The clustering algorithms identified two genetic lineages that diverged around the Pleistocene epoch. The difference between the climatic niches of the two lineages was not significant. The ensembled ENM indicated range expansion of the species in the future. Based on the findings, we proposed sustainable use of genetically diverse populations, outlined measures to preserve the evolutionary potential of the lineages, and identified areas that should be prioritized for conservation actions of this important plant species. [ABSTRACT FROM AUTHOR]

Published

2023

43. Decoupled Indian Summer Monsoon Intensity and Effective Moisture Since the Last Glaciation in Southwest China.

Author

Zhang, Tingwei, Yang, Xiaoqiang, Peng, Jie, Zhou, Qixian, Toney, Jaime, Liu, Huiyang, and Xie, Yixuan

Subjects

*GLACIAL climates, *CLIMATE change, *INTERGLACIALS, *ATMOSPHERIC models, *GLACIATION, *MONSOONS, *ARID regions

Abstract

Effective moisture (EM) distribution in the Indian summer monsoon (ISM) region is strongly related to regional topography. An understanding of climate change and the interactions between climate variables can help predict future climate variations. Here, we reconstruct a stack EM record for Southwest China over the past 90 kyr using environmental magnetism in lake sediment. The EM in Southwest China at the orbital scale was closely linked to precession‐induced change in North Hemisphere solar insolation, as well as the ISM variability. However, at the glacial‐interglacial scale, it was decoupled with ISM intensity, being wetter during glacial periods (weakened ISM) and drier during interglacial periods (enhanced ISM). Combined with modern meteorological observations, we suggest that the topographical barrier effect and temperature induced dryness are responsible for the decoupling between ISM intensity and EM. The terrestrial topography and temperature strongly influence EM distribution by altering the dynamics of onshore airflow and evapotranspiration. Plain Language Summary: Effective moisture (EM) directly affects hydrological cycle and wider‐scale socio‐economic development. Reconstruction of prehistoric EM levels is essential for deeper understanding of the global climate system, developing climate models and improving prediction of future climate variations. Here, we reconstruct a high‐resolution EM record over the past ∼90,000 years from lake sediments in Tengchong, Yunnan province, Southwest China. We found that the variation of precession (shifts in the rotational axis of the Earth) and solar insolation are the key contributors to the EM variability at the orbital scale. Unusually, a wetter climate during the glacial period and relatively drier interglacial periods were observed in our records, which is opposite to those found in previous studies (arid glacial and humid interglacial) in monsoon regions, indicating a decoupling pattern between monsoon intensity and EM in study region. Based on a comprehensive analysis of the modern meteorological observations, we conclude that the topography and temperature exert a considerable role in modulating EM distribution and response to the decoupling pattern. Key Points: The long‐term effective moisture (EM) record in Southwest China since ∼90 kyr was reconstructedThe EM variability at the orbital scale in terrestrial Indian summer monsoon region is primarily dominated by precessionThe topographic barrier and temperature induced aridification contribute to the decoupling of monsoon intensity and EM [ABSTRACT FROM AUTHOR]

Published

2023

44. Marine‐Calibrated Chronology of Southern Laurentide Ice Sheet Advance and Retreat: ∼2,000‐Year Cycles Paced by Meltwater–Climate Feedback.

Author

Wickert, Andrew D., Williams, Carlie, Gregoire, Lauren J., Callaghan, Kerry L., Ivanović, Ruža F., Valdes, Paul J., Vetter, Lael, and Jennings, Carrie E.

Subjects

*MELTWATER, *ICE sheets, *MERIDIONAL overturning circulation, *LAST Glacial Maximum, *GLACIAL climates, *YOUNGER Dryas

Abstract

Climatic warming following the Last Glacial Maximum caused the southern Laurentide Ice Sheet (LIS) to begin ∼2,000‐year cycles of retreat and readvance whose cause remains ambiguous. By developing a marine‐calibrated chronology of southern LIS position, we counterintuitively demonstrate that between 17.6 and 11.3 ka, ice advanced during times of northern‐hemisphere warming and retreated during times of northern‐hemisphere cooling. Here we propose a cyclical feedback: Meltwater from ice retreat cooled the northern hemisphere by weakening the Atlantic Meridional Overturning Circulation (AMOC). This eventually lead to ice‐sheet readvance, which reduced and rerouted meltwater discharge, and thereby allowed the AMOC to strengthen and the northern hemisphere to warm. Our data suggest that this antiphased ice–climate interaction, paced by ice‐sheet response time, was initiated by synchronous warming and ice retreat ∼18.7–17.6 ka (corresponding to the Erie "Interstade") and reached its apex during the Younger Dryas. Plain Language Summary: Twenty thousand years ago, a colder climate allowed glacial ice to flow from northern and eastern Canada into the Great Lakes region. But when climate began to warm, instead of simply melting from south to north, the margin of this ice front repeatedly retreated and re‐advanced in 2,000‐year cycles. First, we track these advances and retreats using records of ancient Gulf of Mexico water, stored in plankton shells retrieved from a sediment cores. Ice advance redirected water bearing "light" oxygen, with fewer neutrons, from Canada and the Great Lakes into the Mississippi River. When ice retreated, these waters found other courses to the sea, shifting Gulf of Mexico chemistry toward heavier oxygen (carrying more neutrons). Next, we ask why these ice‐margin cycles occurred during a time of monotonically increasing solar radiation to the northern hemisphere. We propose that ice‐sheet melt (during retreat) slowed Atlantic Ocean circulation, causing the northern hemisphere to cool and the ice sheet to gradually regrow. However, this same regrowth reduced meltwater flow to the ocean, causing the northern hemisphere to re‐warm and eventually leading the ice margin to retreat once more. This cycle persisted from approximately 17,600 to 11,300 years ago, until North American ice became too small to sustain this feedback. Key Points: δ18O records from the Gulf of Mexico refine the chronology of Laurentide Ice Sheet advance and retreat through the Great LakesCounterintuitively, from 17.6 to 11.3 ka, ice advanced during times of warming and retreated during times of coolingA feedback between meltwater, Atlantic Meridional Overturning Circulation strength, and temperature—paced by ice‐sheet response time—may have set this anticorrelation [ABSTRACT FROM AUTHOR]

Published

2023

45. Thermoelasticity of ice explains widespread damage in dripstone caves during glacial periods.

Author

Spötl, Christoph, Jarosch, Alexander H., Saxer, Andreas, Koltai, Gabriella, and Zhang, Haiwei

Subjects

*GLACIATION, *SPELEOTHEMS, *LAST Glacial Maximum, *THERMOELASTICITY, *CAVES, *STALACTITES & stalagmites, *GLACIAL climates

Abstract

Damage to speleothems is a common phenomenon in mid-latitude caves, and multiple causes have been proposed. Here we report on one of such type of damage, namely stalagmites that are broken and partially sheared near their base but are still in upright position. Such stalagmites occur in the Obir Caves (Austria) associated with cryogenic cave carbonates, demonstrating the former presence of cave ice. 230Th dating suggests damage to the speleothems during the Last Glacial Maximum. Numerical modelling combined with laboratory measurements demonstrates that internal deformation within a cave ice body cannot fracture stalagmites, even on a steep slope. Instead, temperature changes lead to thermoelastic stresses within an ice body that reach values equaling to and exceeding the tensile strength of even large stalagmites. Differences in thermal expansion coefficients cause a sharp vertical jump in stress between the stalagmite and the surrounding ice body, and the ice lifts the stalagmite as it expands with increasing temperature. This study refutes the previously accepted model that flow of ice breaks stalagmites, and suggests a link between glacial climate variability and corresponding cooling and warming cycles in the subsurface that weaken and eventually fracture stalagmites due to the opposing thermoelastic properties of calcite and ice. [ABSTRACT FROM AUTHOR]

Published

2023

46. Ecological and hydrologic evolution history in the sensitive zone of both East Asian summer monsoon and Westerly since the Last Glacial Maximum.

Author

Li, Yu and Peng, Si-min

Subjects

LAST Glacial Maximum, MONSOONS, GLACIAL climates, WESTERLIES, HYDROLOGIC cycle, TRAFFIC violations

Abstract

The Qilian Mountains, located in the northeastern Qinghai-Tibet Plateau, is a sensitive zone of both East Asian summer monsoon (EASM) and westerly winds (WW). The evolution history and driving mechanism of the ecosystem and hydrologic cycle in this region on long-term timescales have not yet been clarified. In this study, we comprehensively study the hydrologic and ecological evolution history in the sensitive zone since the Last Glacial Maximum (LGM) by integrating surface sediments, paleoclimate records, TraCE-21ka transient simulations, and PMIP3-CMIP5 multi-model simulation. Results show that hydrologic and ecological proxies from surface sediments are significantly different from west to east and mainly divided into three sections: the monsoon-affected region in the eastern Qilian Mountains, the intersection region in the central Qilian Mountains, and the westerly-affected region in the western Qilian Mountains. Meanwhile, paleo-ecological and paleohydrologic reconstructions from the surroundings uncover a synchronous climate evolution that the EASM mainly controls the eastern Qilian Mountains and penetrates the central Qilian Mountains in monsoon intensity maximum, while the WW dominates the central and western Qilian Mountains on both glacial-interglacial and millennial timescales. The simulation results further bear out the glacial humid climate in the central and western Qilian Mountains caused by the enhanced WW, and the humidity maximum in the eastern Qilian Mountains controlled by the strong mid-Holocene monsoon. In general, east-west differences in climate pattern and response for the EASM and the WW are integrally stable on both short-term and long-term timescales. [ABSTRACT FROM AUTHOR]

Published

2023

47. Global range dynamics of the Bearded Vulture (Gypaetus barbatus) from the Last Glacial Maximum to climate change scenarios.

Author

Subedi, Tulsi R., Peréz‐García, Juan M., Gurung, Sandesh, Baral, Hem S., Virani, Munir Z., Sah, Shahrul A. M., and Anadón, José D.

Subjects

LAST Glacial Maximum, GLACIAL climates, VULTURES, BEARDS, WILDLIFE conservation

Abstract

Species' ranges are dynamic, particularly at large temporal scales. The reconstruction of range dynamics has an obvious biogeographical interest and might also help to frame current knowledge on the ecology and conservation of a species within a wider biogeographical context. The Bearded Vulture Gypaetus barbatus is a charismatic high‐altitude species occurring along mountain ranges of the Old World. The species has experienced a global range contraction in the last century mainly due to unintentional poisoning and direct persecution. Despite its declining status and high habitat specialization, little is known about how climate change is impacting the distribution of suitable habitat, or about global past range dynamics of the species. We modelled the current distribution of Bearded Vulture throughout its entire range and projected the Last Glacial Maxima (LGM), Mid‐Holocene (MH) and future distribution under 2070s climate change scenarios. Overall, our models predicted that expansion of suitable areas at more northern latitudes for 2070, mostly in Russia and China, does not compensate for range contraction at more southern latitudes, resulting in a global loss of 15% of suitable habitat. Our fine‐scale predictions of habitat contraction due to climate change will assist in identifying current portions of the range that might be particularly vulnerable in coming years. African populations (34% decrease) and more thermic areas in Asia are the most impacted areas, and should be at the forefront of future monitoring and conservation efforts. Our models suggest that the predicted contraction in habitat suitability during the 21st century largely continues the contraction experienced since the LGM (7% decline), albeit over a much shorter period of time. From a biogeographical perspective, our models suggest that there have not been relevant changes in the arrangement of the main suitable areas for the species since the LGM. This result challenges some of the main hypotheses proposed to explain the observed genetic structure of the global population. [ABSTRACT FROM AUTHOR]

Published

2023

48. Does witnessing the effects of climate change on glacial landscapes increase pro-environmental behaviour intentions? An empirical study of a last-chance destination.

Author

Salim, Emmanuel, Ravanel, Ludovic, and Deline, Philip

Subjects

GLACIAL climates, CLIMATE change, GREENHOUSE gases, LANDSCAPE changes, INTENTION, TOURIST attractions

Abstract

Due To the effects of climate change, tourist locations such as glacial landscapes are increasingly becoming last-chance tourism (LCT) destinations. LCT is paradoxical: although visitors to such locations possess high environmental awareness, their travel generates greenhouse gas emissions that threaten these destinations. However, visiting LCT destinations and observing glacial landscapes threatened by climate change may positively affect pro-environmental behaviour. This article aims to explore how experiencing receding glaciers can influence intentions to adopt pro-environmental behaviour. A quantitative survey of 284 visitors to a major glacier tourism site in France (Montenvers-mer-de-Glace) was caried out to test the influence of landscape, emotions, satisfaction, and LCT-related motivations on intentions to adopt pro-environmental behaviours. The results show that landscapes perceived as symbolic of climate change, LCT motivations, and overall satisfaction positively influenced pro-environmental behaviour intentions. To further encourage such intentions, stakeholders should promote practices based on education and experience. [ABSTRACT FROM AUTHOR]

Published

2023

49. Kalimantan hydroclimate variability since the last glacial period.

Author

Hendrizan, Marfasran, Kuhnt, Wolfgang, Holbourn, Ann, Cahyarini, Sri Yudawati, and Ningsih, Nining Sari

Subjects

*GLACIATION, *GLACIAL climates, *YOUNGER Dryas, *X-ray fluorescence, *WATER depth, *EROSION

Abstract

Changes in convective activity and hydroclimate over Northeastern Kalimantan are key features to understand glacial to interglacial climate evolution in the center of the West Pacific Warm Pool during the Late Pleistocene to Holocene. We use high-resolution X-ray fluorescence (XRF) scanner-derived elemental ratios in sediment Core SO217-18522 (1º 24.106' N, 119º 4.701'E, 975 m water depth) recovered from the northern Makassar Strait to reconstruct changes in precipitation-related weathering and erosion over Northeastern Kalimantan over the last 50 kyr. Enhanced seasonality of rainfall and an extended dry season during Heinrich Stadials (HS4 to HS1) and the Younger Dryas (YD) suggest weakening of the tropical convection associated with a southward shift of the tropical rain belt and the annual mean position of the Intertropical Tropical Convection Zone. Increasing sediment discharge and intensification of convective activity occurred during the early to mid-Holocene during an interval of high Northern Hemisphere insolation, elevated atmospheric pCO2 levels and global warming. Our reconstructions in comparison with regional terrestrial and marine records highlight the high spatial variability of Kalimantan hydroclimate on millennial to glacial-interglacial timescales. [ABSTRACT FROM AUTHOR]

Published

2023

50. Sedimentary Ancient DNA Reveals Local Vegetation Changes Driven by Glacial Activity and Climate.

Author

Elliott, Lucas D., Rijal, Dilli P., Brown, Antony G., Bakke, Jostein, Topstad, Lasse, Heintzman, Peter D., and Alsos, Inger G.

Subjects

GLACIAL climates, FOSSIL DNA, VEGETATION dynamics, ARCTIC climate, ALPINE glaciers, CLIMATE sensitivity, GLACIERS

Abstract

Disentangling the effects of glaciers and climate on vegetation is complicated by the confounding role that climate plays in both systems. We reconstructed changes in vegetation occurring over the Holocene at Jøkelvatnet, a lake located directly downstream from the Langfjordjøkel glacier in northern Norway. We used a sedimentary ancient DNA (sedaDNA) metabarcoding dataset of 38 samples from a lake sediment core spanning 10,400 years using primers targeting the P6 loop of the trnL (UAA) intron. A total of 193 plant taxa were identified revealing a pattern of continually increasing richness over the time period. Vegetation surveys conducted around Jøkelvatnet show a high concordance with the taxa identified through sedaDNA metabarcoding. We identified four distinct vegetation assemblage zones with transitions at ca. 9.7, 8.4 and 4.3 ka with the first and last mirroring climatic shifts recorded by the Langfjordjøkel glacier. Soil disturbance trait values of the vegetation increased with glacial activity, suggesting that the glacier had a direct impact on plants growing in the catchment. Temperature optimum and moisture trait values correlated with both glacial activity and reconstructed climatic variables showing direct and indirect effects of climate change on the vegetation. In contrast to other catchments without an active glacier, the vegetation at Jøkelvatnet has displayed an increased sensitivity to climate change throughout the Middle and Late Holocene. Beyond the direct impact of climate change on arctic and alpine vegetation, our results suggest the ongoing disappearance of glaciers will have an additional effect on plant communities. [ABSTRACT FROM AUTHOR]

Published

2023