Abstract. The Tibetan Plateau (TP) has the largest areas of permafrost terrain in the mid-and low-latitude regions of the world. Some permafrost distribution maps have been compiled but, due to limited data sources, ambiguous criteria, inadequate validation, and deficiency of high-quality spatial data sets, there is high uncertainty in the mapping of the permafrost distribution on the TP. We generated a new permafrost map based on freezing and thawing indices from modified Moderate Resolution Imaging Spectroradiometer (MODIS) land surface temperatures (LSTs) and validated this map using various ground-based data sets. The soil thermal properties of five soil types across the TP were estimated according to an empirical equation and soil properties (moisture content and bulk density). The temperature at the top of permafrost (TTOP) model was applied to simulate the permafrost distribution. Permafrost, seasonally frozen ground, and unfrozen ground covered areas of 1.06 × 10 6 km 2 (0.97-1.15 × 10 6 km 2 , 90 % confidence interval) (40 %), 1.46 × 10 6 (56 %), and 0.03 × 10 6 km 2 (1 %), respectively, excluding glaciers and lakes. Ground-based observations of the permafrost distribution across the five investigated regions (IRs, located in the transition zones of the permafrost and seasonally frozen ground) and three highway transects (across the entire permafrost regions from north to south) were used to validate the model. Validation results showed that the kappa coefficient varied from 0.38 to 0.78 with a mean of 0.57 for the five IRs and 0.62 to 0.74 with a mean of 0.68 within the three transects. Compared with earlier studies, the TTOP modelling results show greater accuracy. The results provide more detailed information on the permafrost distribution and basic data for use in future research on the Tibetan Plateau permafrost.
Overexploitation, habitat destruction, human-driven climate change and disease spread are resulting in the extinction of innumerable species, with amphibians being hit harder than most other groups [1]. Few species of amphibians are widespread, and those that are often represent complexes of multiple cryptic species. This is especially true for range-restricted salamanders [2]. Here, we used the widespread and critically endangered Chinese giant salamander (Andrias davidianus) to show how genetically uninformed management efforts can negatively affect species conservation. We find that this salamander consists of at least five species-level lineages. However, the extensive recent translocation of individuals between farms, where the vast majority of extant salamanders now live, has resulted in genetic homogenization. Mitochondrial DNA (mtDNA) haplotypes from northern China now predominate in farms. Unfortunately, hybrid offspring are being released back into the wild under well-intentioned, but misguided, conservation management. Our findings emphasize the necessity of genetic assessments for seemingly well-known, widespread species in conservation initiatives. Species serve as the primary unit for protection and management in conservation actions [3], so determining the taxonomic status of threatened species is a major concern, especially for amphibians. The level of threat to amphibians may be underestimated, and existing conservation strategies may be inadvertently harmful if conducted without genetic assessment.
Permafrost on the Qinghai–Tibet Plateau (QTP) has undergone degradation as a result of recent climate change. This may alter the thermo‐hydrological processes and unlock soil organic carbon, and thereby affect local hydrological, ecological, and climatic systems. The relationships between permafrost and climate change have received extensive attention, and in this paper we review climate change for permafrost regions of the QTP over the past 30 years. We summarize the current state and changes in permafrost distribution and thickness, ground temperature, and ground ice conditions. We focus on changes in permafrost thermal state and in active‐layer thickness (ALT). Possible future changes in ground temperature and ALT are also discussed. Finally, we discuss the changes in hydrological processes and to ecosystems caused by permafrost degradation. Air temperature and ground temperature in the permafrost regions of the QTP have increased from 1980 to 2018, and the active layer has been thickening at a rate of 19.5 cm per decade. The response of permafrost to climate change is not as fast as in some reports, and permafrost degradation is slower than projected by models that do not account for conditions deep in permafrost.
Abstract. Permafrost has great influences on the climatic, hydrological, and
ecological systems on the Qinghai–Tibet Plateau (QTP). The changing
permafrost and its impact have been attracting great attention worldwide
like never before. More observational and modeling approaches are needed to
promote an understanding of permafrost thermal state and climatic conditions
on the QTP. However, limited data on the permafrost thermal state and
climate background have been sporadically reported in different pieces of
literature due to the difficulties of accessing and working in this region
where the weather is severe, environmental conditions are harsh, and the
topographic and morphological features are complex. From the 1990s, we began
to establish a permafrost monitoring network on the QTP. Meteorological
variables were measured by automatic meteorological systems. The soil
temperature and moisture data were collected from an integrated observation
system in the active layer. Deep ground temperature (GT) was observed from
boreholes. In this study, a comprehensive dataset consisting of long-term
meteorological, GT, soil moisture, and soil temperature data was compiled
after quality control from an integrated, distributed, and multiscale
observation network in the permafrost regions of QTP. The dataset is
helpful for scientists with multiple study fields (i.e., climate,
cryospheric, ecology and hydrology, meteorology science), which will
significantly promote the verification, development, and improvement of
hydrological models, land surface process models, and climate models on the QTP.
The datasets are available from the National Tibetan Plateau/Third Pole
Environment Data Center (https://data.tpdc.ac.cn/en/disallow/789e838e-16ac-4539-bb7e-906217305a1d/, last access: 24 August 2021,
https://doi.org/10.11888/Geocry.tpdc.271107, Lin et al., 2021).
Frozen ground is an important component of the cryosphere, which exerts strong influences on regional ecology, hydrology and infrastructure engineering (W. Wang et al., 2018; Westermann et al., 2015). The Qinghai-Tibet Plateau (QTP) is underlain by typical high-altitude permafrost region, which is undergoing more dramatic climatic warming than its surrounding regions (Wang et al., 2019). A growing number of studies have reported the present status and predicted degradation of permafrost under various global warming scenarios (
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.