Modeling the Effect of Climate Change on the Potential Distribution of Qinghai Spruce (Picea crassifolia Kom.) in Qilian Mountains

Rong, Zhanlei; Zhao, Chuanyan; Liu, Junjie; Gao, Yunfei; Zang, Fei; Guo, Zhaoxia; Mao, Yahua; Wang, Sheng

doi:10.3390/f10010062

Cited by 57 publications

(39 citation statements)

References 71 publications

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“…Unfortunately, surface meteorological stations are sparse in QLM, especially in the western QLM. erefore, most of previous studies in QLM are based on limited observations or remote sensing data on the climate and glacier changes in QLM [6][7][8][9]. Jiang et al [10] found that the annual variations of ice and snow are significant along elevations based on MODIS data.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of ERA-Interim Air Temperature Data over the Qilian Mountains of China

Zhao

Gao

Wei

et al. 2020

Advances in Meteorology

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In this study, 2 m air temperature data from 24 meteorological stations in the Qilian Mountains (QLM) are examined to evaluate ERA-Interim reanalysis temperature data derived from the European Centre for Medium-Range Weather Forecasts (ECMWF) for the period of 1979-2017. ERA-Interim generally captures the monthly, seasonal, and annual variation very well. High daily correlations ranging from 0.956 to 0.996 indicate that ERA-Interim captures the daily temperature observations very well. However, an average root-mean-square error (RMSE) of ±2.7°C of all stations reveals that ERA-Interim should not be directly applied at individual sites. e biases are mainly attributed to the altitude differences between ERA-Interim grid points and stations. e positive trend (0.457°C/decade) is significant over the Qilian Mountains based on the 1979-2017 observations. ERA-Interim captures the warming trend very well with an increase rate of 0.384°C/decade. e observations and ERA-Interim both show the largest positive trends in summer with the values of 0.552°C/decade and 0.481°C/decade, respectively. We conclude that in general ERA-Interim captures the trend very well for observed 2 m air temperatures and ERA-Interim is generally reliable for climate change research over the Qilian Mountains.

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Section: Introductionmentioning

confidence: 99%

Evaluation of ERA-Interim Air Temperature Data over the Qilian Mountains of China

Zhao

Gao

Wei

et al. 2020

Advances in Meteorology

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“…Existing research of different regions has reported variables found to have an important effect on various species. For example: Evangelista, Young & Burnett, 2013 Studied teff by using three climate projection model that the value of predictable were 0.79 (Bio16, Bio12, Bio19, Bio15) and others studied different species in different geographical area including, (Elham et al, 2015) (Bio2, Bio3, Bio7, Bio8, Bio13, Bio14, Bio15, Bio18), ( Ardestani et al, 2015 ) (Bio8, Bio19, Bio2, Bio13, Bio7), Sen et al, 2016 (Bio4 and Bio19), Rong et al, 2019 (Bio1, Bio8 and elevation), ( Abdelaal et al, 2020 ) (elevation, precipitation, temperature and soil), and Yang et al, 2020 (Temp Seasonality, Precipitation, Vegetation Type, Soil Type). Our results indicate that temperature of coldest quarter had a predictability value of 0.83 for teff, which is stronger than that of any other existing model.…”

Section: Discussionmentioning

confidence: 99%

“…A variety of SDMs have been developed to predict species distributions under different climate scenarios (e.g., RCP). Commonly used SDM models including the Genetic Algorithm for Rule-set Production (GARP), BIOCLIM and Ecological Niche Factor Analysis (ENFA) have proved to be essential for predicting target species distributions under current, and also future climate scenarios ( Rong et al, 2019 ; Tognelli et al, 2009 ). Maxent (maximum entropy) has been widely used due to its many advantages, including its ability to: deal with incomplete data, small sample size, species presence data, both continuous and categorical environmental data; reduce laborious jobs in data collection; facilitate model interpretation, and for its prediction accuracy and reliability ( Guo et al, 2017a ; Rong et al, 2019 ).…”

Section: Introductionmentioning

confidence: 99%

“…Commonly used SDM models including the Genetic Algorithm for Rule-set Production (GARP), BIOCLIM and Ecological Niche Factor Analysis (ENFA) have proved to be essential for predicting target species distributions under current, and also future climate scenarios ( Rong et al, 2019 ; Tognelli et al, 2009 ). Maxent (maximum entropy) has been widely used due to its many advantages, including its ability to: deal with incomplete data, small sample size, species presence data, both continuous and categorical environmental data; reduce laborious jobs in data collection; facilitate model interpretation, and for its prediction accuracy and reliability ( Guo et al, 2017a ; Rong et al, 2019 ). SDMs assume that available presence locations represent a random (representative) sample in the geographical space, with no spatial dependencies and bolstered by data-rich technologies, such as geographical information systems (GIS) ( Rushton, Ormerod & Kerby, 2004 ; Elith et al, 2011 ).…”

Section: Introductionmentioning

confidence: 99%

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Spatiotemporal dynamics of habitat suitability for the Ethiopian staple crop, Eragrostis tef (teff), under changing climate

Zewudie

Ding

Rong

et al. 2021

PeerJ

Self Cite

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Teff (Eragrostis tef (Zucc.) Trotter) is a staple, ancient food crop in Ethiopia. Its growth is affected by climate change, so it is essential to understand climatic effects on its habitat suitability in order to design countermeasures to ensure food security. Based on the four Representative Concentration Pathway emission scenarios (i.e., RCP2.6, RCP4.5, RCP6.0 and RCP8.5) set by the Intergovernmental Panel on Climate Change (IPCC), we predicted the potential distribution of teff under current and future scenarios using a maximum entropy model (Maxent). Eleven variables were selected out of 19, according to correlation analysis combined with their contribution rates to the distribution. Simulated accuracy results validated by the area under the curve (AUC) had strong predictability with values of 0.83–0.85 for current and RCP scenarios. Our results demonstrated that mean temperature in the coldest season, precipitation seasonality, precipitation in the cold season and slope are the dominant factors driving potential teff distribution. Proportions of suitable teff area, relative to the total study area were 58% in current climate condition, 58.8% in RCP2.6, 57.6% in RCP4.5, 59.2% in RCP6.0, and 57.4% in RCP8.5, respectively. We found that warmer conditions are correlated with decreased land suitability. As expected, bioclimatic variables related to temperature and precipitation were the best predictors for teff suitability. Additionally, there were geographic shifts in land suitability, which need to be accounted for when assessing overall susceptibility to climate change. The ability to adapt to climate change will be critical for Ethiopia’s agricultural strategy and food security. A robust climate model is necessary for developing primary adaptive strategies and policy to minimize the harmful impact of climate change on teff.

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“…Many model intercomparison studies have reported that the MaxEnt model, which is based on the principle of maximum entropy [24,27,31,32] , typically outperforms other species distribution models (SDMs) in terms of high tolerance and high predictive accuracy [33][34][35] . Over the past 10 years, worldwide research teams have achieved excellent results in the study of rare animal and plant diversity protection [36][37][38][39] , invasive species risk prediction [40,41] , marine ecosystem protection [42,43] , disaster distribution prediction [44] , and disease propagation [45,46] using the MaxEnt model. Zhang et al [47] predicted the distribution of suitable habitats for Cinnamomum camphora (L.) Presl in China under future climate change scenarios.…”

Section: Introductionmentioning

confidence: 99%

Global distribution of Sapindus habitats under current and future climate change scenarios

Liu

Wang

Sun

et al. 2021

Preprint

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Sapindus (Sapindus L.) is a widely distributed economically important tree genus that provides biodiesel, biomedical and biochemical products. However, with climate change, deforestation, and economic development, Sapindus germplasm resources have been lost. Therefore, utilising historical environmental data and future climate projections from the BCC-CSM2-MR global climate database, we simulated the present and future global distributions of suitable habitats for Sapindus using a Maximum Entropy (MaxEnt) model. The estimated ecological thresholds for critical environmental factors were: a minimum temperature of 0–20°C in the coldest month, soil moisture levels of 40–140 mm, a mean temperature of 2–25°C in the driest quarter, a mean temperature of 19–28°C in the wettest quarter, and a soil pH of 5.6–7.6. The total suitable habitat area was 6059.97 × 104 km2, which was unevenly distributed across six continents. As greenhouse gas emissions increased over time, the area of suitable habitats contracted in lower latitudes and expanded in higher latitudes. Consequently, surveys and conservation should be prioritised in southern hemisphere areas which are in danger of becoming unsuitable. In contrast, other areas in northern and central America, China, and India can be used for conservation and large-scale cultivation in the future.

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Modeling the Effect of Climate Change on the Potential Distribution of Qinghai Spruce (Picea crassifolia Kom.) in Qilian Mountains

Cited by 57 publications

References 71 publications

Evaluation of ERA-Interim Air Temperature Data over the Qilian Mountains of China

Evaluation of ERA-Interim Air Temperature Data over the Qilian Mountains of China

Spatiotemporal dynamics of habitat suitability for the Ethiopian staple crop, Eragrostis tef (teff), under changing climate

Global distribution of Sapindus habitats under current and future climate change scenarios

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