Inconsistent Responses of Hot Extremes to Historical Land Use and Cover Change Among the Selected CMIP5 Models

Li, Xing; Chen, Haishan; Wei, Jiangfeng; Hua, Wenjian; Sun, Shurong; Ma, Hedi; Li, Jingping

doi:10.1002/2017jd028161

Cited by 20 publications

(19 citation statements)

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“…Some regions with extensive historical LCC (Eurasia and North America) have experienced biophysical decreases in annual mean temperature of a magnitude similar to the concomitant increase in greenhouse gases (de Noblet-Ducoudré et al 2012). However, considerable disagreement is evident in model responses; most models show mid-latitude decreases of most hot extreme indices , Christidis et al 2013, Li et al 2018, Chen and Dirmeyer 2019, while other models simulate increases (Avila et al 2012, Findell et al 2017, Lejeune et al 2018, Li et al 2018, Chen and Dirmeyer 2019 in response to historical LCC. For instance, three out of four models of the 'land-use and climate, identification of robust impacts' (LUCID) intercomparison project simulated a decrease in extremely warm daytime temperatures over the northern mid-latitudes during summer due to historical LCC .…”

Section: Introductionmentioning

confidence: 99%

Anthropogenic land cover change impact on climate extremes during the 21st century

Quesada

2020

Environ. Res. Lett.

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Anthropogenic land cover change (LCC) can have significant impacts at regional and seasonal scales but also for extreme weather events to which socio-economical systems are vulnerable. However, the effects of LCC on extreme events remain either largely unexplored and/or without consensus following modelling over the historical period (often based on a single model), regional or idealized studies. Here, using simulations performed with five earth system models under common future global LCC scenarios (the RCP8.5 and RCP2.6 Representative Concentration Pathways) and analyzing 20 extreme weather indices, we find future LCC substantially modulates projected weather extremes. On average by the end of the 21st century, under RCP8.5, future LCC robustly lessens global projections of high rainfall extremes by 22% for heavy precipitation days (>10 mm) and by 16% for total precipitation amount of wet days (PRCPTOT). Accounting for LCC diminishes their regional projections by >50% (70%) in southern Africa (northeastern Brazil) but intensifies projected dry days in eastern Africa by 29%. LCC does not substantially affect projections of global and regional temperature extremes (<5%), but it can impact global rainfall extremes 2.5 times more than global mean rainfall projections. Under an RCP2.6 scenario, global LCC impacts are similar but of lesser magnitude, while at regional scale in Amazon or Asia, LCC enhances drought projections. We stress here that multi-coupled modelling frameworks incorporating all aspects of land use are needed for reliable projections of extreme events.

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Section: Introductionmentioning

confidence: 99%

Anthropogenic land cover change impact on climate extremes during the 21st century

Quesada

2020

Environ. Res. Lett.

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“…Climate models (Arora and Montenegro 2011;Bala et al 2007; Davin and de Noblet-Ducoudré 2010) simulate a warming effect while observations (Alkama and Cescatti 2016;Burakowski et al 2018;Duveiller et al 2018;Li et al 2015;Schultz et al 2017;Wang et al 2018) point to cooling. Recent studies also suggest afforestation can impact temperature extremes (Findell et al 2017;Skinner et al 2018;Teuling et al 2010) although modeling of these processes is very uncertain (Avila et al 2012;Li et al 2018;Pitman et al 2012). Despite these uncertainties, the biophysical effects of afforestation on climate need to be considered, especially at local and regional scales where afforestation strategies are being implemented, to avoid risk of maladaptation (Anderson et al 2011;Bonan 2008).…”

Section: Introductionmentioning

confidence: 99%

The Nonradiative Effect Dominates Local Surface Temperature Change Caused by Afforestation in China

Guo

Pitman

et al. 2019

Journal of Climate

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China is several decades into large-scale afforestation programs to help address significant ecological and environmental degradation, with further afforestation planned for the future. However, the biophysical impact of afforestation on local surface temperature remains poorly understood, particularly in midlatitude regions where the importance of the radiative effect driven by albedo and the nonradiative effect driven by energy partitioning is uncertain. To examine this issue, we investigated the local impact of afforestation by comparing adjacent forest and open land pixels using satellite observations between 2001 and 2012. We attributed local surface temperature change between adjacent forest and open land to radiative and nonradiative effects over China based on the Intrinsic Biophysical Mechanism (IBM) method. Our results reveal that forest causes warming of 0.23°C (±0.21°C) through the radiative effect and cooling of −0.74°C (±0.50°C) through the nonradiative effect on local surface temperature compared with open land. The nonradiative effect explains about 79% (±16%) of local surface temperature change between adjacent forest and open land. The contribution of the nonradiative effect varies with forest and open land types. The largest cooling is achieved by replacing grasslands or rain-fed croplands with evergreen tree types. Conversely, converting irrigated croplands to deciduous broadleaf forest leads to warming. This provides new guidance on afforestation strategies, including how these should be informed by local conditions to avoid amplifying climate-related warming.

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“…Compared with the impacts on precipitation, which are more complex and difficult to validate, the relationship between deforestation and temperature has been extensively investigated using both observational datasets and modeling approaches 4 . In particular, recent studies have suggested that historical LULCC (namely deforestation) can significantly influence local high temperature extremes [5][6][7][8][9][10] .…”

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confidence: 99%

“…Satellite-based observations show that cleared lands are warmer than nearby forest in daily maximum temperature during summer [12][13][14] . On the contrary, results from CMIP5 (Coupled Model Intercomparison Project Phase 5 15 ) and LUCID (land use and climate: identification of robust impacts 16,17 ) tend toward a summer daytime cooling over the middle latitudes as a result of documented historical deforestation 6,11 . The disagreement of model results with observations has been claimed to be associated with parameterization issues in current land surface models, such as the changes in partitioning of available energy between latent and sensible heat fluxes due to LULCC 6,8,11 .…”

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confidence: 99%

Reconciling the disagreement between observed and simulated temperature responses to deforestation

Chen

Dirmeyer

2020

Nat Commun

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Land use changes have great potential to influence temperature extremes. However, contradictory summer daytime temperature responses to deforestation are reported between observations and climate models. Here we present a pertinent comparison between multiple satellite-based datasets and climate model deforestation experiments. Observationally-based methods rely on a space-for-time assumption, which compares neighboring locations with contrasting land covers as a proxy for land use changes over time without considering possible atmospheric feedbacks. Offline land simulations or subgrid-level analyses agree with observed warming effects only when the space-for-time assumption is replicated. However, deforestation-related cloud and radiation effects manifest in coupled climate simulations and observations at larger scales, which show that a reduction of hot extremes with deforestationas simulated in a number of CMIP5 modelsis possible. Our study provides a design and analysis methodology for land use change studies and highlights the importance of including land-atmosphere coupling, which can alter deforestation-induced temperature changes.

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Inconsistent Responses of Hot Extremes to Historical Land Use and Cover Change Among the Selected CMIP5 Models

Cited by 20 publications

References 77 publications

Anthropogenic land cover change impact on climate extremes during the 21st century

Anthropogenic land cover change impact on climate extremes during the 21st century

The Nonradiative Effect Dominates Local Surface Temperature Change Caused by Afforestation in China

Reconciling the disagreement between observed and simulated temperature responses to deforestation

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