Abstract
Change of global monsoon (GM) during the Last Glacial Maximum (LGM) is investigated using results from the multi-model ensemble of seven coupled climate models participated in the Coupled Model Intercomparison Project Phase 5. The GM changes during LGM are identified by comparison of the results from the pre-industrial control run and the LGM run. The results show (1) the annual mean GM precipitation and GM domain are reduced by about 10 and 5 %, respectively; (2) the monsoon intensity (demonstrated by the local summer–minus–winter precipitation) is also weakened over most monsoon regions except Australian monsoon; (3) the monsoon precipitation is reduced more during the local summer than winter; (4) distinct from all other regional monsoons, the Australian monsoon is strengthened and the monsoon area is enlarged. Four major factors contribute to these changes. The lower greenhouse gas concentration and the presence of the ice sheets decrease air temperature and water vapor content, resulting in a general weakening of the GM precipitation and reduction of GM domain. The reduced hemispheric difference in seasonal variation of insolation may contribute to the weakened GM intensity. The changed land–ocean configuration in the vicinity of the Maritime Continent, along with the presence of the ice sheets and lower greenhouse gas concentration, result in strengthened land–ocean and North–South hemispheric thermal contrasts, leading to the unique strengthened Australian monsoon. Although some of the results are consistent with the proxy data, uncertainties remain in different models. More comparison is needed between proxy data and model experiments to better understand the changes of the GM during the LGM.
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1 Introduction
Objectives of the Paleoclimate Modeling Intercomparison Project Phase 3 (PMIP3) are to understand the mechanisms of past climate changes and to test the capability of the models used for future climate projections to represent a climate different from the modern one (Braconnot et al. 2011). Three key time periods of PMIP3 (the Last Glacial Maximum (LGM), mid-Holocene, and Last Millennium) are now included in the Coupled Model Intercomparison Project Phase 5 (CMIP5) within Tier 1 and Tier 2 (Taylor et al. 2012). Simulating the LGM provides an opportunity to study climate response to a decrease in CO2 concentration and an increase in ice sheets over North America and northern Europe, along with the change of the solar irradiance and the land-sea mask. Researchers have investigated regional (Yanase and Abe-Ouchi 2007; Jiang and Lang 2010), hemispheric (Li and Battisti 2008; Laine et al. 2009; Rojas et al. 2009; Chavaillaz et al. 2013; Rojas 2013) and general climatologic features (Braconnot et al. 2007a, b; Otto-Bliesner et al. 2009; Wang et al. (2013b)) responding to the LGM conditions using the PMIP datasets. However, little has been done concerning the changes of the monsoon precipitation during the LGM, especially in the global perspectives.
Global monsoon (GM) represents the dominant mode of annual variation of the Earth’s climate system (Wang and Ding 2008). Study of GM change can advance the understanding of the processes by which the coupled climate system responds to various external forcings. Kim et al. (2008) emphasized the response of the GM precipitation to volcanic aerosols. Wang et al. (2012) found that regional monsoons are coordinated not only by external solar forcing but also by internal feedbacks. It was also found that the Northern Hemisphere summer monsoon (NHSM) intensification is primarily attributed to a Mega-ENSO and the Atlantic Multidecadal Oscillation (AMO), and further influenced by hemispherical asymmetric global warming (Wang et al. 2013a). Liu et al. (2009) examined how the GM precipitation respond to the external and anthropogenic forcing during the last millennium and further investigated mechanisms governing decadal-centennial variations of the global summer monsoon precipitation (Liu et al. 2012). An important finding is that the NHSM precipitation is enhanced by the increased NH land–ocean thermal contrast and hemispheric thermal contrast and it responds to greenhouse gas forcing more sensitively than Southern Hemisphere summer monsoon (SHSM) precipitation, whereas the SHSM precipitation responds to the solar-volcanic radiative forcing more sensitively than the NHSM precipitation.
The changes of the modern and the future monsoon under global warming have been investigated using the observations and models. The global land monsoon precipitation is found to be weakened in the past half century (Wang and Ding 2006; Zhou et al. 2008a; Li et al. 2010), but has seen no significant trend since 1980 despite the rapid intensification of global warming (Zhou et al. 2008b). On the other hand, the total global monsoon precipitation (over both land and ocean) shows increasing trends over the period of 1979–2008. The future change of the GM precipitation and intensity has been investigated (Kitoh et al. 2013; Christensen et al. 2013; Hsu et al. 2013; Chen and Sun 2013; Lee and Wang 2014) using the Representative Concentration Pathways scenarios (RCP4.5 and/or RCP 8.5) for 2006–2100 as projected by models participated in CMIP5. The results show that the GM precipitation will increase over most parts of the GM regions due to the moisture convergence increase, but whether the GM domain will expand or not is inconsistent within these works.
The climate during LGM is quite opposite to the global warming, which can provide a test for the models used to predict future change. Proxy data revealed a stronger East Asian winter monsoon but weaker summer monsoon during glacial periods (Jiang and Lang 2010; Wang 2009). Chabangborn et al. (2014) found that paleo-data and climate model simulation were agreed in a dry LGM climate in the western and northern part of the Asian monsoon region due to a stronger winter monsoon, and/or wetter conditions in equatorial areas of the Asian monsoon region due to a strengthened summer monsoon. However, the sparse reconstruction data in the global monsoon region make it difficult to pin down the uncertainty. The LGM experiments conducted by CMIP5/PMIP3 provide us another way to find out how the GM responds to the changes of external forcing.
Previous works have shown that large uncertainties exist in simulation of the past and future climate change. Some results are model dependent. For instance, Jiang and Lang (2010) found that the East Asian winter monsoon strengthened during the LGM in 10 out of 21 models but weakened in the other 11 models used in PMIP2. Xiang et al. found that some models projected a strengthened Equatorial Pacific trade wind while others projected a weakened one in the future using CMIP5 future change simulations (personal communication). In CMIP5/PMIP3, most models have been upgraded from atmosphere–ocean coupled model (AOGCM) to the Earth System Models (ESM), containing more complex processes than those in PMIP2 models. Harrison et al. (2014) compared PMIP2 and CMIP5/PMIP3 simulations with the reconstructions and found that some models perform better than others. It suggests a careful evaluation of individual model and the Multi-Model Ensemble (MME) are necessary in analyzing the model results.
In the present work, we use the simulated results from 7 coupled models participated in the CMIP5/PMIP3 to investigate the characteristics of GM precipitation change under the LGM boundary conditions, and explore the possible causes of the changes. The models and data used in this study are introduced in Sect. 2. Section 3 evaluates the models’ performance. The analyses and results are shown in Sect. 4. The possible attributions of GM change in the LGM are discussed and concluded in Sect. 5.
2 Model, data and analysis method
2.1 Models and experiments
Among the models participated in CMIP5, only 8 models have finished two PMIP3 experiments for the pre-industrial control (piControl) and the LGM so far. Because of lacking of sea surface temperature (SST) output, FGOALS-g2 is excluded in this study. The results from 7-model piControl and LGM experiments are investigated. The models and experiments used in the study are listed in Table 1. The piControl (0 ka) is used to evaluate the models’ performance and serve as the benchmark for comparing with the LGM.
The boundary conditions (the orbital parameters, the trace gases, the ice-sheet and the land-sea mask) for the LGM experiment are listed and illustrated in Table 2 and Fig. 1. The insolation (viz. incident shortwave radiation at the top of the atmosphere) is also different from the piControl experiment (Fig. 2; http://pmip2.lsce.ipsl.fr/pmip2/design/tables/inso_tables_21k.shtml). More information can be found on the PMIP3 website (http://pmip3.lsce.ipsl.fr/) and in Braconnot et al. (2011, 2012).
To validate the model performance, each model’s output is interpolated into a fixed 2.5° (latitude) × 2.5° (longitude) grid using bilinear interpolation method. The MME of the 7 models (7MME) is constructed by arithmetic mean. Model climatology is obtained from the last 500 model years of each model for the piControl experiment and from the last 100 model years for the LGM experiment.
2.2 Data
The Climate Prediction Center Merged Analysis of Precipitation (CMAP) data (Xie and Arkin 1997) and the Global Precipitation Climatology Project (GPCP) data (Huffman et al. 2009) from 1979 to 2010 are merged by arithmetic mean to serve as the observation data (Lee and Wang 2014). The reason to merge the CMAP and GPCP data sets is to diminish the uncertainty of the individual dataset. Meanwhile, the difference between the CMAP and the GPCP is not significant in terms of climatology. As Lee and Wang (2014) found that the pattern correlation coefficient (PCC) between CMAP and GPCP climatology is 0.95, 0.94, 0.95, 0.96 and 0.96, respectively for annual mean, March–April–May (MAM), June–July–August (JJA), September–October–November (SON), and December–January–February (DJF) seasonal mean precipitation.
The merged precipitation data is also on a fixed 2.5° (latitude) × 2.5° (longitude) grid. The observed climatology is obtained from the 32-year (1979–2010) data.
2.3 Method
The PCC and normalized root-mean-square-error (NRMSE) between the simulation and observation are used to objectively evaluate the performance of the models. The NRMSE is the RMSE normalized by the observed standard deviation that is calculated with reference to the global mean (Lee and Wang 2014).
The signal-to-noise (S2N) ratio is used for the sake of depicting significant changes. In this study, the S2N ratio is defined by the ratio of the absolute mean of the 7MME (as the signal) to the averaged absolute deviation of the individual model against the 7MME (as the noise). Only the areas where the S2N ratio exceeds 1 are discussed in the following sections.
3 Model evaluations
3.1 Annual cycle of precipitation
Wang and Ding (2008) defined two annual cycle (AC) modes of the precipitation according to the EOF analysis of the climatological monthly mean precipitation. The first EOF mode (AC1), representing a solstice global monsoon mode, can be well explained by the difference between June–July–August–September (JJAS) and December–January–February–March (DJFM) mean precipitation. The second EOF mode (AC2), representing an equinox asymmetric mode, can be represented by the difference between April–May (AM) and October–November (ON) mean precipitation. Therefore, in this study, these two AC modes will be evaluated. To depict the monsoon mode (AC1) over the Northern Hemisphere (NH) and the SH separately, the annual range (AR) is used, which is calculated by the difference between the local summer rainfall and local winter rainfall at each location, i.e., JJAS (DJFM) mean precipitation minus DJFM (JJAS) mean precipitation for the NH (SH).
Figure 3a, b show the spatial distribution patterns of the AR and the AC2 derived from the 7MME of piControl runs and the merged CMAP–GPCP. Although the models underestimated the AR over the western Pacific and overestimated the AC2 over the Indian Ocean and southern Pacific, they depict well the general patterns of the AR and AC2, especially the AR. The PCC and NRMSE of the AR (AC2) between 7MME simulation and observation are 0.87 (0.79) and 0.52 (0.72). The individual model’s PCC and NRMSE for the AR are ranged from 0.72 to 0.83 and from 0.61 to 0.95. For the AC2, the individual PCC and NRMSE are ranged from 0.59 to 0.73 and from 0.84 to 1.28 (Fig. 4a, b).
3.2 Global monsoon precipitation intensity and domain
The ratio of the local AR over the annual mean precipitation is used to demonstrate the GM precipitation intensity (Wang and Ding 2008). This ratio reflects how large is the seasonal variation of the precipitation compared with its annual mean. The GM precipitation domain is defined by the regions where the local AR exceeds 2.5 mm/day and the GM precipitation intensity exceeds 0.55 (Wang et al. 2011).
The 7MME captures the monsoon precipitation intensity realistically (Fig. 3c). The PCC and NRMSE of the GM precipitation intensity between 7MME and the observation are 0.88 and 0.47, much better than the individual models, whose PCC and NRMSE are from 0.78 to 0.84 and from 0.56 to 0.69 (Fig. 4c). To evaluate the models’ performance on the monsoon precipitation domains, the threat score is used, which is defined as the number of hit grids divided by the sum of hit, missed, and false-alarm grids (Wang et al. 2011). The threat score of 7MME is 0.64, still higher than those of the individual models, which are ranged from 0.44 to 0.56. The main differences between the simulation and the observation are found over East Asia, Northwest Pacific and South American monsoon regions.
Lee and Wang (2014) evaluated the historical run period of 1980–2005 derived from the 20 CGCMs’ MME participated in the CMIP5. They also found that the simulated monsoon precipitation intensity and domain did not match the observed well over the Western North Pacific–East Asia monsoon region. The disagreement over these regions seems to be a common problem in the state-of-the-art general climate models. It might be related to the difficulty in correctly simulate the annual march of the western North pacific Subtropical high and the treatment of processes related to Tibetan Plateau in the models.
As the 7MME best captures the observed characteristics of the AR, AC2, GM precipitation intensity and domain, we will investigate the changes of the GM precipitation during the LGM mainly based on the 7MME in the following sections. Additional information from individual models is provided when needed to discuss the robustness of the changes.
4 GM changes during LGM
Before examination of the GM change, we briefly discuss the global mean temperature and precipitation changes as a background for understanding the GM changes. The 7MME results indicate that during LGM, the global mean surface air temperature was reduced by 4.43 °C compared to preindustrial period. The decreases of global mean temperature is primarily caused by lower greenhouse gas concentration and the presence of ice sheets because the annual mean insolation is nearly the same. The decrease in temperature dramatically reduced the atmospheric saturation water vapor content according to the Clausius–Clapeyron equation, and thus the total atmospheric moisture content decreased. As a result, the annual mean global precipitation rate during LGM decreased with a rate of 2.26 % per degree of global cooling. We note that the CMIP5 model assessment indicates that the global mean precipitation will increase by 1.9 % per degree global mean temperature rise. The rate of the change of global precipitation is slightly higher under the LGM cooling than under the global warming scenario. But this difference may not be statistically significant and could be due to different MME models. A rigorous comparison should use the same group of models’ MME which is not available.
In comparison, the area averaged annual mean GM precipitation rate is 3.66 mm/day in the present day and 3.30 mm/day during the LGM. There is a reduction of rainfall rate of 0.36 mm/day in LGM or 9.84 % decrease of the GM precipitation rate. Given the global mean surface air temperature reduction of 4.43 °C, it means the decrease of GM precipitation rate is 2.22 % per degree of global cooling. This rate of change is essentially the same as that of the global mean precipitation.
Given this overall picture, in the following subsections we shall further discuss the GM changes in terms of the domain (4.1), intensity (4.2) and seasonal distribution (4.3) as well as the change of Australian monsoon that is unique due to change of the land–ocean configuration accompanied by decreased sea level during LGM.
4.1 Global monsoon domain change
The ensemble mean GM domain is reduced over most monsoon regions except Australian monsoon (Fig. 5). The total global monsoon area is reduced by 5.5 % during the LGM, the NH monsoon area reduced by 7.3 % and the SH monsoon area reduced by 3.4 % (Table 3). The reduction of global and NH monsoon areas are consistent across individual models (Fig. 6). However, the reduction of the SH monsoon domain area has large spread among individual models, thus inconclusive. The changes of the sub-monsoon areas over the SH are much larger than those over the NH (Fig. 6; Table 3).
For the NH, the sub-monsoon areas are reduced 8.7, 7.3 and 4.3 % over Asia, northern Africa and North America, respectively. In addition, the Asian and North American monsoon domain are shifted southeastward, especially their northwest ridges. Six models have simulated the shifting except MRI-CGCM3. The shift of the Asian monsoon domain is consistent with the palaeo-data (Chabangborn et al. 2014) and opposite to the simulated northward shift of the Asian summer monsoon circulation under CO2 doubling (Kitoh et al. 1997). Braconnot et al. (2007b) also found that some of the models participated in PMIP2 simulated a southward shift of the intertropical convergence zone (ITCZ) over the continents and the Indian Ocean, which was in agreement with the results found from marine data (Leduc et al. 2007). Since the ITCZ in monsoon region is referred to as a monsoon trough, the shift of the ITCZ is consistent with the shift of the monsoon domain. Theoretically, the ITCZ always tends to shift toward the warmer ocean. During the LGM, the SST is decreased more over the mid-high latitudes than over the tropics (Fig. 7), and more over the northern tropics than over the southern tropics. The southern tropical ocean is a little warmer than the northern tropical ocean, which favors the southward shift of the ITCZ. In addition, there is no La Nina or El Nino like signal during the LGM, which is also not clear in the PMIP2 simulations (DiNezio et al. 2011).
For the SH, the changes of sub-monsoon domain are inhomogeneous. The South America and southern Africa monsoon domains are reduced by 15.6 and 13.4 %, respectively, while the Australian monsoon domain is dramatically enlarged by 36.4 %. All the models simulate the shrink of the South American monsoon domain. The results of the most models, except the CNRM-CM5 and MPI-ESM-P, are agreed in the reduced South African monsoon domain. The enlargement of the Australian monsoon domain is simulated by most models except MPI-ESM-P (Fig. 6).
The smaller changes of NH monsoon domain in LGM may be partially related to the fact that the domains tend to shift southeastward due to the cooling effects of the two ice sheets located over the NH high latitude (Fig. 1). The shrink of the total domain area may primarily due to the global cooling and reduction of moisture availability induced by the lower greenhouse gas concentration, as well as the reduced insolation during summer and increased insolation during winter (Fig. 2). The radiative forcing does not change the annual mean GM but tends to reduce the AR of the NH monsoon due to seasonal redistribution of insolation associated with the precession cycle. On the other hand, there are no shifting in the SH sub-monsoons. The shrink of the southern African and South American monsoon domain is likely due to a combination of the cooling associated with the reduced greenhouse gas concentration and the reduced AR in insolation. In the ocean-dominant SH, the monsoon is more sensitive to the reduction of moisture content due to global cooling. The drastically enlarged Australian monsoon domain, as will be discussed in 4.4, might be ascribed to the expanded land area and the strengthened seasonal land–ocean thermal contrast and NH–SH thermal contrast.
4.2 Global monsoon intensity change
The monsoon intensity measured by the annual range and/or the amount of local summer rainfall indicates weakening monsoons over Asian, northern African, North and South American, and the northern part of southern African monsoon regions, whilst a strengthening occurring over Australian monsoon region, a small area in subtropical East Asia, and far southern African monsoon region (Fig. 8). The monsoon region used here and after refers to the fixed present day monsoon region. The annual mean precipitation shows similar changes as the summer monsoon precipitation over most monsoon regions except the Australian monsoon region. The annual mean precipitation over the northern Australia is slightly reduced in spite of the Australian summer monsoon intensified. This means that Australian monsoon precipitation is reduced in other seasons than local summer. Despite the outliers, the area averaged annual range derived from the 7MME and models are decreased over the global, the NH and most regional monsoon areas except the Australian monsoon region, which is increased on the contrary (Fig. 9).
The reduced annual ranges over all NH monsoon regions are mainly due to the decreasing JJAS mean precipitation, i.e. the boreal summer precipitation is decreased much more than the boreal winter counterparts (Fig. 10a, b). The precipitation over South American and northern part of the Southern African monsoon regions is decreased in DJFM (austral summer) while increased in JJAS (austral winter), which leads to the reduction of the annual range over these two monsoon regions. This change may be caused by the changes in the annual distribution of insolation. On the contrary, for the Australian and far southern African monsoon regions, the annual range are increased during the LGM, as a consequence of the wetter austral summer and drier austral winter (Fig. 10). This indicates the change of the local summer rainfall plays important role in the change of the annual range.
In addition, the precipitation over the Northern Australia is only increased in DJF while decreased in the other three seasons (not shown), which explains why the annual mean precipitation over this region is slightly decreased while the annual range is increased.
4.3 The change of the seasonal distribution of global monsoon
The variation of GM precipitation computed here is also based on the fixed present day monsoon domain.
While the annual mean GM precipitation is reduced due to decreased greenhouse gas forcing and the existence of ice sheets, the reduction of the GM precipitation shows obvious seasonal variation. The GM precipitation is reduced more from May to September, and less from November to March (Fig. 11a). The large reduction in July–August or in general from May to September is dominated by the reduction of precipitation in NH monsoon, including all three regional components: the North American, Asian, and northern African monsoons (Fig. 11b). During the austral summer, especially from November to December, the reduction of NH winter monsoon precipitation is minimal and the change in SH summer monsoon is small except the large reduction of South American monsoon. That is why the global monsoon precipitation reduction is minimal in November and December.
For the NH, all regional monsoon precipitation changes quite consistently, with decreasing more from June to October (maximal in August), and less from December to May (Fig. 11b). On the other hand, the SH sub-monsoon precipitation changes differently, especially the Australian monsoon precipitation (Fig. 11c). The seasonal variation of southern African monsoon precipitation is small, which can be explained by the aforementioned different changes between the northern and southern part of this region. The South American winter monsoon precipitation is increased slightly from July to October, while the summer monsoon rainfall is decreased notably from January to March. The Australian monsoon precipitation has the largest changes, which is slightly increased in November and December (austral summer) and substantially decreased from April to September (austral fall-winter). The reduction of the fall-winter monsoon precipitation and the increase of the summer monsoon precipitation explains why the Australian annual mean precipitation is decreased, but its annual range and monsoon intensity are significantly increased (Fig. 11c).
Although some uncertainties exist in the change of the SH monsoon precipitation from December to May, all the models and the 7MME are agreed in the change from June to November and the change of the NH monsoon precipitation seasonal distribution (Fig. 12).
While the general reduction for the monsoon precipitation can be attributed to the effects of greenhouse gas forcing and ice sheet forcing, the changes in the seasonal distributions of the GM and NH sub-monsoon precipitation are likely related to the insolation change (Fig. 13), i.e., the monsoon precipitation is reduced more when the insolation is reduced and less when the insolation increased. For the SH sub-monsoon precipitation, the seasonal distribution lags the seasonal change of the insolation for one or two seasons. The large heat capacity of the ocean regulates the lagged response of the SH monsoon precipitation to the change of the insolation. The nearly simultaneous response in the NH monsoon suggests the ocean regulation effect is small, possibly due to the presence of the ice sheet effect but the precise reason needs further investigation.
4.4 Changes of the Australian monsoon
As mentioned above, the Australian monsoon shows a distinctive change amongst all components of regional monsoons. Here we zoomed into it to find out what was happening during the LGM.
The precipitation is reduced significantly during the austral autumn and winter, while is increased during the austral spring and summer (Fig. 14). The wetter local spring-summer and the drier local autumn–winter is consistent with the strengthened monsoon intensity (AR) and the enlarged monsoon domain as mentioned above. Among the 7 models, most of them simulate an increasing austral summer precipitation rate over land mass, except CNRM-CM5 and MPI-ESM-P. The increased local summer rainfall is consistent with the proxy reconstruction hypothesis resulted from a high austral summer insolation (20°S, December) (Ding et al. 2013).
The change of the Australian monsoon precipitation is related to the change in atmospheric circulation, for instance the convergence at 850 hPa over the monsoon region, which is strengthened during the austral summer (DJF) while weakened during the austral winter (JJA) (not shown). During DJF the westerly at 850 hPa over the eastern Indian Ocean and the cross equatorial flow from South China Sea are strengthened (Fig. 15a). On the other hand, the JJA mean wind difference at 850 hPa shows a divergence circulation over northern Australia (Fig. 15b). The changes of the seasonal wind and divergence fields explain the changes of the seasonal precipitation. 6 models (except MPI-ESM-P) simulate a strengthened DJF convergence over the land mass, 5 of which are agreed with the increased rainfall (except CNRM-CM5).
The strengthened Australian monsoon is also related to the change in seasonal NH–SH thermal contrast. The NH is warmer than the SH during the present day while much cooler during the LGM. The annual mean NH surface air temperature is 14 °C during the present day and is reduced to 8.2 °C during the LGM, and the annual mean SH surface air temperature is reduced from 13.3 °C (present day) to 10.3 °C (LGM). The JJA mean NH minus SH thermal contrast is weakened during the LGM (from 9.3 °C in the piControl to 7.8 °C in the LGM), and DJF mean NH–SH thermal contrast is strengthened (from −8.1 to −11.9 °C). Such changes in seasonal NH–SH thermal contrast may induce a strengthened cross-equatorial flow during austral summer, remarkably over eastern Indian Ocean to western Pacific Ocean regions (Fig. 15a), and therefore induces the strengthened Australian monsoon.
Because of the enlarged landmass, the land–ocean thermal contrast around the Australian monsoon region is strengthened in three seasons (MAM, JJA, SON), except DJF, as seen through the change of the surface air temperature (Fig. 16). As a sequence of the land–ocean thermal contrast increase, there is already a differential cyclonic circulation in SON over west of the Australian monsoon region, which maintains till DJF to strengthen the convergence over the monsoon region. The zonal departure of the SST from the area average of (30°S–30°N, 120°E–180°E) (not shown) indicates a strengthened NH–SH asymmetry in boreal winter, which is also consistent with the change of the monsoon intensity.
5 Conclusion and discussion
By comparing the simulated climatological GM and precipitation from the LGM and the piControl experiments, we find the GM changes have the following features.
-
1.
The global monsoon area is reduced during the LGM. However, the changes of the sub-monsoons are not uniform. The changes of the sub-monsoon domain over the NH are smaller than those over the SH. Regionally, the Asian, northern African and North American monsoon areas are reduced by 8.7, 7.3 and 4.3 %, respectively, with the southeastward shifting of the Asian and North American monsoon domain. In contrast, in the SH, the South American and southern African monsoon areas are reduced respectively by 15.6 and 13.4 %, while the Australian monsoon area is dramatically enlarged by 36.4 %.
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2.
The monsoon intensity measured by the annual range of the precipitation is weakened over most part of the GM regions except the Australia and southern part of the southern Africa, mainly contributed by the decreasing of the local summer precipitation.
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3.
The GM precipitation is reduced generally. The global and the NH monsoon precipitation are reduced more during the local summer and less during the local winter, in accordance with the change in seasonal distribution of the insolation. While the seasonal variation of the NH monsoon precipitation is nearly in phase with the seasonal change of the insolation, the SH monsoon precipitation especially the Australian monsoon precipitation lags the seasonal distribution of the insolation change by one or two seasons.
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4.
The Australian monsoon is strengthened and the monsoon area is enlarged uniquely. The strengthened Australian monsoon intensity is contributed by the increased local summer rainfall and the decreased local winter rainfall. The increased austral summer (DJF) rainfall is mainly caused by the strengthened land–ocean thermal contrast in SON due to the sea level change during the LGM, which leads to a strengthened convergence in DJF.
The aforementioned changes in GM is a combined consequence of the four major factors: the reduced greenhouse gas concentration, the presence of the ice sheets over Eurasian and North American continent, the changes in the annual distribution of insolation caused by changing orbital forcing, and change of land configuration due to lowering sea level. Each of the four factors plays different roles in changing the GM and its regional component.
The weakening of annual mean global monsoon precipitation is primarily attributed to the lower greenhouse gas concentration in the atmosphere (Table 2) and the presence of the Fennoscandian and Laurentide ice sheets in the NH (Fig. 1, shading). Since the global annual mean insolation only changed 0.02 W/m2, its contribution to global mean change is negligible. On the other hand, the CO2 radiative forcing (RF) was reduced by 2.22 W/m2, which contributes significantly to the reduction of the global annual mean surface air temperature (GMT). Here the simplified formula is used to estimate the RF of the CO2: RF = 5.35 × ln(CO2/CO2_orig) (IPCC TAR 2001), where CO2 = 185 ppm and CO2_orig = 280 ppm. The result derived from the 7MME indicates that during LGM the GMT is decreased by 4.4 °C with more over the NH (5.8 °C) and less over the SH (3.0 °C). A large portion of the reduction may be attributed to the greenhouse gas forcing change that is enhanced by the existence of the ice sheets.
A direct consequence of the global cooling is the reduction of the moisture content in the atmosphere. The Clausius–Clapeyron equation predicts a 7 % reduction in saturation humidity per degree of global cooling in the present day climate. The reduction of the moisture content in the atmospheric column follows the reduction of the saturation humidity closely. Such a large reduction in available moisture in the atmosphere can reduce the monsoon precipitation substantially assuming the atmospheric circulation unchanged. This so-called “dry-gets-drier” mechanism (Held and Soden 2006; Wang et al. 2012; Lee and Wang 2014) is certainly an essential explanation to the weakening of the global mean monsoon precipitation.
Note also that the presence of the Fennoscandian and Laurentide ice sheets in the NH play important role in the LGM climate change. Chiang and Bitz (2005) found that the ITCZ would shift southwards due to a wind-evaporation-SST feedback induced by the anomalous ice. Donohoe et al. (2013) also found a southward shift of the ITCZ in the LGM. As stated in Sect. 4.1, the southward shifting of the ITCZ is consistent with the shift of the NH monsoon domain. We found that the two presented ice sheets during the LGM trigger two cyclonic difference circulations at mid-high level (500 and 200 hPa, not shown) over the eastern landmass during JJA, especially over the eastern North America. The strengthened northwest flows over the mid-high latitude to the East Asian and North American monsoon regions push the two monsoon domains shift southward and eastward.
Ueda et al. (2011) found that for the mature period of the Asian summer monsoon, the ice sheet effect emerged to cool the atmospheric temperatures throughout the troposphere and might weaken the summer monsoon circulation. Kim (2004) simulated the effect of lower CO2 concentration and ice sheet topography on the LGM climate separately. They found that the surface cooling was substantially larger in the NH than in the SH for both cases and was more pronounced in the ice sheet topography case. In this study, we find that the changes in seasonal NH–SH thermal contrast may induce the strengthened Australian monsoon. It may also be attributed to the lower greenhouse gas concentration and the presence of the ice sheets during LGM.
The change of the insolation forcing, although does not affect the mean GM, it may contributes to the seasonal distribution of the GM thus change the annual range and the GM intensity. The GM is a response of atmosphere–land–ocean coupled system to the annual variation of solar radiation (Wang and Ding 2008). During the LGM, for both the NH and SH, the hemispheric insolation is increased during the local winter while decreased during the local summer (Fig. 13), especially over the NH, which means the annual variation of solar radiation is weakened during the LGM. The annual variation of the global insolation is reduced by 3.85 W/m2, likely leading to a weakened GM intensity. How far would the insolation change influence the GM? Numerical experiments with changing orbital forcing only might provide a clue. This calls for further study.
For the Australian monsoon region, the land-sea mask is changed during the LGM because of the change of sea level, and the Maritime Continent and Australia becomes an expanded continent, especially over the equatorial regions (Fig. 1, red line). The change of the land–ocean thermal contrast is quite on the contrary between the Australian monsoon region and the southern African and South American monsoon regions. The strengthened land–ocean thermal contrast between the Australia and its adjacent Pacific Ocean favors the Australian monsoon precipitation and therefore enlarges the monsoon domain. For the other two monsoon regions over the SH, the southern African and the South American, the weakened land–ocean thermal contrast leads to the reduced monsoon precipitation and the monsoon domain.
It is important to point out that the qualitative discussion here cannot assess the quantitative contributions of the each factor to the monsoon changes. More sensitivity experiments are needed for understanding the relative contributions of these four factors to changes of the global, NH and SH monsoons, as well as regional monsoons.
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Acknowledgments
We acknowledge the reviewers and Prof. Zhu AX for the constructive comments helping to clarify and improve the paper. This work is jointly supported by the National Basic Research Program (Grant No. 2015CB953804), the Strategic and Special Frontier Project of Science and Technology of the Chinese Academy of Sciences (Grant No. XDA05080800), the National Natural Science Foundation of China (Grant Nos. 41302137, 41371209 and 41420104002), and A Project Funded by the Priority Academic Program Development of Jiangsu Higher Education Institutions (PAPD). Bin Wang acknowledge support from the National Research Foundation (NRF) of Korea through a Global Research Laboratory (GRL) grant of the Korean Ministry of Education, Science and Technology (MEST, #2011-0021927) and the support from China-US Atmosphere–Ocean Research Center. We also acknowledge the World Climate Research Programme’s Working Group on Coupled Modelling, which is responsible for CMIP, and we thank the climate modeling groups (listed in Table 1 of this paper) for producing and making available their model output. For CMIP the US Department of Energy’s Program for Climate Model Diagnosis and Intercomparison provides coordinating support and led development of software infrastructure in partnership with the Global Organization for Earth System Science Portals. This is the Earth System Modeling Center (ESMC) Contribution Number 065.
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Yan, M., Wang, B. & Liu, J. Global monsoon change during the Last Glacial Maximum: a multi-model study. Clim Dyn 47, 359–374 (2016). https://doi.org/10.1007/s00382-015-2841-5
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DOI: https://doi.org/10.1007/s00382-015-2841-5