Introduction

Indian summer monsoon rainfall determines to a large extent food production for subcontinental India and has major socioeconomic impacts. Simulating monsoon precipitations variability from intra-seasonal to interannual timescales is identified as major challenge, especially in the context of climate change and increasing anthropogenic pressures over the Indian subcontinent. The complexity of the monsoon system arises from the interactions between physical processes involving atmosphere, land and ocean and operating over a wide range of spatial and temporal scales (Turner and Annamalai, 2012). The role of aerosol as a possible factor modifying these interactions, with consequences on precipitation variability, has been a subject of intense study for the last decade (Lau et al., 2008).

There are basically two mechanisms invoked when discussing the climatic response to direct aerosol forcing over southern Asia. The “solar dimming effect” (Ramanathan et al., 2005) proposes that the reduction in surface solar radiation due to absorption and scattering by aerosols, which shows a regional maximum over northern India and Indian ocean, induces a reduction of the north–south surface temperature gradients resulting in a weakening of the Indian summer monsoon. Consistently with this mechanism, the observed summertime drying trend observed over the central Indian region since 1950 has been attributed to increased anthropogenic aerosol emissions through a slowdown of the tropical meridional circulation (Bollasina et al., 2011). In contrast the “elevated heat pump effect” (Lau et al., 2006) proposes that radiative heating anomalies due to anthropogenic black carbon and dust transported over the Himalayan foothill and Tibetan plateau during the dry and pre-monsoon seasons enhance meridional tropospheric temperature gradients, resulting in a strengthening and earlier onset of the Indian monsoon rainfall. The elevated heat pump effect has, however, been questioned by Nigam and Bollasina (2010). Though apparently antagonistic, both these mechanisms might be effective at different stages of the pre-monsoon and monsoon development (Meehl et al., 2008), indicating the complexity of aerosol climate feedbacks operating on different timescales. In addition it has been outlined that the regional impact of Asian aerosol might be reinforced by non-Asian sources through long distance transport and global dynamical adjustments (Bollasina et al., 2013; Ganguly et al., 2012; Cowan and Cai, 2011; Wang et al., 2009).

Despite a large focus on anthropogenic aerosol effects justified by the observed intensification of emissions contributing to the “Asian brown cloud” (Ramanathan et al., 2005), the potential importance of natural, and in particular dust, aerosol has been also recently highlighted (Jin et al., 2014; Vinoj et al., 2014): tt is suggested that west Asian dust outbreaks can induce a fast and regional atmospheric response which could explain observed positive correlation between aerosol optical depth (AOD) over west Asia and summer precipitation over India on a weekly timescale. Using global circulation model (GCM) experiments with prescribed sea surface temperature (SST), Vinoj et al. (2014) attributes the cause of this correlation to the large radiative heating induced by dust radiation absorption over Arabia and the Arabian Sea resulting in an intensification of southwesterly moisture convergence towards India. This mechanism involves primarily direct and semi-direct aerosol effects and is based on a fast reaction of monsoonal weather systems to dust radiative heating perturbation.

The question of characterizing the impact of west Asian dust on the Indian monsoon becomes even more relevant when we consider another striking fact: the observed recent enhancement of Arabian dust activity as measured by satellite and ground-based AOD observations during the past decade. Based on Sea-viewing Wide Field of View Sensor (SeaWIFS) satellite observations, a significant June–July–August increasing AOD linear trend has been determined for the period 1998–2010 for the Arabian region (Hsu et al., 2012). This regional trend, associated with a regional increase of dust storm activity, is also detected in ground-based photometer measurements from the Aerosol Robotic Measurement Network (AERONET) at the Solar village site in Saudi Arabia (Xia, 2011). To our knowledge, the attribution of this regional emission increase to climatic factors and/or land use change is yet to be fully investigated. Ginoux et al. (2012) discuss the possible increasing contribution anthropogenic dust sources relevant to the region, and we also indicate later some possible connections with the evolution of low-pressure conditions over the Arabian Sea and the Indian monsoon system.

In this context, the questions we wish to primarily address here are as follows: what are the main characteristic of dust radiative forcing regional climatic feedbacks, and to what extent could the recent enhancement of dust activity in the Arabian region affect the Indian monsoon dynamics and precipitations on a decadal timescale? As dust emissions might evolve naturally or/and as a result of climate and land use change (Mahowald, 2007; Mulitza et al., 2010; Yoshioka et al., 2007), characterizing and quantifying the regional climate implications of observed dust variability is especially relevant for a better understanding of the Indian monsoon system variability and its possible evolution.

Toward this goal, we use a 50 km resolution regional climate model coupled to an aerosol scheme and a slab-ocean model together with diverse observation and reanalysis products. Specific attention is paid to the quality of the simulated Indian monsoon circulation and precipitation fields as well as to the representation of aerosols notably in term of sources, optical depth, radiative forcing and heating rates gradients. In our approach, we believe that the simulation domain size is large enough to capture important regional dynamical feedbacks to the aerosol radiative perturbation. As a caveat we acknowledge that large-scale dynamical feedbacks arising from the possible aerosol-induced excitation of planetary waves (Rodwell and Jung, 2008) cannot be accounted for using a limited area model. Knowing in what proportion the effective regional climatic response to aerosol forcing is dominated by regional vs. global dynamical adjustments is, however, a matter of debate (Ramanathan et al., 2005; Bollasina et al., 2011; Ganguly et al., 2012; Cowan et al., 2011). In Sect. 1 we detail the modeling experiments as well as the different data sets and methods used for trend calculation. Section 2 focuses on analyzing observed summer AOD and precipitation trends and interannual correlations over the domain. Dust radiative and climatic impacts and the possible links between Arabian dust trend and southern India precipitation at the decadal scale are then addressed in Sects. 3 and 4.

Data and methods

Regional climate model

We use the International Center for Theoretical Physics regional climate model RegCM4 (Giorgi et al., 2012) at 50 km resolution. Runs are performed on the COordinated Regional climate Downscaling Experiment (CORDEX)-India domain over the period 1999–2009 including a 1-year spin up. Boundary conditions are provided by ERA-Interim reanalyses through a 1000 km buffer zone. The Newtonian relaxation to large-scale fields applied in the boundary buffer zone is designed to limit wave reflections in the domain as much as possible (Marbaix et al., 2003). Important physical options we used for this study are the Community Land Model version 3.5 (CLM3.5) (Tawfik and Steiner, 2011), the University of Washington turbulence scheme (O'Brien et al., 2012) and the Emanuel convection scheme (Emanuel, 1991) with enabled tracer transport capabilities. The RegCM4 aerosol scheme includes a representation of anthropogenic sulfates, black and organic carbon (Solmon et al., 2006; Qian et al., 2001) as well as sea-salt and dust aerosol. For anthropogenic emissions, we use the Regional Emission inventory in ASia (REAS) (Ohara et al., 2007; Nair et al., 2012) completed by the Atmospheric Chemistry and Climate Model Intercomparison Project (ACCMIP) emissions (Lamarque et al., 2010) to account for biomass burning emissions and REAS-uncovered regions. For natural particles, sea-salt aerosol emissions are calculated online and are represented by two (sub- and super-micronic) different bins (Zakey et al., 2008). The dust emission scheme (Marticorena and Bergametti, 1995; Zakey et al., 2006) includes updates of soil texture distribution following Menut et al. (2013) and emission size distribution (Kok, 2011; Nabat et al., 2012). Lateral boundary conditions for aerosols are prescribed from a decadal climatology obtained from global runs performed using CAM-Chem model (J. von Hardenberg, personal communication, 2014). Dusts are represented using four bins and impact short- and long-wave radiation transfer as detailed in the Supplement (Table S1). All other aerosols impact the RegCM shortwave radiation scheme through pre-calculated optical properties (Solmon et al., 2006). Only the first indirect effect is accounted for and applied to sulfate aerosol (Giorgi et al., 2003).

Of particular importance for studying aerosol effects (Miller et al., 2004; Zhao et al., 2011), we implemented in RegCM4 a “flux-corrected” slab-ocean parameterization following an approach used in the FMS model (http://www.gfdl.noaa.gov/fms-slab-ocean-model-technical-documentation). This parameterization assumes a 50 m depth ocean mixed layer for which we calculate a prognostic SST through a simple energy budget. The lack of ocean dynamics, diffusion and convection as well as other model surface flux errors are compensated by specifying surface flux adjustments ($q$ flux adjustments) to the slab temperature tendency equation, notably in order to maintain a realistic SST seasonal cycle compared to observations. To derive the $q$ flux terms, we perform first a “restoring run” (with no interactive dust aerosol) where the slab prognostic SST are restored to observations, taken here as the Optimum Interpolation Sea Surface Temperature (OISST) (Reynolds et al., 2002), and considering a 5-day restoring timescale. As the slab mixed layer model is integrated (over the 1999–2009 period in this experiment), the restoring heat fluxes ($q$ flux) calculated through this procedure are archived and saved in a monthly mean climatology at the end of the restoring run. Once the $q$ flux climatology is built, the control and experimental “adjusted runs” are performed accounting for $q$ fluxes (prescribed from the climatology) in the slab-ocean temperature equation. Over the domain, seasonal average differences of SST between the $q$ flux adjusted control experiment and OISST observations vary in the range of $-$1 to 1${}^{\circ }$, ensuring that prognostic SSTs in the adjusted runs do not diverge much from observations and follow a realistic seasonal cycle. This approach extends previous aerosol regional climate studies based on forced SST over the Indian monsoon and other domains (e.g., Das et al., 2014).

The control experiment consists of three ensemble members of adjusted runs with no interactive dust aerosol activated (nodust). An ensemble of three adjusted runs is then performed with activation of dust (dust). Additionally, a sensitivity test consisting of removing the Indo-Pakistani regional dust source (dust_noIP) is also performed. Finally an experiment of three ensemble members is done by imposing an increasing emission trend over Arabia in order to better reproduce observed AOD trends (dust_ft). This is done by increasing the saltation flux erodibility factor (Marticorena and Bergametti, 1995) during the run. From year 2004 to 2009 the corresponding increase of erodibility factor is about 30 %. In order to limit the effect of internal variability on our analysis of the aerosol feedbacks, we impose a small random perturbation in boundary conditions to every ensemble member during the run following O'Brien et al. (2011). With this technique, we increase the filtering of noise vs. statistically significant physical signal while performing differences between the ensemble means of perturbed and control run experiments. All results, figures and discussion are based on ensemble means.

Aerosol optical depth trend calculation

June–July–August–September (JJAS) AOD linear trend calculations are first performed using SeaWIFS monthly AOD (550 nm) products at 0.5${}^{\circ }$ and regridded on the 50 km RegCM grid. Algorithms and validity of AOD retrievals from SeaWIFS atmospheric corrections are discussed in Sayer et al. (2012a, b). Moreover, as argued in Hsu et al. (2012), the SeaWIFS AOD product is recognized as a “stable” data set minimizing sensor calibration impact on trend analysis. For each model grid column, the SeaWIFS AODs are first deseasonalized applying a 13-term moving average for trend first guess and a stable seasonal filter for removing of the seasonal cycle (Brockwell and Davis, 2002). The deseasonalized times series of JJAS 2000–2009 are then extracted and a linear regression is applied on this subset to determine the JJAS linear trend. Statistical significance of the trend is determined using an $F$ test and we plot only statistically significant pixels with a significant non-zero slope ($p$ value $<$ 0.05). Over our region of interest this treatment shows much consistency with the results of Hsu et al. (2012). The same method is applied to simulated monthly AOD time series for model–measurement comparison. Over the particular location of Solar Village, the deseasonalized JJAS AOD time series is also calculated from the Aerosol Robotic Network (AERONET) monthly optical depths and considering the average of AODs measured at 440 and 640 nm.

In addition to SeaWIF, we also make use of the Multiangle Imaging Spectro-Radiometer (MISR; Martonchik et al., 2004) retrievals for the validation of mean AOD and further interannual variability analysis.

Precipitation trend calculation

For the 2000–2009 precipitation trend calculation over southern India (Fig. 1b), we use the University of East Anglia Climate Research Unit product (CRU) (Harris et al., 2014), the Tropical Rainfall Measuring Mission (TRMM 3B42) (Huffman et al., 1995) product, the University of Delaware product (UDEL) (Matsuura and Willmott, 2009) and the Precipitation Estimation from Remotely Sensed Information using Artificial Neural Networks (PERSIANN) product (Ashouri et al., 2015). For each data set, monthly precipitation time series are first geographically averaged over a continental southern Indian box (5–20${}^{\circ }$ N, 60–80${}^{\circ }$ E). Deseasonalized time series are produced following a similar method than for AOD treatment. A yearly series of JJAS average precipitation is then produced by averaging the different deseasonalized series from each data sets and keeping the minimum and maximum values for estimation of the spread between different observation data sets.

Arabian AODs and southern India deseasonalized precipitation trends during the decade 2000–2009. (a) The thick blue line represents monthly deseasonalized time series of JJAS AODs obtained from the Solar Village AERONET station (monthly product, average of 480–640 nm spectral bands). A quadratic regression fit, showing the progressive intensification of observed dust activity, is superimposed (blue curve). The blue hatched line represents the deseasonalized AOD time series obtained from SeaWIFS AOD interpolated on the Solar Village station. The green lines represent the monthly deseasonalized time series (as well as the corresponding quadratic fit) of JJAS AODs simulated by the model in dust simulation. The red lines represent the monthly deseasonalized time series (as well as the corresponding quadratic fit) of JJAS AODs simulated by the model with forced dust emission trends (dust_ft simulation). (b) The blue line represent the yearly time evolution of observed continental precipitation averaged for JJAS, over a southern India box (5–20${}^{\circ }$ N, 60–80${}^{\circ }$ E) and for different data sets (TRMM, CRU, PERSIANN). The blue bars materialize the amplitude between maximum and minimum values amongst observations for a given year. The equivalent deseasonalized JJAS average simulated precipitations are reported for the nodust simulations (black line), the dust standard simulations (green line) and the forced emission trend dust_ft simulations (red line). All modeling results represent a three-ensemble-member mean.

[Figure omitted. See PDF]

Additionally, for the evaluation of simulated mean JJAS precipitation we also use the Asian Precipitation – Highly Resolved Observational Data Integration Towards Evaluation of water resources (APHRODITE) data set over the 2000–2007 period (Yatagai et al., 2012).

AOD vs. precipitation trends and interannual variability correlations

Linear trends of JJAS AODs, calculated from SeaWIFS observations over our domain (cf. Sect. 2), are presented in Figs. 1 and 3a. As already reported in Hsu et al. (2012), a significant positive trend is found over the Arabian Peninsula region. In addition, a positive AOD trend observed at the AERONET station of solar village (Xia, 2011) is also reported (Fig. 1a). As discussed in Hsu et al. (2012), a decreasing trend in AERONET-retrieved Ångstrom coefficients has been observed at Solar Village, indicating an enhanced contribution of larger particles to AODs over the decade. Together with the fact that AOD trends are due to an amplification of seasonal cycle coincident with dust seasonal maximum, this indicates that the Arabian region positive AOD trends are mainly due to increasing dust emission activity vs. a possible anthropogenic contribution. From the time series in Fig. 1a, we note that the JJAS observed deseasonalized AODs tends to steepen around year 2005. Consequently the 2005–2009 pentad shows sensibly higher averaged AODs relative to the 2000–2004 pentad. For simplifying the following discussion we will refer to these pentads as “NONDUSTY” and “DUSTY”.

Interannual variability correlation coefficients calculated between deseasonalized summer (JJAS) AODs and deseasonalized JJAS precipitations averaged over a southern India box (5–20${}^{\circ }$ N, 60–80${}^{\circ }$ E): (a) based on the SeaWIFS AOD retrieval over the 1999–2010 period and (b) based on MISR AOD retrieval over the 2000–2010 period. Pixels showing monthly AOD $<$ 0.2 are excluded from the calculation as well as pixels for which sampled valid year number is less than 8.

[Figure omitted. See PDF]

An increasing trend for precipitation over southern and eastern India is also detected in several data sets as illustrated in Fig. 1b. In a rather similar way to Arabian AODs, the observed JJAS precipitation in Fig. 1b shows a relative intensification for DUSTY relative to NONDUSTY pentads. If we plot the mean surface pressure and circulation differences between DUSTY and NONDUSTY pentads from ERAI and NCEP2 reanalyses (Figs. 4a and S3), we observe that both data sets show a cyclonic pattern over the eastern Arabian Sea and India with enhanced southwesterly circulation toward continental India. The associated increase of moisture flow over southern India is a likely reason for enhanced precipitation during DUSTY pentad relative to NONDUSTY pentad observed in precipitation data sets in Fig. 1b.

Linear JJAS AOD trend calculated over the 2000–2009 period from (a) SeaWIFS monthly observations, (b) model standard dust simulations and (d) model dust_ft simulations including a forced emission trend over the Arabian Peninsula. Only statistically significant trends ($p$ value $<$ 0.05) are represented (cf. Sect. 2). All modeling results represent a three-ensemble-member mean.

[Figure omitted. See PDF]

Furthermore, the cyclonic pattern found in pentad differences depicts a relative increase of the frequency/intensity of low-pressure situations over the northern Arabian Sea for DUSTY relative to NONDUSTY pentad. Such conditions are favorable to enhanced Shamal wind (Hamidi et al., 2013; Notaro et al., 2013) and could thus be a likely reason for the observed increase of AODs during the decade. On short timescales, it is also known that individual storms moving in the Arabian Sea and the northern Bay of Bengal can trigger large dust emission from Arabia and the Indo-Pakistani–Iran desert regions (Kaskaoutis et al., 2014; Ramaswamy, 2014). Based on these observations, both enhanced precipitation over India and Arabian dust AODs increase could be linked to lower pressure conditions prevailing over the Arabian Sea during DUSTY relative to NONDUSTY pentads. Reasons for these conditions are likely a feature of climate decadal variability over the region (Patra et al., 2005) and further analysis is beyond the scope of this study.

If the arguments developed above are valid, one should also expect a possible correlation between the interannual variability of summer dust AODs and precipitation over southern India. This correlation is not obvious in Fig. 1 for the case of Solar Village AODs. In order to get a more regional picture, we extend our analysis by calculating interannual correlations between observed deseasonalized summer AODs (based on SeaWIFS and MISR data) and deseasonalized summer precipitation over the previously defined southern India box (based on the PERSIANN data set). We consider the 1999–2010 period for SeaWIFS and 2000–2010 for MISR, excluding pixel with JJAS AOD $<$ 0.2 in the process. Pixels with less than 8 years of valid JJAS observations over the period are excluded of the correlation calculation as well. Evident caution must be taken while interpreting the values of correlation coefficients due to the limited sample size. Nevertheless, in Fig. 2a and b our analysis reveals clear regional patterns: over the Indo-Pakistani source region both MISR and SeaWIFS deseasonalized summer AODs tend to be anti-correlated with southern Indian deseasonalized precipitations. Inversely, over Arabia, positive correlation coefficients tend to be observed for both MISR and SeaWIFS. This analysis has been repeated using the TRMM precipitation data set with no significantly different results (not shown here). Despite the fact that correlations are not very strong, the homogeneity of regional patterns and their consistency through different observational data sets lead us to think that a relation exists between the interannual variability of dust sources activity and Indian precipitation. This relation is in line with the previous argument linking cyclonic activity in the Arabian Sea, associated with more summer precipitation over India and Pakistan, and enhanced Arabian dust emissions. Contrarily to the Arabian Peninsula, the Indo-Pakistani region is affected by Indian monsoon rainfall. The anti-correlation obtained over this region could thus possibly be explained by enhanced particle wet deposition and/or inhibiting effect of soil moisture on dust emissions during rainy years.

Difference of mean JJAS 850 hpa circulation and surface pressure between DUSTY (2005–2009) and NONDUSTY (2000–2004) pentads as defined in the text and calculated from (a) ERAI reanalysis, (b) “nodust” simulations, (c) “dust” standard simulations and (d) “dust_ft” simulations with forced emission trend over Arabia. As a complement to ERAI, an equivalent graph has been produced from NCEP reanalyses and displayed in Fig. S1 in the Supplement. All simulated results represent a three-ensemble-member mean.

[Figure omitted. See PDF]

Simulation of dust radiative forcings, trends and associated feedbacks

Simulation of mean JJAS climate

In this section we assess the model capacity to simulate the mean observed JJAS monsoon circulation and precipitation over the domain. Comparison of simulated JJAS 850 hpa circulation patterns show an overall consistency with ERA-Interim reanalysis in terms of pattern and intensity as illustrated in Fig. 5a and b. The main differences are a moderate underestimation of easterly circulation in the region of the Somali Jet and a tendency for the model to overestimate average wind speed over the Bengal Gulf and Indonesia. Model mean JJAS precipitations are evaluated using TRMM, PERSIANN and the high resolution APHRODITE data sets (cf. Sect. 1). The variability between observations is illustrated in Fig. 6, c, e and g. As in many modeling studies and due to the complexity of convective and dynamics processes, important precipitation overestimation biases are found in regions of low precipitation as well as over the northeastern Himalayas and over the southern Bay of Bengal (Fig. 6). Over continental India, the control simulation (nodust) tends to produce drier conditions than observed, with a relative bias increasing toward eastern and southern India (Fig. 6d, f, h). The model shows better results when compared to the high-resolution APHRODITE rain-gauge-based data set (Fig. 6g–h). A comparison of Fig. 6b and 6d, f and h shows that radiative effects of dust tend to reduce model biases over southern and northwestern regions of continental India (see also Fig. S4). Biases are, however, increased over the western Bay of Bengal. Overall the simulated mean circulation and precipitation biases obtained in these simulations are either lower or comparable with CMIP5 state-of-the-art GCMs and multi-model ensemble (Sperber et al., 2013).

Mean 850 hpa JJAS wind intensity and direction as seen in (a) the ERAI reanalysis and (b) the RegCM nodust simulation for the period 2000–2009 and over the CORDEX-India domain. All modeling results represent a three-ensemble-member mean.

[Figure omitted. See PDF]

(a) Mean JJAS 2000–2009 precipitation simulated by the model in “nodust” configurations. (b) Relative difference in precipitation between dust and nodust simulations for JJAS 2000–2009 and calculated as (dust $-$ nodust $/$ nodust) $\times$ 100. (c) JJAS 2000–2009 TRMM precipitation. (d) Relative difference (bias) between nodust and TRMM precipitations for observed precipitation level $>$ 0.2 mm day${}^{-\mathrm{1}}$. (e–f) Same than (c–d) for the PERSIANN data set. (g–h) Same than (c–d) for the APHRODITE data sets but calculated for JJAS 2000–2007 only. All modeling results represent a three-ensemble-member mean.

[Figure omitted. See PDF]

Simulation of aerosol optical depth, radiative forcings and heating rates

The climate response to aerosol via direct and semi-direct effects is strongly dependent on radiative forcing gradients as well as the vertical distribution of radiative heating due to aerosol. To evaluate model performance in this regard, the AOD simulated for both anthropogenic and natural aerosol is evaluated using MISR and SeaWIFS products described in Sect. 1 (Fig. 7). Simulated AODs in regions dominated by anthropogenic emissions (northeastern India, China, Indonesia) are reasonably captured despite local underestimations for Indian and Chinese megacities. An underestimation of simulated AODs over the Bay of Bengal is, however, noted, which can be due to uncertainties in emissions, notably for biomass burning (Streets et al., 2003), and/or an excessive deposition rate due overestimated precipitations as discussed previously. Overall, simulated JJAS 2000–2009 AODs show a very good agreement with observations both in term of magnitude and spatial gradients, providing additional regional details when compared to existing GCM simulations (e.g., Vinoj et al., 2014; Bollasina et al., 2011; Lau et al., 2006). Of particular importance, the dust-dominated regions of the Arabian Peninsula, the Arabian Sea and the Indo-Pakistani desert regions are quite accurately represented in terms of averaged JJAS AOD, although a likely small contribution of non-dust aerosol might play a part in this comparison.

JJAS 2000–2009 AODs seen from the (a) MISR sensor and (b) as simulated by RegCM “dust” simulation for the full CORDEX-India domain. JJAS composite averages are built form monthly observations and model outputs. Regions of missing observations are screened out from the model averages. (c, d) Same as (a, b) but using the SeaWIFS AOD observations. All modeling results represent a 3 member's ensemble mean.

[Figure omitted. See PDF]

Simulated monthly AODs vs AERONET measured monthly AODs for the period of 2000–2009. Blue dots represent the solar Village Station (46.40${}^{\circ }$ E, 24.90${}^{\circ }$ N), red dot represent the Karachi station (67.03${}^{\circ }$ E, 24.87${}^{\circ }$ N), green dots represent Kuwait Airport station (47.98${}^{\circ }$ E, 29.22${}^{\circ }$ N) and black dots the Meizera station (53.8${}^{\circ }$ E, 23.15${}^{\circ }$ N). The correlation coefficient between data and measurements is equal to 0.59 and the root mean square error is 0.16.

[Figure omitted. See PDF]

Additional comparisons of simulated AODs and ground-based AERONET-retrieved AOD (500 nm) are proposed in Fig. 8 for the stations of Solar Village, Meizera, Kuwait Airport and Karachi. Dust aerosol mass is known to be dominant over these stations except perhaps during winter season over Karachi. For both model and observations, monthly averages are built from daily means and screened for missing days in observations. Figure 8 shows that the model tends in general to slightly underestimate observed AODs. This underestimation is perhaps more pronounced for the Karachi station, as also shown on JJAS average AOD comparisons (Fig. 7). The simulation of AOD seasonal cycles shows an overall consistency with observations (Fig. 9a, c). However, we note that for certain years AOD spring maxima tend to be underestimated by the model over solar village, while summer peaks tends to be overestimated. This slight shift of the seasonal cycle is also discussed in Shalaby et al. (2015).

(a) Comparison between simulated and AERONET monthly AODs (see text) for Solar Village station. (b) Comparison of simulated and measured aerosol normalized volume size distribution averaged for JJAS 2009 over Solar Village. For comparison, the AERONET normalized volume distribution (green dotted line) is re-binned using a weighted average between model bins cutoff diameters (red lines). Blue lines show the corresponding simulated four-bin distribution for the same cutoff diameters. (c) Same as (a) for Karachi station. (d) Same as (b) for Karachi station.

[Figure omitted. See PDF]

In Fig. 9b and d we compare simulated aerosol size distribution to size distributions retrieved by AERONET inversions and re-binned to match model dust bins. Due a to lack of observational data and given the scope of the study, we restrict this comparison to JJAS 2009. Interannual variation of JJAS size distribution might anyway be of secondary order, especially given the possible uncertainties in AERONET inversions (Dubovik and King, 2000). For both Solar Village and Karachi, the model tends to show a consistent relative distribution between size bins compared to observations. However, we can note an overestimation of simulated fine and/or medium bins compared to underestimated coarse bins, especially in the case of Karachi (Fig. 9d). One of the possible reasons for this might lie in the emission size distribution (Kok, 2011), which tends to be more uncertain with regards to representing coarse particles, as for example discussed in Mahowald et al. (2014). Other reasons could be linked to accuracy of sources' geolocation, removal and transport processes. Bearing in mind observational uncertainties, the implication of a simulated dust size distribution shifted towards smaller particles would be to enhance shortwave scattering vs. absorption and long-wave emission with implications for radiative forcing and feedback discussed further. With possible compensating effects, note that dust refractive indices considered in this study are issued from the OPAC database (cf. Supplement), which could enhance absorption as noticed in Kaufman et al. (2001), Moulin et al. (2001) and Balkanski et al. (2007).

(a) JJAS 2000–2009 dust aerosol surface radiative forcing diagnostic. (b) JJAS 2000–2009 dust top-of-atmosphere radiative forcing diagnostic. (c and d) Corresponding surface radiative forcing efficiencies. (e) JJAS 2000–2009 2 m temperature difference between dust and nodust simulations. (f) 850 hpa radiative heating rate difference between dust and nodust simulations. All modeling results represent a three-ensemble-member mean.

[Figure omitted. See PDF]

Over dust-dominated regions, the net dust surface radiative forcing (Fig. 10a) is dominated by shortwave cooling vs. positive long-wave surface warming as reported in the Supplement (Fig. S1). This induces a surface temperature cooling illustrated in Fig. 10e which can reach $-$2 K in subregions of Arabia. Over the ocean, a surface cooling is also obtained through the slab-ocean response but tends to be less effective due to larger surface thermal inertia. SST cooling reaches up to $-$1 ${}^{\circ }$C close to Oman Gulf with a decreasing gradient towards India (Fig. 10e). As a result of both dust optical properties and surface albedo, top-of-atmosphere (TOA) radiative forcing is mostly positive over the high emission region of the Arabian Peninsula and become negative above the ocean and continental India. Note that in comparison to the Arabian Peninsula, the TOA radiative forcing efficiencies (i.e., TOA normalized by AOD reported in Fig. 10d) show less of a warming effect in the Indo-Pakistani desert regions due essentially to lower surface albedo. Over continental India the TOA radiative forcing efficiencies becomes largely negative due to relatively dark albedo and also due to the fact that long-range transported dust from Arabian and Indo-Pakistani sources are finer and more scattering. Uncertainties and regional variability in dust size distribution and optical properties might affect the magnitude and even the sign of the radiative forcing simulated here with potential consequences for regional climate feedbacks, which are discussed further.

Atmospheric radiative heating rate anomalies primarily associated with dust radiative absorption are presented in Figs. 10f and S2. Mean simulated values for JJAS range from more than 1 K day${}^{-\mathrm{1}}$ over source regions of Arabia to about 0.3 K day${}^{-\mathrm{1}}$ in the core of the Arabian dust outflow, located between 850 and 600 hpa. Over India, the JJAS dust radiative warming at 850 hpa reaches about 0.05 to 0.1 K day${}^{-\mathrm{1}}$. These values are in the range of different observational studies (Moorthy et al., 2009; Kuhlmann and Quaas, 2010; Nair et al., 2008). We note that when radiative and moist processes feedbacks are combined, the diabatic heating induced by dust is, however, significantly lower than the 2 K day${}^{-\mathrm{1}}$ warming reported in Vinoj et al. (2014), which can also explain differences further discussed in Sect. 4.3.

Mean monsoon response to dust radiative forcing

Regional climate adjustments to dust radiative forcing are first discussed by comparing “dust” and “nodust” simulations (as defined in Sect. 1) for JJAS 2000–2009. Figure 11a presents 850 hpa circulation and geopotential height (GPH) anomalies induced by dust direct and semi-direct effects over the domain. Two patterns emerge from this comparison: the first one is a low GPH anomaly centered over the southern Arabian Peninsula associated with a cyclonic circulation and the second one a positive GPH anomaly roughly centered over northeastern India associated with an anti-cyclonic anomaly. Regions of large positive or negative values in 850 hpa GPH difference patterns tend to match closely the regional TOA radiative forcing patterns (Fig. 10b). Over Arabia, dust radiative warming is maximum due to high concentrations of dust while dust surface cooling efficiency is relatively reduced due to high surface albedo. This induces a deepening of the Arabian thermal low (Fig. 11) and dry convection collocated with the maximum of dust radiative warming (Fig. S2c and d). On its southern part, the cyclonic circulation anomaly is associated with an intensification of the Somalia jet and eastward circulation between 10 and 20${}^{\circ }$ N and 50 and 75${}^{\circ }$ E. This intensification induces an enhanced convergence of moisture flux toward southern India and an increase of convective activity and precipitations over the southern Indian continent (Figs. 11 and S2d, e). From these simulations we estimate that this mechanism could enhance average precipitation by up to 10 % in southern India, thus contributing to the improvement of the model dry bias (Fig. 6a). Up to roughly ${20}^{\circ }$ N, our results show much similarity with GCM results notably reported in Vinoj et al. (2014). One noticeable difference, however, is that while Vinoj et al. (2014) obtain an increase of precipitation over northern Arabian Sea, northwestern India and Pakistan, convective precipitations tend to be inhibited for these regions in our case. This regional stabilization is induced by a relatively large surface radiative dimming which decreases continental and sea surface temperatures (Fig. 10e) and predominate over dust diabatic warming effects. This is consistent with a negative simulated TOA radiative forcing (Fig. 10b). Such mechanisms have been analyzed in great detail by Miller et al. (2014). On average, in our simulations the combined contribution of Arabian and Indo-Pakistani dust sources appears to have a dual signature resulting in a strengthening of the Somali Jet, moisture convergence and precipitation over southern India while inhibiting convective precipitation and decreasing monsoon intensity north of about 20${}^{\circ }$ N (Fig. 11).

Dust impact on the mean monsoon dynamic and precipitations over the period JJAS 2000–2009. (a) 850 hpa geopotential heights (GPH) and monsoon circulation dust-induced anomalies calculated as the GPH difference between dust and nodust simulations. (b) Dust-induced precipitation anomaly. The dotted region defines statistically significant results at the 95 % confidence level. All modeling results represent a three-ensemble-member mean.

[Figure omitted. See PDF]

Impact of the Indo-Pakistani dust source compared to the dust simulation calculated as dust_noIP $-$ dust over the period JJAS 2000–2009. (a) 850 hpa geopotential heights (GPH) and circulation change. (b) Precipitation changes. The dotted region defines statistically significant results at the 95 % confidence level. All modeling results represent a three-ensemble-member mean.

[Figure omitted. See PDF]

In order to further illustrate this point, we perform an additional experiment where the Indo-Pakistani dust sources are removed (dust_noIP). By analyzing the difference between dust_noIP and dust we see that taking into account the Indo-Pakistani sources results in an inhibition of convergence and precipitation over India (Fig. 12). Due to its geographic position and regional surface characteristics, the Indo-Pakistani dust source contributes relatively more than Arabia to the negative TOA radiative forcing and the dimming signal obtained over India. In this regard the Indo-Pakistani source-related effects tends to “compete” with the positive feedback associated with large radiative warming efficiencies over the Arabian Peninsula.

That said, it must be noted that radiative forcings and impacts might strongly depend on dust chemical composition and absorption/scattering properties (Miller et al., 2014; Perlwitz et al., 2001; Solmon et al., 2008), which exhibit a large regional variability (Deepshikha et al., 2005) but are unfortunately poorly constrained by observations. In the present simulations we do not account for regional variation of dust refractive indices as proposed in recent studies (Scanza et al., 2015). This point might be especially important over the Indo-Pakistani region where simulated single-scattering albedo might be close to its critical value in relation to surface albedo: a slight change in optical properties and/or a misrepresentation of size distribution could result in a change in the sign of radiative forcing which can potentially result in an opposite dynamical feedback (in this case an enhancement of elevated heat pump effect over Pakistan and northern India). Some simple tests modifying dust single-scattering albedo values in RegCM4 and performed over the same domain tend to show that the more absorbing the dust, the more intense the positive feedback on convergence and precipitation over India is (S. Das, personal communication, 2015). Finally, note that we do not account for possible indirect dust effects on warm and ice cloud microphysics. There is still a considerable debate in this matter, and impacts are difficult to assess within the scope of the present study.

Coupling of Arabian dust increasing activity and precipitation variability over the 2000–2009 decade

Our working hypothesis is that, if the above mechanisms are valid, the observed increasing dust AOD trend over Arabia over the decade 2000–2010 might have been associated with, and perhaps contributing to, a positive impact on circulation and precipitation over southern India. Focusing on model results we see that, although the standard dust simulation is able to capture a slightly positive AOD trend over part of the Arabian Peninsula, this trend is nevertheless largely underestimated when compared to observations (Fig. 3a and b). Consistent with the arguments developed before, a likely reason for this underestimation is related to the fact that the cyclonic pattern found in reanalysis pentad differences is also not properly captured by the model as shown in Fig. 4b and c, meaning that the model does not properly reproduce increasing occurrences or/and intensification of Shamal conditions during the decade. These deficiencies are likely to be due to uncertainties in coupled convective and dynamical processes over the northern Arabian Sea, Pakistan and Bengal Gulf, which are extremely challenging to capture properly in climate models (Turner and Annamalai, 2012). In terms of dust AOD, the uncertainties in dust emissions parameterizations could further worsen errors in adequately simulating regional climatic trends (Evan et al., 2014).

However, since dust triggers a potentially important climatic feedback over the region, it is possible that failure to capture the increasing Arabian dust trend also contributes to failure to capture a proper trend in regional climate. To explore this issue, we perform an additional experiment in which dust emissions are forced in order to reproduce more realistically the observed JJAS AOD increasing trend (see Sect. 2.2 and Figs. 1a, 3b and c). This constraint is applied only over the Arabian Peninsula and eventual trends visible over other regions are primarily a result of Arabian dust transport or simulated spontaneously in response to simulated climate. In the JJAS AOD time series (Fig. 1a) we can note that the adjusted model shows enhanced AOD for DUSTY pentad relative to NONDUSTY pentad in a relatively similar way to observations. In terms of climatic impact, simulated circulation and surface pressure changes between NONDUSTY and DUSTY pentads show a rather different behavior depending on whether nodust, dust only or adjusted dust_ft simulations are considered (cf. Sect. 2), especially over the Arabian Sea and southern India (Fig. 4). With no dust, or when increasing dust emission tendency is not forced, the model tends to reproduce an anti-cyclonic pattern over the Arabian Sea (Fig. 4b and c) and no enhanced westward circulation toward the Indian coast, unlike what is observed in reanalyses (Fig. 4a). When dust tendency is forced, however, a westward convergence is obtained between 5 and 20${}^{\circ }$ N, and surface pressure pentad differences over the Arabian Sea switch from positive to slightly negative (Fig. 8d). The cyclonic pattern and southward flow clearly seen in reanalyses is, however, not well reproduced by the simulation; it instead tends to generate a cyclonic pattern shifted to eastern India and Bengal Gulf. This indicates that dust radiative trends alone shall not be considered as the main driver for explaining regional circulation changes and also points out model limitations. With this in mind, the simulations still tend to show some relatively improved circulation and surface pressure changes when dust is present and especially when the increasing dust trend is more realistically forced. From these results we suggest that while the cyclonic changes observed between pentad in reanalyses might be primarily a feature of climate variability, the likely associated increase in JJAS west-Asian dust emissions and Arabian Sea AODs could, however, determine a possibly important positive feedback contributing to the intensification of easterly circulation and humidity flux convergence towards the southwestern Indian coast. The simulated impact of this feedback on summer precipitation trends over southern India is depicted in Fig. 1b: simulated JJAS precipitations show an increasing linear trend in dust_ft deseasonalized JJAS simulations of about 0.11 mm day${}^{-\mathrm{1}}$ year${}^{-\mathrm{1}}$ and close to the value of the JJAS trend calculated from observations (0.13 mm day${}^{-\mathrm{1}}$ year${}^{-\mathrm{1}}$), when no statistically significant trends are detected in nodust and dust simulations.

Conclusion

Overall our results emphasize the possible two-way interaction between dust emissions variability and the summer regional climate variability in the Indian monsoon domain for interannual to decadal timescales. Using observations and a regional climate model, we suggest that an increasing Arabian dust emission trends could have impacted the Indian monsoon circulation and contributed to the observed increasing 2000–2009 summer precipitation over southern India. There are potentially many global and regional players contributing to monsoon precipitation interannual and decadal variability (e.g., Indian Ocean Dipole, ENSO; Patra et al., 2005) and dust radiative forcing should not be considered as the main driver of the observed precipitation interannual and decadal variability. Dust radiative forcing might, however, determine a positive dynamical feedback favoring the establishment of lower-pressure conditions over the Arabian Sea likely associated with both enhanced Arabian dust emissions and precipitation over southern India. Please note, however, that the entire feedback loop has not been fully demonstrated here since we used forced emission trends.

This study does not consider any trend in anthropogenic aerosol emissions during the decade. Increasing AOD trends attributed to anthropogenic pollution have been measured over continental India, though they are mostly significant during the winter season (Babu et al., 2013). Nevertheless, it is likely there has been an impact of the anthropogenic aerosol trend on Monsoon rainfall during the studied decade, as for example discussed in Bollasina et al. (2011) (who conclude a general drying effect of anthropogenic aerosol in continental India). Note that in magnitude, the measured dust decadal AOD trends over Arabia and the Arabian Sea are equally if not more important than AOD trends attributed to pollution increase over India (Babu et al., 2013).

In view of these results, capturing the positive feedback between dynamics and dust emission trends in climate models could lead to a more realistic representation of decadal precipitation variability over India. This is even more relevant when considering the emergence and potential importance of “anthropogenic dust sources” as discussed in Ginoux et al. (2012). However, the present study, as well as Evan et al. (2014), shows that current dust parameterizations and implementations in climate and Earth system models have difficulties reproducing observed regional AOD interannual and decadal variability. Improvement of models – whether they deal with dust emissions processes, regional land use change or surface wind speed downscaling – is still of primary importance.

The Supplement related to this article is available online at doi:10.5194/acp-15-8051-2015-supplement.

Acknowledgements

The authors would like to thank two anonymous reviewers for their very useful comments, Jost von Hardenberg for providing aerosol large-scale fields for boundary conditions, R. Farneti and F. Kucharski for advices on slab-ocean implementation and scientific discussion as well as G. Giuliani and the RegCM developing team for maintaining and managing the code. The authors would also like to thank all the research teams involved in the creation and maintenance of the aerosol and precipitation observational products used in this study. Edited by: Y. Balkanski