contribución de radiación solar a variabilidad de temperaturas decadal sobre tierra
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EARTH,
ATMOSPHERIC,
www.pnas.org/cgi/doi/10.1073/pnas.1311433110 PNAS Early Edition | 1 of 6
Contribution of solar radiation to decadal temperature
variability over landKaicun Wanga,1 and Robert E. Dickinsonb
aState Key Laboratory of Earth Surface Processes and Resource Ecology, College of Global Change and Earth System Science, Beijing Normal University, Beijing100875, China; and bDepartment of Geological Sciences, Jackson School of Geosciences, The University of Texas at Austin, Austin, TX 78712
Edited by Mark H. Thiemens, University of California, San Diego, La Jolla, CA, and approved August 2, 2013 (received for review June 18, 2013)
Global air temperature has become the primary metric for judging
global climate change. The variability of global temperature on a
decadal timescale is still poorly understood. This paper examines
further one suggested hypothesis, that variations in solar radia-tion
reaching the surface (Rs) have caused much of the observed
decadal temperature variability. Because Rs only heats air during
the day, its variability is plausibly related to the variability of di-
urnal temperature range (daily maximum temperature minus its
minimum). We show that the variability of diurnal temperature
range is consistent with the variability of Rs at timescales from
monthly to decadal. This paper uses long comprehensive datasets
for diurnal temperature range to establish what has been the
contribution ofRs to decadal temperature variability. It shows that
Rs over land globally peaked in the 1930s, substantially decreased
from the 1940s to the 1970s, and changed little after that. Reduc-
tion ofRs caused a reduction of more than 0.2 C in mean temper-
ature during May to October from the 1940s through the 1970s,
and a reduction of nearly 0.2 C in mean air temperature during
November to April from the 1960s through the 1970s. This cooling
accounts in part for the near-constant temperature from the 1930s
into the 1970s. Since then, neither the rapid increase in tempera-
ture from the 1970s through the 1990s nor the slowdown of
warming in the early twenty-first century appear to be signifi-cantly
related to changes ofRs.
global dimming | global brightening | global warming |surface incident solar radiation | decadal variability
lobal temperature has become the primary metric forjudging global climate change, although many other factors
are recognized to be of comparable importance. The overallincrease of global temperature over the last century has beenlargely attributed to the increase of greenhouse gases (1). Lesswell understood are the reasons for the variability of this increaseon a decadal timescale. In particular, warming from 1900 to 1940was followed by three decades of flat or slightly decreasingtemperature, then three decades of very rapid temperature in-crease, then so far in this century, very little additional increase.The two most plausible explanations for the decadal variabilityare natural climate variability and variable degrees of coolingfrom anthropogenic releases of sulfur gas producing sulfateaerosols (2). This effect has long been proposed as a mechanism
to counter greenhouse warming (3), has become the basis formany geoengineering proposals (4), and has been used to attri-bute the lack of warming so far this century to the rapid growthof aerosols in Asia (5).
Besides the difference in sign of their temperature effects,sulfate aerosols are distinguished from greenhouse gases in thatthey only affect daytime radiation, i.e., surface incident solarradiation (Rs). Some kinds of natural variability can also actthrough affecting Rs, i.e., those involving cloud properties.
Changes of aerosol loading and cloud properties likely causedthe rapid decrease ofRs, measured at the surface from the 1950sto the 1980s, referred to as global dimming, and its partialrecovery after that (6). The plausible suggestion was made byWild et al. (7) that the rapid warming in the late twentieth
century was a consequence of the cessation of global dimming,possibly in part from the imposition of controls on sulfur emis-sion in the industrialized nations (8, 9).
This paper examines further the hypothesis that variations in Rshave caused much of the observed decadal variability in the rateof warming. Direct measurements ofRs cannot be quanti-tativelyrelated to such variability because they have been limited in theirgeographical coverage. The approach used here is to examine aglobal land dataset of diurnal temperature range (DTR). Thisconcept is not new, indeed, Wild et al. (7) noted (compare withtheirfigure 2) that the global pattern ofDTRwas similar to that oftheir global dimming and brightening. The present paper develops
the longest and most comprehensive dataset for DTRpossible,and, with some plausible assumptions, establishes what thecontribution ofRs has been to decadal temperature variability. Itindicates that a decrease ofRs from the 1940s through the 1970sreduced the global temperature trend over that period. However,global temperature does not appear to have been significantlyaffected by changing Rsafter that. The method is limited in that itis only applicable over land. As the effects of aerosols are likelyto be less over ocean, es-pecially in the Southern Hemisphere, thisapproach may exag-gerate the actual effect of aerosols on globaltemperature trends.
Results
Relationship Between Rs and DTR. This section establishes that lo-cally DTRis highly correlated with Rs,but that spatial and sea-
sonal variability precludes direct use of this correlation to infer Rswhere it is not already measured. In the absence of weathervariability, near-surface air temperature Ta over land decreaseswith time at night from longwave radiative cooling and reachesTminbefore sunrise. After sunrise, the surface is heated byRsand
Significance
Global air temperature has become the primary metric for
judging global climate change. The variability of global tem-
perature on a decadal timescale is still poorly understood. This
paper shows that surface incident solar radiation (Rs) over
land globally peaked in the 1930s, substantially decreased
from the 1940s to the 1970s, and changed little after that. The
cooling effect of this reduction of Rs accounts in part for thenear-constant temperature from the 1930s into the 1970s.
Since then, neither the rapid increase in temperature from the
1970s through the 1990s nor the slowdown of warming in the
early twenty-first century appear to be significantly related to
changes ofRs.
Authorcontributions:K.W. designed research; K.W. performed research; K.W. and R.E.D.
analyzed data; and K.W. and R.E.D. wrote the paper.
The authors declare no conflict of interest.
This article is a PNAS Direct Submission.
Freely available online through the PNAS open access option.
1To whom correspondence should be addressed.E-mail: [email protected].
This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.
1073/pnas.1311433110/-/DCSupplemental.
G
http://www.pnas.org/cgi/doi/10.1073/pnas.1311433110http://www.pnas.org/cgi/doi/10.1073/pnas.1311433110mailto:[email protected]:[email protected]:[email protected]://www.pnas.org/lookup/suppl/doi:10http://www.pnas.org/lookup/suppl/doi:10mailto:[email protected]://www.pnas.org/cgi/doi/10.1073/pnas.1311433110 -
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1.5
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Fig. 1. Correlation coefficients between monthly anomalies ofDTRand Rs. The
Rs observations are from the GEBA, and the homogenized maximum and
minimum air temperature at 2 m are from the Global Historical Clima-tology
Network (GHCN). Both datasets cover the period from 1950 to 2005. Each
point in the figure represents a weather station where both Rs and DTR areavailable for more than 120 mo. There are 524 stations in total.
. . . . . . . . . .
this heat is transferred as sensible heat H to the overlying air, raising
Tato Tmax in early afternoon. Therefore, changes ofDTR= Tmax Tmin, have been interpreted as directly related to changes ofRs (6, 7,1013). Here we explain how Rs and DTRconnect physically andhow their relationship varies with environment.
Fig. 1 shows the correlation of monthly anomalies of Rs col-lected by the Global Energy Balance Archive (GEBA) (14) withDTRfrom 1950 to 2005 at 524 globally distributed stations (see SIText and Fig. S1 forDTRdata sources and their quality control).The correlation coefficients between Rs and DTRare the highest inhumid areas and lower in arid or semiarid areas because thefraction of absorbed Rs generating H also depends on variable soilmoisture resulting from the frequency and in-tensity oprecipitation (15, 16). Besides its dependence on sur-face wetness(17), the partitioning of surface-absorbed Rsbetween H and latent
heat flux (1E) depends on land-cover conditions (18, 19) andatmospheric evaporative demand (20). In humid areas, both H and1E generally increase with Rs (21, 22), but under warm conditionsthe latter increases more (23). In arid or semiarid regions, 1E islimited by soil water supply and H can account for a higher portionof surface absorbed Rs. Fig. 2 shows, as expected from the abovediscussion, that the sensitivity of DTRto Rs is higher in arid orsemiarid areas than in humid areas.
Surface aridity changes seasonally for most monsoon areas,i.e., where it is wet only in a rainy season, but its interannual
Annual Rs Anomaly (Wm2
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Annual Rs Anomaly (Wm2
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China, Cold Seasons
Annual Rs Anomaly (Wm2
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Europe, Cold Seasons
Annual Rs Anomaly (Wm2
)
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AnnualDTRAnomaly(C)
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AnnualDTRAnomaly(C)
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Fig. 2. The sensitivity ofDTRto Rs(in C per Wm2) calculated from the monthly
anomalies ofRsand DTR. The data used here are the same as in Fig. 1.
Fig. 3. Scatterplots of annual anomalies of regional DTR as a function ofannual anomaly of Rs during warm seasons (May to October) and cold sea-sons (November to April) from 1950 to 2005. The correlation coefficients are0.61 and 0.83 over China and 0.86 and 0.73 over Europe during the warm andcold seasons, respectively.
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variability is expected to be much less than such seasonalchanges. To reduce the impact of seasonality, we used monthlyand annual anomalies rather than absolute values of DTRandRs. In the following discussion, we also divide a year into borealwarm seasons (May to October) and boreal cold seasons(November to April).
The correlations and sensitivity shown in Figs. 1 and 2 are thelowest in coastal areas. Evidently the impact of Rs on DTR inthese areas is masked by the impact of energy advection with
regular alteration between land breezes and ocean breezes. Thismasking can be substantially reduced by regional averaging ofDTRand Rs (6, 24).
Figs. 3 and 4 compare Europes and Chinas regional averageannual anomalies of DTR with those of Rs. These quantitiesagree quite well, partly because of their better data density anddata continuity (Fig. S3). The agreement between regional DTRand Rs over Europe has also been confirmed by both dataanalysis (10) and model simulation (24). In China, the decreaseof Rs is in good agreement with the reduction of DTRbefore1990 (11). However, Rs in China increased suddenly during theearly 1990s but not DTR and sunshine duration (25). The in-troduction of new pyranometers from 1990 to 1993 introducedthis inhomogeneity into the Rs observations (25, 26).
Fig. 4 also shows that DTRhas had a larger temporal vari-ability than Rs, a consequence of the annual variability of pre-cipitation leading to variations in the partitioning of surfaceabsorbed Rs between 1E and H. The Intergovernmental Panel onClimate Change (IPCC) Fourth Assessment Report (AR4) con-cluded that precipitation has had large annual variability duringthe last century, but that its long-term trend and thus its impact onthe long-term trend ofDTRhas been negligible (1), as con-firmedby Figs. 3 and 4 and the following sections. The impact of annualvariability of precipitation is largely removed by using 5-ysmoothing of the anomalies ofDTRas in the following.
Variability ofDTR, a Proxy of Rs, from 1900 to 2010. This sectionestablishes what is available as a global record for DTR vari-ability. For estimation ofDTRover land with optimum spatial andtemporal coverage and the highest quality, we combined three datasources (2729) (see SI Text fordetailed information)
China, Warm Seasons Europe, Warm Seasons
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China, Cold Seasons
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urope, o easons
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AnnualDTRAnomaly(C)
AnnualDTRAnomaly(C)
AnnualRsAnomaly(Wm2)
AnnualRsAnomaly(Wm2)
China, Warm Seasons. .
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Europe, Warm Seasons
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Wang and Dickinson PNAS Early Edition | 3 of 6
EARTH,ATMOSPHERIC,
A s i a
1900 1950 2000
0 .5
0 . 5
0
Au st ra li a
1900 1950 2000
0.5
0
0.5
FiveyearAverageAnomalyofDiuranlTemperatureRange(DTR,
C)
South America
North America
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1900 1950 2000 1900 1950 2000
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1900 1950 2000 1900 1950 2000
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Fig. 4. Regionally averaged annual anomalies of RS (in blue) and DTR (in
green) during boreal warm seasons (May to October) and boreal cold sea-sons
(November to April) from 1950 to 2005. Data used here are the same as in Fig.
3. Equivalent plots for the United States are given in Fig. S2.
for the past 110 y. Monthly anomalies ofDTRwere derived byremoving its seasonal cycle. Observations of DTR had thehighest density in North America. To mitigate the impact of thedifferent data densities, monthly anomalies ofDTRwere binnedinto 5 5 grids. Given the low correlation between DTRandRs in coastal areas, we only selected the grids with more than50% of their area over land, as shown in Fig. S4. The monthlyanomalies at each grid were averaged into regional monthlyanomalies, and then into annual values and 5-y average annualanomalies at each region, as plotted in Fig. 5.
Europe is the only region where measurements of both DTRand Rs extend back to the 1920s (6). DTRgenerally increased inEurope from the 1920s to the 1950s. After the late 1950s, itbegan to decrease until the 1980s, and since the 1990s increased.
These variations ofDTRare consistent with those of observed Rs(6, 24, 30). The better agreement of warm-season variability ofDTRwith that ofRs is consistent with the largerRs during warmseasons.
Attempts have been made to correlate annual Rs and DTRbothat regional and global scales (6, 7). However, existing studieshave not recognized that DTR and Rs have different seasonalcycles; Rs is largest in summertime as a result of higher solarelevation. However, DTR is relatively low in moist summersbecause of the small fraction of Rs that is partitioned into H.Therefore, annual variability ofDTRis primarily determined byits variability during seasons other than summer. DTR and Rsagree well both for warm and cold seasons, and variability of Rsover warm seasons is more representative of its annual vari-ability. The reported annual variability of Rs, therefore, agrees
better with DTR over warm seasons over Europe (and otherregions) than that over an entire year or cold seasons. VariabilityofDTRover warm and cold seasons is substantially different atboth the regional scale (Fig. 5) and the global scale (Fig. 6). Forthis reason, it is essential to consider these differences in recon-structing variability ofRs from DTR.
In Asia, DTR substantially decreased from the 1950s to the1980s, was stable until 2000, and then decreased again, consistentwith Rs derived from sunshine duration (25) and the dimming ofdirectly measured Rs between 1960 and 1990 in China (11, 31). Asalready mentioned, after the 1990s, direct observations of Rsbecame inconsistent with those of DTRand sunshine (31), a re-sult of the urban bias ofRs observations. When averaged over allstations (400 stations) rather than over the 50 urban stations inChina with direct observations ofRs, Rs derived from
sunshine duration was stable during the 1990s and decreasedafter 2000 (25).
DTR substantially decreased in North America from 1900 to2010, consistent with the increase of cloudiness, in particular, oflow clouds (32), and decrease of sunshine duration (33). Cloudcover alone accounted for up to 63% of the regional annual DTRvariability in the United States from 1902 to 2002, with cloud-cover trends especially driving DTR in northern United States(34). Aerosol loading over North America was relatively light
(35) and rather stable during the past few decades (8). Obser-vations at six stations in the United States showed that Rs sig-nificantly increased from 1995 to 2007 (36, 37), primarily in the1990s (38).
As there is a good agreement between Rs and DTR, changes ofRs are expected to be similar to those of DTR, especially duringthe warm seasons. Fig. 5 shows the variability of DTRover landduring the past century, and hence provides qualitative estimatesof Rs variability over this period. However, it is difficult to re-construct Rs quantitatively using the variability of DTRbecauseof the changes of their relationship with time (e.g., from wet todry seasons; Fig. 3) and region (e.g., from humid to arid regions)(Figs. 1 and 2). Below, we describe another approach for usingDTRto estimate the impact ofRs on Ta.
Estimation of the Impact of Rs on Ta from 1900 to 2010. Elevatedgreenhouse gases (GHG) have increased atmospheric downwardlongwave radiation (Ld) (39, 40) and Ta (41) during the twentiethcentury. However, variability in radiative forcing from aerosolsand clouds complicates the attribution of the observed climatechange to the elevated GHG. The previous sections haveestablished a more comprehensive climatology forDTRthan thatavailable previously and its long-term variability is highly con-sistent with that ofRs. This climatology allows us to address thequestion of how much of the observed temperature change hasbeen a result of changes of Rs. For the following analysis, weassume: (i) Tmin is not changed by Rs; and (ii) DTR is onlychanged by changes of Rs (elaborated on in Discussion andConclusions).
The globally averaged anomaly of DTR is calculated directlyfrom its grid values. Daily mean air temperature Ta is commonlyestimated by Ta = 0.5 (Tmax + Tmin). As DTR= Tmax Tmin, we
Fig. 5. Five-year average of annual anomaly (black) of regional DTRfrom 1900
to 2010 averaged from the monthly anomalies at 5 5 grids (Fig. S4), whichis calculated from weather stations. For comparison, anomalies during boreal
warm seasons (May to October, red) and boreal cold seasons (No-vember to
April) are shown.
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ImpactofRsonTa(C)
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1900 1920 1940 1960 1980 2000
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MayOctoberNovemberAprilEntire Year
Y e a r MeanAirTemperature(Ta)(C)
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B
Fig. 6. (A) The 5-y smoothed impact of Rs on mean air temperature (Ta) over
global land during boreal warm seasons (May to October, red), boreal cold
seasons (November to April, blue), and an entire year (black). The mean air
temperatures over global land are also shown in B.
obtain Ta = Tmin+ 0.5 DTR. For the given assumptions, theimpact ofRs on daily mean Ta is 0.5 DTR (Fig. 6). Theseassumptions can be inaccurate for various reasons, e.g., changesof daytime radiation can be stored and released to changenighttime temperature. Observations from global flux networksshow that storage fraction is less than 10% of Rs at most
surfaces (42, 43). Allowing for this effect would likely amplifyour esti-mate of the impact ofRs on Ta over global land by afactor of-1.1.
We calculate the impact of Rs on mean Ta during the threetime periods: (i) 19002010 (the whole time period when dataare available); (ii) 19401984 (the global dimming period) and(iii) 19852010 (the global brightening period). The results aresummarized in Table 1.
Table 1 and Fig. 6 indicate that a reduction in Rshas reduced Taand that it decreased most rapidly during the dimming period of19401984. The rate of temperature increase during the cold
seasons has been reported to be much higher than that duringthe boreal warm seasons (May to October) (44). Fig. 6 showsthat warm-season Rs substantially decreased from the 1940s toearly 1950s and during the 1970s, resulting in a reduction ofmore than 0.2 C in Ta. Similarly, cold-season Rs substantiallydecreased from the 1960s through the 1970s, resulting in a de-crease of nearly 0.2 C in Ta. A subsequent increase ofRs wasonly significant over Europe. In conclusion, the variations ofRspartly accounted for the near absence of warming from
midcentury through the 1970s. The maximum cooling seen inthe early 1980s and early 1990s were consistent with the effectsexpected from the El Chichn and Pinatubo volcanoes,respectively. Fig. 6 also shows that the results are substantial-lydifferent for warm seasons, cold seasons, and the entire yearwhen using DTR to quantify the impact of Rs on air tem-perature (7).
Discussion and Conclusions
This paper shows, using direct Rs observations (6, 45) and sun-shine duration observations (25), that the interannual variabilityofDTRcan be used as a proxy for the long-term variability ofRs. In principle, this relationship should also be applicable tomodel simulations. AR4 climate models (46) show a weakmonotonic increase ofDTRfrom 1950 (44), compare with their
figure 5, suggesting that many of the models examined applied aslow constant ramp-up of aerosol forcing rather thanconcentrated increases before 1980 as indicated here. Changes ofDTR are expected to be directly related to H from surface tooverlying air but the magnitudes of these turbulent fluxes are notreadily estimated (22). Many parameters affect the relationshipbe-tween Rs and H, and consequently, the relationship betweenRsandDTR.
Impacts of land-cover and land-use change (i.e., urbanizationand irrigation) have been ignored here. In developing countries,such as China and India (47), there has been substantial ur-banization and increased irrigation activity (48) since 1900 withopposing and possibly largely cancelling effects on DTR(16, 49,50), so with impacts likely to be important locally, but likely to
be small at a regional scale (1). Precipitation had a large annualvariability but its long-term trend was negligible during the lastcentury (1), and so likely also its impact on the long-term trend ofDTR. At annual timescale or station-scale changes of pre-cipitation and land-cover/land introduce substantial uncertain-ties. Therefore, use ofDTRfor estimates of variability ofRsand
Table 1. The impact of Rs on daily mean air temperature (Ta) during three periods, 19002010,
19852010, and 19401984 (in C per 100 y)
Time periods Global land North America South America Europe Africa Asia Australia
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Yearly
19002010a 0.11* 0.11* 0.68* 0.01 0.04 0.50* 0.084
19852010b 0.07 0.21 0.23 0.46* 0.34 0.57* 0.80
19401984 0.36* -0.46* 1.04* 0.24* 0.29* 0.53* 0.08
Warm seasons
19002010a 0.11* 0.15* 0.47 0.01 0.03 0.43* 0.06
19852010b 0.19 0.31 0.03 0.75* 1.10* 0.22 1.96*
19401984 -0.45* 0.62* 0.82 0.29* 0.43* 0.54* 0.08
Cold seasons
19002010a 0.12* 0.07 0.82* 0.03 0.14 0.52* 0.0919852010b 0.09 0.02 0.28 0.27 0.49 0.50 0.41
19401984 0.29* 0.22 1.58* 0.20* 0.28 0.55* 0.03
Negative values indicate that Rs reduced the rate of warming caused by the elevated GHG, and positive values
mean that Rs amplified the warming rate by GHG. We also divide the data into boreal warm seasons (May to
October) and cold seasons (November to April). The asterisk represents impact of Rs is statistically significant (i.e.,
pass the Students t confidence test at = 0.05).aTime periods for different regions are different and may cover only a fraction of 1900 2010 (Fig. 5).
bTime periods for different regions are different and may cover only a fraction of 1985 2010 (Fig. 5).
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EARTH,ATMOSPHERIC,
its impact on Ta should be confined to decadal timescale andregional space scale.Because of the sparse distribution of measurement stations (1)
and changes in measurement methods (38) and instruments (25,51), direct observations cannot provide a reliable estimate ofRsover land during the past century, nor do current climate modelsgenerate long-term variability of Rs (52). This studyqualitatively reconstructs Rsover land from 1990 to 2010 usingthe latest homogenized DTRobservations at globally distributed
weather stations. It infers that Rs over land globally peaked inthe late 1930s, substantially decreased from the 1940s to the1970s, and changed little after that. These estimates areconsistent with observations ofRs and sunshine duration wherethese observa-tions are available.
More importantly, the DTRobservations allow us to estimatethe impact ofRs on the observed changes ofTa. Only changesbefore 1984 appear related to the observed temperature trendsand DTRvariability after 1995 indicates a negligible global im-pact of Rs variability. The small impact of Rs on Ta may bepartly a result of the low sensitivity of Ta to Rs, much lowerthan the sensitivity of Ta to longwave radiation caused bygreenhouse gases (53).The surface energy budget directly determines the Earths surface
climate and its changes, but on more local scales strongly interactswith transport processes. In consequence, most existing studieshave focused on the energy balance at the top of the atmosphere(5), which is indirectly related to surface Ta, depending on howclouds (54, 55), aerosols, and other feedbacks work. This paperprovides a direct and simple method to estimate the variability ofRsover land, which is applied from 1900 to
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2010 and estimates the impact of this variability on surfacetemperature change.
Changes ofRs are primarily determined by changes of cloudsand aerosols. Aerosols are known to have accounted for vari-ability ofRs in Europe and China (25, 56), while clouds havebeen used to explain changes ofRs in the United States (36, 37)during the last two decades. Natural variability from clouds isexpected to be more regional and of shorter timescale than the
trends from aerosols, but otherwise we are not able to separatetheir effects. This paper also does not address the mechanismsthrough which clouds and aerosols respond to climate change(57), i.e., through changes of cloud-cover fraction or cloudheight (58).
Our analysis of impact ofRson Tadoes not account for warmingeffect of solar radiation absorbed by aerosols, i.e., from blackcarbon (5961). To zeroth order, aerosol absorption within thedaytime boundary layer will return the solar energy removed fromthe surface, so will not change DTRbut will contribute to warmingTa. Our analysis, in principle, cannot include the warming ofabsorbing aerosols in the aerosol layer although their scatteringand absorption effects on surface Rsare included.
AC KN OW LE DG ME NT S. Chinese homogenized dai ly maximum and
minimum temperature at 549 stations were provided by Prof. Zhongwei
Ya n. GE BA su rf ac e in ci de nt so la r ra di at io n da ta we re ki nd ly pr ov id ed by
Prof. Martin Wild. We thank Dr. Qian Ma for processing some data for this
study. This study was supported by the National Basic Research Program of
China (2012CB955302), the National Natural Science Foundation of China
(41175126), and the US Department of Energy (BER) Grant DE-FG02-
09ER64746.
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