>. Mode), defined as the first EOF of 20th- a_ Sotar Forcing of Regional century SLP (16). This pattern contains the North Atlantic Oscillation (NAO), which t_ Climate Change During the may be considered a different view of the same phenomenon (17). We define the mod- Maunder Minimum el's AO pattern as EOF i, and the AO index as the opposite of the area-weighted change in SLP northward of 60°. Projection of the Drew T. ShindeU, 1Gavin A. Schmidt, 1Michael E. Mann, 2 1780-to-1680 SLP difference (Fig. 2) onto ',O David Rind, 1Anne Waple 3 the first five control EOFs shows that they account for 37.3, 0.0, 3.4, 1.5, and 0.0% of We examine the dimate response to solar irradiance changes between the late the variance, respectively. Thus, the regional t_ a_ 17th century Maunder Minimum and the late 18th century. Global average climate variations primarily result from a d temperature changes aresmall (about 0.3 to 0.4°C) inboth aclimate model and lower index state of the AO during the Maun- z empirical reconstructions. However, regional temperature changes are quite der Minimum relative to that of a century large. Inthe model, these occur primarily through aforced shift toward the low later (by -!.1 mbar; similarly, the SLP con- index state of the Arctic Oscillation/North Atlantic Oscillation. This leads to trast between Iceland and the Azores decreas- co|der temperatures over the Northern Hemisphere continents, especially in es by 1.9 mbar). This reduces onshore advec- winter (1 to 2*(:), in agreement with historical records and proxy data for tion of warm oceanic air, yielding a 1°to 2°C surface temperatures. cooling over large areas of North America and Eurasia (Fig. i). A minimum in solar irradiance, the Maunder creases with solar output. Thus, the reduced Historical data associate the European .. Minimum, is thought to have occurred from Maunder Minimum irradiance leads to in- Maunder Minimum winter cooling with en- ,< the mid-16OOs to the early 1700s (1-3). Con- creased upper stratospheric ozone, which in hanced northeasterly advection of continental currently, surface temperatures appear to turn causes lower stratospheric ozone to de- air, consistent with an anomalous negative have been at or near their lowest values of the crease. Both cause negative radiative forcing NAO (18). Reconstructions of large-scale oo OtM past millenium in the Northern Hemisphere (14). Inclusion of ozone photochemistry surface temperature patterns in past centuries (NH) (4-7), and European winter tempera- therefore enhances radiative forcing from (19, 20) from networks of diverse proxy in- toO- tures were reduced by 1to 1.5°C (8). preindustriai solar variations. formation (tree rings, ice cores, corals, and r- We used a version of the Goddard Insti- Equilibrium simulations were performed historical records) are particularly useful r- tute for Space Studies (GISS) general circu- for spectrally discriminated irradiances in benchmarks for comparison. Correlations be- ro- lation model (GCM), which includes a de- 1680 and 1780 (1). An alternative reconstruc- tween these reconstructions and solar irradi- tailed representation of the stratosphere, to tion has a 40% larger long-term solar varia- ance reconstructions (1) during the preanthro- ll t/1 simulate the difference between that period tion, which would give a larger climate re- pogenic interval from 1650 to 1850 provide Ill and a century later, when solar output re- sponse (15). Initial conditions were taken an empirical estimate of the large-scale cli- _O mained relatively high over several decades. from 1680 and 1780 in atransient simulation. mate response to solar forcing (21). The in- The model contains a mixed-layer ocean, al- A spin-up time of about 25 years was never- stantaneous (zero-lag) frequency-indepen- "D lowing sea surface temperatures (SSTs) to theless required for equilibration with the dent regression pattern, primarily indicative i- t'- respond to radiative forcing, and has been increased preindustrial ozone. Results are of decadal solar-climate relationships, shows O O shown to capture observed wintertime solar therefore based on the past 30 years of 60- little evidence of an AO/NAO signal (Fig. 3, O cycle-induced variations reasonably well (9). year simulations. top). This is consistent with the extremely I]0 The GCM includes parameterizations of Modeled global annual average surface weak modeled AO/NAO response to the 1I- L. the response of ozone to solar irradiance, temperatures were 0.34°C cooler in 1680 year solar cycle using fixed SSTs, equivalent 9 temperature, and circulation changes (al- than in 1780. This is similar to the annual to an instantaneous response (22). However, though transport changes are noninteractive) average NH 1680-minus-1780 temperature when filtered to isolate the multidecadal/cen- u (9), based on results for preindustrial condi- change of about -0.2 ___0.2°C from proxy tennial time scales associated with the Maun- _O tions from our two-dimensional (2D) chem- data (6) or an energy balance model (7) der Minimum, and lagged to allow for inertia istry model (10). These show more ozone in (model NH cooling is-0.33 C). Other proxy- in the ocean's response, the empirical regres- i _0 the upper and lower stratosphere, as expected based reconstructions for the NH extratropics sion (Fig. 3, bottom) shows a clear AO/NAO- (11), primarily because of the absence of during summer indicate a -0.3 to -0.4°C type pattern of alternating cold land and t- i- anthropogenic halogens and a drier strato- cooling (4,5) (comparable model cooling is warm ocean temperature anomalies. Both pa- sphere (12). Ozone's temperature sensitivity -0.3°C). leoclimate reconstructions and the GCM thus was also increased throughout the upper Modeled surface temperature changes indicate in a remarkably consistent manner stratosphere, more than doubling at 3 milli- show alternating warm oceans and cold con- that solar forcing affects regional scales much bars (mbar) relative to the present (13). Solar tinents at NH mid-latitudes (Fig. 1), with more strongly than global or hemispheric heating then speeds up chemical destruction maximum amplitude inwinter. To character- scales through forcing of the AO/NAO. more than irradiance enhances photolytic ize regional changes, we calculated empirical Most additional paleoclimate data have production, so that ozone concentration de- orthogonal functions (EOFs) from the NH insufficient time resolution to distinguish the extratropical (20 °to 90°N) cold season (from Maunder Minimum but suggest a shift toward _NASAGoddardInstitute forSpaceStudiesandCen- November to April) sea level pressure (SLP) the AO/NAO low-index state during periods terfor ClimateSystemsResearch,ColumbiaUniver- time series. The last 40 years of each run of reduced solar forcing. Ocean sediments sity,New York,NY 1002S, USA._Department of were used as an 80-year control. show a decreased SST of I to 2°C in the EnvironmentalSciences,University ofVirginia,Char- lottesviile,VA 22902, USA._Department of Geo- The leading control EOF (Fig. 2) closely Sargasso Sea during the 16th to 19th centu- sciences,Universityof Massachusetts,Amherst,MA matches the Arctic Oscillation pattern (AO, ries, and warmer Atlantic temperatures north 01003.USA also called the Northern Hemisphere Annular of 44°,extending to the area off Newfound- www.sciencemag.org SCIENCE VOL 0 • MONTH 2001 1 REPORTS ........ Ir_-= I- I I 1 I:_1 I -1.31 -.7 -.5 -.35 -.2 -.05 .05 .2 .35 .5 .7 .9 Annual Temperature change (C) -1.75 -.7 -.5 -.35 -.2 -.05 .05 .2 .35 .5 .7 .9 Winter Temperature change (C) Fig.1.Surfacetemperature change(in°C) from 1780 to 1680 inthe GCM.Global annua[ average (left) andNovember toApril NH extratropics (right) areshown. Nearly allpoints arestatistically significant (not shown) becauseof theLargenumber of model years. Data for all figuresareavaitabte as online supplemental material (40). (27, 28), and zonal wind and planetary wave propagation changes over recent decades are well reproduced in the model (22). Reduced irradiance during the Maunder Minimum causes a shift toward the low-index AO/NAO state via this same mechanism. During December to February, the surface cools by 0.4 ° to 0.5°C because of reduced incoming radiation and the upper stratospher- ic ozone increase. Cooling in the tropical and subtropical upper troposphere is even more pronounced (-0.8°C) because of cloud feed- backs, including an -0.5% decrease in high cloud cover induced by ozone through sur- face effects. A similar response was seen in simulations with a finer resolution version of the GISS GCM (14). This cooling signifi- I I..... : I I I I_: TI I cantly reduces the latitudinal temperature -7.0-2.5-1.9-1.4-.8 -.3 .3 .8 1.4 1.9 2.5 3 -2.2-1.6-1.2-.9 -.5 -.2 .2 .5 .9 1.2 1.6 2.3 gradient in the tropopause region, decreasing Pressure (mb) Pl_mSure (rob) the zonal wind there at _40°N. Planetary Fig.2. The leadingEOF ofNH extratropicaL November-to-April SLPover the past40 years of the waves coming up from the surface at mid- 1680 and 1780 simulations (left), and the SLPchange from 1780 to 1680 (right), both in mbar latitudes, which are especially abundant dur- (mb). The SLPdifference isfiltered inEOFspacebyshowing the projection onto thefirst 20 EOFs, ing winter, are then deflected toward the which contain 70% of the total difference. This removes some ofthe high-frequency noiseinthe equator less than before (equatorward Elias- model induced byoverly large energies at high wavenumber_ Hatched areas indicate statistical significance at the 90% Level. sen-Palm flux is reduced by 0.41 m2/s 2, 12° to 35°N, 300 to 100 mbar average), instead land (23), which isconsistent with a reduced processes. This results in (iii) an increased propagating up into the stratosphere (in- NAO but not with uniform basin-wide cool- latitudinal temperature gradient at around 100 creased vertical flux of 6.3 × l0 -4 m2/s 2, 35° ing. Other evidence suggests colder North to 200 mbar, because these pressures are in to 60°N, 100 to 5 mbar average) (29). This Atlantic temperatures during those centuries, the stratosphere at higher latitudes, and so do increases the wave-driven stratospheric resid- however, including evidence for increased not feel the surface warming (26). The tem- ual circulation, which warms the polar lower sea ice around Iceland (24), a region of min- perature gradient leads to (iv) enhanced lower stratosphere (up to I°C), providing a positive imal change in the GCM. stratospheric westerly winds, which (v) re- feedback by further weakening the latitudinal Our previous studies have demonstrated fract upward, propagating tropospheric plan- temperature gradient. The wave propagation how external forcings can excite the AO/ etary waves equatorward. This causes (vi) changes imply a reduction in northward an- NAO in the GISS GCM (22, 25). Briefly, the increased angular momentum transport to gular momentum transport, hence a slowing mechanism works as follows, using a shift high latitudes and enhanced tropospheric down of the middle- and high-latitude west- erlies and a shift toward the low AO/NAO toward the high-index AO/NAO as an exam- westerlies, and the associated temperature ple: (i) tropical and subtropical SSTs warm, and pressure changes corresponding to a high index. Because the oceans are relatively leading to (ii) a warmer tropical and subtrop- AO/NAO index. Observations support a warm during the winter owing to their large ical upper troposphere via moist convective planetary wave modulation of the AO/NAO heat capacity, the diminished flow creates a 2 • HONTH 2001 VOL 0 SCIENCE www.sciencemag.org REPORTS 8O ilar experiments (32). The ECHAM3 GCM exhibits a similar spatial pattern of response to solar forcing, 6O with warming over the NH continents and cooling over the North Atlantic and North 4O Pacific (33). In that model, however, the sur- face temperature and AO sensitivity were much less than in our simulation. This is probably due to the lack of interactive ozone and the poorly resolved stratosphere, two im- portant positive feedbacks in our model. The importance of SST changes to initiate -.9 -.7 -.S -.35 -.2 -.05 .05 .2 .35 .5 .7 the AO/NAO response is consistent with our Temperature change (C) fixed-SST solar cycle experiments (9, 22), whose response did not project strongly onto the AO/NAO, and with the weak empirical instantaneous climate sensitivity (Fig. 3, top). Present-day observations and modeling also support links between long-term tropical SST changes and the NAO (34,35). Surface temperatures in an energy bal- ance model (36) driven by volcanic forcing gave a poor correlation with proxies during the 17th and 18th centuries. Correlations between calculations of solar-induced cli- mate change and temperature proxies were quite good, however, although the impacts -.0 -.7 -.s --.36 -2 -.05 .05 .2 .35 .s .7 .0 were very small. Inclusion of ozone chem- ical feedback would amplify the response, Temperature change (C) potentially reproducing observed ampli- Fig. 3.Regression duringthe period from 1650 to 1850 between reconstructed solar irradiance (1) tudes as well as variability. and annual average surface temperatures (19). The top panel shows the instantaneous regression The GISS model results and empirical over alltime scales, whereas the bottom panel shows the regression when filtered to onLyinclude contributions from time scales longer than 40 years, with a20-year lag(resuLtsare similar fortime reconstructions both suggest that solar-forced lagsof 10to 30years). Thecorrelation isgivenin °C per-0.32 W/m z(the solar forcing usedinthe regional climate changes during the Maunder modeL) for comparison with the modeLedtemperature changes shown in Fig.1.Gray areasindicate Minimum appeared predominantly as a shift no data; hatched areas indicate statistical significance atthe 90% Level. toward the low AO/NAO index. Although global average temperature changes were cold-land/warm-ocean surface pattern (Fig. and climate feedbacks are included, the cool- small, modeled regional cooling over the 1). ing drops to --0.19°C. With current atmo- continents during winter was up to five times To quantify the importance of ozone spheric composition, ozone enhancement greater. Changes in ocean circulation were changes, an identical pair of 1680 and 1780 from increased irradiance outweighs temper- not considered in this model. However, given experiments was run, leaving out the ozone ature-induced changes, leading to more mid- the sensitivity of the North Atlantic to AO/ response. These simulations show areduction die and upper stratospheric ozone (9), which NAO forcing (37), oceanic changes may well in the AO index of only 0.5 mbar, and the dampens the net radiative forcing. Ozone's have been triggered as a response to the SLP change projection onto the AO was reversal from apositive (preindustrial) to a atmospheric changes (38). Such oceanic 15.1%. Thus, there was an analogous but negative feedback supports results showing changes would themselves further modify the weaker response without interactive ozone. that solar forcing has been a relatively minor pattern of SST in the North Atlantic (39) and, The ozone changes further reduce the tropo- contributor to late 20th-century surface to a lesser extent, the downstream air temper- pause radiative forcing by -0.02 W/m 2 (in- warming (7, 19, 31). However, ozone feed- ature anomalies in Europe. stantaneous, but with adjusted stratospheric backs remain important to the dynamical re- These results provide evidence that rela- temperatures) for 1680 conditions (compared sponse associated with decadal and shorter tively small solar forcing may play a signif- to the direct solar forcing of-0.32 W/m2). term solar variability, which is initiated by icant role in century-scale NH winter climate Cloud feedbacks caused by ozone magnify its upper stratospheric temperature changes, change. This suggests that colder winter tem- influence somewhat, so that the global annual which are proportional to solar heating and peratures over the NH continents during por- average surface temperature change increases hence to ozone (9). tions of the 15th through the 17th centuries from -0.28°C to -0.34°C, including ozone The AO/NAO response is dependent on (sometimes called the Little Ice Age) and chemistry. The largest impacts resulted from the overall forced change in tropical and sub- warmer temperatures during the 12th through the enhancement of the tropopause region tropical SSTs, translation of these changes 14th centuries (the putative Medieval Warm latitudinal temperature gradient through high into upper tropospheric temperature changes Period) may have been influenced by long- cloud changes and subsequent wave-driven by hydrological feedbacks, and the resulting term solar variations. feedbacks. wind and planetary wave refraction changes. In contrast to the preindustrial simula- These processes vary between models and in References and Notes tions, 20th-century simulations (30) show particular are sensitive to the inclusion of a 1.J.Lean,J.Beer,R.Bradley,Geophys.Res.Lett.22, that solar irradiance changes alone warm the realistic stratosphere (22, 25), emphasizing 319s 099s). surface by -0.25°C, but when ozone changes the need for intermodel comparisons of sim- 2. E.Bardetal.,TellusB52,985 (2000). www.sciencemag.org SCIENCE VOL 0 • MONTH 2001 3 REPORTS 3. M. Stuiver, T. F. Braziunas, Radiocarbon 35. 137 the rate-limiting reactions for the chlorine, nitrogen, Thompson, J.R.Holton. Proc. Natl. Acad. 5d. U.S.A. (1993). and hydrogen cycles isweakly negative, whereas for 97, 1412 (2000). 4. K.Briffa et al., Nature 393, 350 (1998). oxygen itisstrongly positive. The relative importance 29. The flux changes are roughly -1/3 those seen inour 5. P. Jones et al., Holocene 8, 455 (1998). of the oxygen cycle was greater during the preindus- greenhouse gas forcing simulations (22, _>5),which is 6. M. E.Mann, R.S.Bradley, M. K.Hughes, Geophys. Res. trial period, leading to large increases inoverall tem- consistent with the AO response ratio. Lett. 26, 759 (1999). perature sensitivity in the upper stratosphere. 30. Temperature change was calculated as the differ- 7. T. J.Cmwley, Science 289, 270 (2000). 14. J.Hansen, M. Sato, R.Ruedy, ]. Geophys. 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This isparticularly true before (1999). methane trends were taken from ice core data, 1730, when five or fewer eigenvectors are retained. 37. T.L Delworth, K.W. Dixon, J. C6m. 13, 3721 (2000). which show approximately 60% less methane dur- 21. A. M. Waple, M. E.Mann, R.S.Bradley, C6m. Dyn., in 38. W. S.Broecker, Proc. Natl. Acad. Sd U.S.A. 97, 1339 ingthe preindustrial period. Observations from the press. (2000). HALOE instrument, version 18data, obtained from 22. D. T. Shindell, G.A. Schmidt, R.L Miller, D. Rind, J. 39. M. Visbeck, H. CuUen, G. Krahmann, N. Naik, Geo- the NASA Langley data center, were used to de- Geophys. Res. 106, 7193 (2001). phys. Res. Lett. 25, 4521 (1998). termine the fraction of methane oxidized through- 23. L D. Keigwin, I_ S.Pickart, Science 286, 520 (1999). 40. Supplemental Web material is available on Science out the stratosphere. For example, at 1 mbar in 24. P. Bergth6rsson, J&kul! 19, 94 (1969). Online at www.sciencemag.org/cgi/contentJfull/ mid-latitudes, -1.6 parts per million by volume 25. D.T. Shindell, R.L Miller, G. A.Schmidt, L Pandolfo, VOL/ISSUE/PAGE/DCl. (ppmv) of water was removed relative to the Nature 399, 452 (1999). 41. Stratospheric climate modeling at GlSS is supported present based on 80% oxidation of the 1.0-ppmv 26. For forcing by greenhouse gases, the enhanced lati- by NASA's Atmospheric Chemistry Modeling and methane change. This assumes that the preindus- tudinal gradient isfurther strengthened bytheir cool- Analysis Program. GA.S. and D.T.S. acknowledge the trial methane oxidation rate in the stratosphere ing effect in the stratosphere. Ozone depletion and support of NSF grant ATM-00-02267. M.E.M ac- was aslarge asthat at present. This isfundamental volcanic forcing enhance the AO by an abbreviated knowledges support from the National Oceanic and to the negative ozone response, which differs from mechanism, directly altering temperatures near the Atmospheric Administration- and NSF-supported that seen in aprevious study (11). tropopause as instep (iii). Earth Systems History program. We thank J.Lean for 13. Ozone's temperature sensitivity isgoverned by cat- 27. Y. Ohhashi, K.Yamazaki, J. Meteorol. Soc. Jpn. T'I, providing the solar irradiance reconstruction. alytic cycles involving chlorine, nitrogen, hydrogen, 495 (1999). and oxygen radicals. The temperature dependence of 28. D.LHartmann, J.M.Wallace, V. Limpasuvan, D.W. J. 13 July 2001; accepted 31 October 2001 Artic[e is 585 picas 4 • MONTH 2001 VOL0 SCIENCE www.sciencemag.org