Climate Change 1995: The Science of Climate Change: Contribution of Working Group I to the Second Assessment Report of the Intergovernmental Panel on Climate ChangeCambridge University Press, 1996 M06 6 - 572 pages The IPCC reports represent the primary source of scientific and technical advice for the implementation of the UN Framework Convention on Climate Change. This assessment therefore forms the standard scientific reference for all those concerned with climate change and its consequences, including policy makers in governments and industry worldwide, and researchers and senior-level students in environmental science, meteorology, climatology, biology, ecology and atmospheric chemistry. |
From inside the book
Results 6-10 of 88
Page 21
... significant uncertainty remains but an estimate of +0.1 Wm2 ( range : 0.03 to 0.3 Wm2 ) is made . The direct radiative forcing since 1850 of particles associated with biomass burning is estimated to be -0.2 Wm2 ( range : -0.07 to −0.6 ...
... significant uncertainty remains but an estimate of +0.1 Wm2 ( range : 0.03 to 0.3 Wm2 ) is made . The direct radiative forcing since 1850 of particles associated with biomass burning is estimated to be -0.2 Wm2 ( range : -0.07 to −0.6 ...
Page 34
... significant source of potential error in climate simulation . This potential error can be estimated by first noting that if clouds and sea ice are kept fixed according to their observed distributions and properties , climate models ...
... significant source of potential error in climate simulation . This potential error can be estimated by first noting that if clouds and sea ice are kept fixed according to their observed distributions and properties , climate models ...
Page 36
... significant contributions to the radiative forcing , all such pattern comparison studies show significant correspondence between the observations and model predictions ( an example is shown in Figure 17 ) . Much of 0.75 ( a ) 0.50 0.25 ...
... significant contributions to the radiative forcing , all such pattern comparison studies show significant correspondence between the observations and model predictions ( an example is shown in Figure 17 ) . Much of 0.75 ( a ) 0.50 0.25 ...
Page 37
Sorry, this page's content is restricted.
Sorry, this page's content is restricted.
Page 45
Sorry, this page's content is restricted.
Sorry, this page's content is restricted.
Contents
XXXI | 37 |
XXXV | 39 |
XXXVI | 40 |
XXXVII | 41 |
XXXIX | 42 |
XL | 43 |
XLI | 44 |
XLII | 47 |
CLXVII | 242 |
CLXIX | 243 |
CLXXVI | 244 |
CLXXVIII | 245 |
CLXXX | 246 |
CLXXXII | 247 |
CLXXXIV | 251 |
CLXXXV | 252 |
XLIV | 51 |
XLV | 53 |
XLVI | 55 |
XLVIII | 56 |
XLIX | 57 |
LI | 58 |
LIV | 59 |
LV | 60 |
LVI | 61 |
LVIII | 65 |
LIX | 71 |
LX | 72 |
LXII | 76 |
LXIV | 78 |
LXV | 79 |
LXVI | 80 |
LXVII | 81 |
LXVIII | 82 |
LXXI | 83 |
LXXIII | 84 |
LXXV | 86 |
LXXVII | 87 |
LXXX | 90 |
LXXXI | 91 |
LXXXII | 92 |
LXXXIII | 99 |
LXXXV | 101 |
LXXXVI | 102 |
LXXXVII | 103 |
LXXXVIII | 104 |
LXXXIX | 105 |
XC | 107 |
XCIII | 108 |
XCV | 109 |
XCVI | 110 |
XCVII | 111 |
XCVIII | 114 |
CI | 116 |
CII | 118 |
CIV | 120 |
CV | 129 |
CVI | 133 |
CVII | 137 |
CVIII | 138 |
CIX | 139 |
CX | 142 |
CXI | 143 |
CXII | 144 |
CXIII | 145 |
CXVII | 146 |
CXVIII | 147 |
CXX | 148 |
CXXI | 152 |
CXXIII | 154 |
CXXV | 155 |
CXXVI | 156 |
CXXVII | 157 |
CXXIX | 158 |
CXXXI | 159 |
CXXXV | 161 |
CXXXVI | 163 |
CXXXVIII | 164 |
CXLIII | 165 |
CXLV | 166 |
CXLVI | 167 |
CXLVII | 168 |
CL | 169 |
CLII | 170 |
CLIII | 173 |
CLIV | 175 |
CLVI | 177 |
CLVII | 189 |
CLVIII | 223 |
CLIX | 227 |
CLX | 229 |
CLXIII | 238 |
CLXXXVI | 253 |
CLXXXVII | 254 |
CLXXXVIII | 255 |
CXCII | 257 |
CXCIII | 258 |
CXCIV | 260 |
CXCVII | 261 |
CXCVIII | 263 |
CC | 264 |
CCI | 265 |
CCIV | 267 |
CCV | 268 |
CCVII | 269 |
CCVIII | 270 |
CCIX | 279 |
CCXI | 353 |
CCXII | 357 |
CCXIII | 359 |
CCXV | 364 |
CCXVII | 365 |
CCXVIII | 367 |
CCXIX | 368 |
CCXX | 371 |
CCXXI | 373 |
CCXXII | 374 |
CCXXIII | 375 |
CCXXV | 376 |
CCXXVI | 377 |
CCXXVII | 378 |
CCXXVIII | 379 |
CCXXX | 380 |
CCXXXII | 382 |
CCXXXIII | 383 |
CCXXXVII | 385 |
CCXXXVIII | 387 |
CCXXXIX | 388 |
CCXLI | 389 |
CCXLII | 390 |
CCXLIII | 391 |
401 | |
CCXLV | 405 |
CCXLVI | 407 |
CCXLVIII | 409 |
CCLI | 411 |
CCLII | 412 |
CCLIII | 413 |
CCLIV | 414 |
CCLV | 415 |
CCLVI | 416 |
CCLVII | 417 |
CCLIX | 418 |
CCLX | 419 |
CCLXI | 424 |
CCLXII | 425 |
CCLXIII | 428 |
CCLXIV | 429 |
CCLXV | 431 |
CCLXVI | 432 |
CCLXVII | 433 |
CCLXVIII | 439 |
CCLXX | 477 |
CCLXXII | 511 |
CCLXXIII | 515 |
CCLXXIV | 517 |
CCLXXV | 519 |
CCLXXVI | 521 |
CCLXXVII | 524 |
CCLXXVIII | 527 |
CCLXXX | 529 |
CCLXXXII | 531 |
CCLXXXIV | 545 |
CCLXXXVI | 559 |
CCLXXXVIII | 563 |
CCXC | 565 |
Other editions - View all
Common terms and phrases
aerosol aerosol forcing albedo analysis anomalies anthropogenic AOGCM areas Assessment atmospheric CO2 average biogeochemical carbon cycle century Chapter circulation model Clim climate change climate models climate sensitivity climate system climate variability cloud CO₂ convection coupled models decades decrease distribution dynamics ecosystems effects El Niño-Southern Oscillation emission scenarios ENSO estimates experiments feedbacks Figure flux adjustment Geophys glaciers global climate global mean temperature global warming greenhouse gases GtC/yr GWPS high latitudes ice sheet increase interannual IPCC land land-surface marine Meteorological methane natural variability North Atlantic Northern Hemisphere observed ocean models Pacific parametrization patterns ppmv precipitation processes projections radiation radiative forcing rainfall range recent Research response scale sea ice sea level change sea level rise Section simulations soil moisture solar spatial stabilisation stratospheric studies sulphate aerosols surface air temperature temperature change terrestrial thermohaline circulation time-scales trends tropical tropospheric ozone uncertainties variations water vapour Wigley