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Trenberth on Tracking Earth’s energy: A key to climate variability and change

Posted on 12 July 2011 by Kevin Trenberth

Energy and Climate

Climate change is very much involved with energy, most commonly in the form of heat but other forms of energy are also important. Radiation comes in from the sun (solar radiation at short wavelengths), and every body radiates according to its temperature (proportional to the fourth power of absolute temperature), so that on Earth we, and the surface and atmosphere radiate at infrared wavelengths. 

Weather and climate on Earth are determined by the amount and distribution of incoming radiation from the sun.  For an equilibrium climate, global mean outgoing longwave radiation (OLR) necessarily balances the incoming absorbed solar radiation (ASR), but with redistributions of energy within the climate system to enable this to happen on a global basis.  Incoming radiant energy may be scattered and reflected by clouds and aerosols (dust and pollution) or absorbed in the atmosphere.  The transmitted radiation is then either absorbed or reflected at the Earth’s surface. Radiant solar (shortwave) energy is transformed into sensible heat (related to temperature), latent energy (involving different water states), potential energy (involving gravity and altitude) and kinetic energy (involving motion) before being emitted as longwave infrared radiant energy.  Energy may be stored, transported in various forms, and converted among the different types, giving rise to a rich variety of weather or turbulent phenomena in the atmosphere and ocean.  Moreover the energy balance can be upset in various ways, changing the climate and associated weather.

Hence the incoming radiation may warm up the ground or any object it hits, or it may just go into drying up surface water. After it rains and the sun comes out, the puddles largely dry up before the temperature goes up.   If energy is absorbed it raises the temperature.  The surface of the body then radiates but also loses heat by transfer through cooler winds or by evaporative cooling.  Some energy gets converted into motion as warm air rises and cold air sinks, and this creates winds and thus kinetic energy, which gets dissipated by friction.  Over oceans the winds drive ocean currents. 

The differential between incoming and outgoing radiation: the net radiation is generally balanced by moving air of different temperature and moisture content around.  Air temperature affects density as warmer air expands and thus it takes up more room, displacing cooler air, thereby changing the air in a column whose weight determines the surface pressure.  Consequently, this sets up pressure differences that in turn cause winds, which tend to blow in such a way as to try to offset the temperature differences. The Earth’s rotation modifies this simple picture. A result is that southerlies are warm in the northern hemisphere and northerlies are cold.  And so we get weather with clouds and rain in all of its wondrous complexity.

The changing seasons illustrate what happens as the sun apparently moves across the equator into the other hemisphere.  In summer some excess heat goes into the ocean, which warms up reaching peak values about the equinox, and in winter the land cools off but heat comes out of the oceans and this is carried onto land, and so oceans moderate the seasonal climate variations.  Much of the exchange involves water evaporating and precipitating out, and thus the hydrological cycle.

The same can happen from year to year: heat can accumulate in the ocean and then later be released, leading to warmer spells and cooler spells.  This commonly happens in the tropical Pacific and gives rise to the El Niño phenomenon.  El Niño is the warm phase in the tropical Pacific while La Niña is the cool phase.  During and following an El Niño there is a mini global warming as heat comes out of the ocean, while during La Niña, heat tends to get stored in the ocean.  The El Niño cycle is irregular but has a preferred time scale of 3 to 7 years.

Ocean heat storage can last longer: for decades or centuries and inevitably involves ocean currents and the much deeper ocean.  In the North Atlantic, cold waters sink and move equatorward at depth while the Gulf Stream at the surface takes warmer waters polewards, creating an overturning circulation that can also involve density changes in the ocean associated with both temperature and salt (the thermohaline circulation). Salty water is denser. Nonetheless, much of the ocean overturning circulation is wind driven. The overturning may involve the ocean down to several kilometers and can take many centuries to complete a cycle.

As well as the ocean taking up heat, heat can be lost by forming ice, as glaciers, ice caps, or major ice sheets (Greenland and Antarctica) on land, or as sea ice. Extra heat can melt this ice and may contribute to sea level rise if land ice melts.  Surface land can also absorb a small amount of heat but not much and not to great depths as it relies on conduction to move heat through the land unless water is flowing. Land energy variations occur mostly in the form of water or its absence, as heat goes to evaporate surface water.  Highest temperatures and heat waves typically occur in droughts or deserts.

The atmosphere can not hold much heat and is dependent for its temperature on links to the underlying surface through conduction and thermals, convection, and radiation, as well as the wind in moving it around.

The global energy budget

In the past, we (Kiehl and Trenberth 1997) provided estimates of the global mean flow of energy through the climate system and presented a best-estimate of the energy budget based on various measurements and models, by taking advantage of the fact that energy is conserved.  We also performed a number of radiative computations to examine the spectral features of the incoming and outgoing radiation and determined the role of clouds and various greenhouse gases in the overall radiative energy flows. At the top-of-atmosphere (TOA) values relied heavily on observations from the Earth Radiation Budget Experiment (ERBE) from 1985 to 1989, when the TOA values were approximately in balance. 

Values are given in terms of Watts per square meter. The incoming radiation is about 342 W m-2.  But there are about 5.1x1014 square meters for the surface area and so the total incoming energy is about 174 PetaWatts (=1015 watts, and so 174 with 15 zeros after it or 174 million billion).  About 30% is reflected back to space and so about 122 PW flows through the climate system.  For comparison, the biggest electric power plants are of order 1000 MegaWatts, and so the natural flow of energy is 122 million of these power plants.  If we add up all of the electric energy generated and add in the other energy used by humans through burning etc, it comes to about 1/9000th of the natural energy flow.  Hence the direct effects of human space heating and energy use are small compared with the sun, although they can become important very locally in cities where they contribute to the urban heat island effect.

New observations from space have enabled improved analyses of the energy flows. Trenberth et al. (2009) have updated the earlier global energy flow diagram (Fig. 1) based on measurements from March 2000 to November 2005, which include a number of improvements. We deduced the TOA energy imbalance to be 0.9 W m-2, where the error bars are ±0.5 W m-2 based on a number of estimates from both observations and models.

Figure1

Figure 1. The global annual mean Earth’s energy budget for 2000 to 2005 (W m–2). The broad arrows indicate the schematic flow of energy in proportion to their importance.  From Trenberth et al (2009).

The net energy incoming at the surface is 161 W m-2, and this is offset by radiation (63), evaporative cooling (80), and direct heating of the atmosphere through thermals (17).  Consequently, evaporative cooling and the resulting water cycle play a major role in the energy balance at the surface, and for this reason, storms are directly affected by climate change. The biggest loss at the surface is from long-wave radiation but this is offset by an almost as big downward radiation from greenhouse gases and clouds in the atmosphere to give the net of 63 units. 

Updates included in this figure are revised absorption in the atmosphere by water vapor and aerosols. The direct transfer of heat has values of 17, 27 and 12 W m-2 for the globe, land and ocean, and even with uncertainties of 10%, the errors are only order 2 W m-2. There is widespread agreement that the global mean surface upward longwave (LW) radiation is about 396 W m-2, which is dependent on the skin temperature and surface emissivity.

Global precipitation should equal global evaporation for a long-term average, and estimates are likely more reliable of the former. However, there is considerable uncertainty in precipitation over both the oceans and land.  The latter is mainly due to wind effects, undercatch and spatial coverage, while the former is due to shortcomings in remote sensing.  The downward and net LW radiation were computed as a residual and compared to various estimates which tend to be higher but all involve assumptions and models. The correct depiction of low clouds is a continuing challenge for models and is likely to be a source of model bias in downward LW flux. For example, there are sources of error in how clouds overlap in the vertical and there is no unique way to treat the effects of overlap on the downward flux.

The new observations from space have enabled improved analyses of the energy flows, their variations throughout the annual cycle, for land versus ocean, as a function of location, and also over a number of years. There is an annual mean transport of energy by the atmosphere from ocean to land regions of 2.2±0.1 PW primarily in the northern winter when the transport exceeds 5 PW.  It is now possible to provide an observationally based estimate of the mean and annual cycle of ocean energy, mainly in the form of ocean heat content. 

Note that the sum of all the values at the TOA and at the surface in the figure leaves an imbalance of 0.9 W m-2, which is causing global warming.  As carbon dioxide and other greenhouse gases increase in the atmosphere, there is initially no change in the incoming radiation, but more energy is trapped and some is radiated back down to the surface. This decreases OLR and leads to warming.  At the surface the warming raises temperatures and thus increases the surface radiation, but there is still a net amount of energy that partly goes into heating the ocean and melting ice, and some of it goes into increasing evaporation and thus rainfall.  To achieve an energy balance, the vertical structure of the atmosphere changes, and the radiation to space ultimately comes from higher regions that were originally colder.  In that sense, the figure is misleading because it does not show the vertical structure of the atmosphere or how it is changing.

There is often confusion about how the greenhouse effect works. Greenhouse gases are those with more than two atoms, and water vapor is most important (H2O).  But water has a short lifetime in the atmosphere of 9 days on average before it is rained out. Carbon dioxide (CO2), on the other hand, has a long lifetime, over a century, and therefore plays the most important role in climate change while water vapor provides a positive feedback or amplifying effect: the warmer it gets, the more water vapor the atmosphere can hold by about 4% per degree Fahrenheit.  Most of the atmosphere is nitrogen (N2) and oxygen (O2) and does not play a role in the greenhouse effect.  Oxygen does play an important role through ozone (O3) though, especially in the stratosphere where an ozone layer forms from effects of ultraviolet light. Ozone is not well mixed throughout the atmosphere as it has a short lifetime in parts of the stratosphere, and in the lower atmosphere its life is measured in months as it plays a role in oxidation.

The air is otherwise well mixed up to about 80 km altitude and heavier gases like carbon dioxide do not settle out owing to all the turbulent motions, convection, and so on. Also the other long lived greenhouse gases are well mixed and connect to the non-greenhouse gases with regard to temperature.  Air near the surface has a temperature not much less than the surface on average, and therefore it radiates back down with almost as much energy as came up from below.  But because the air gets thinner with height, its temperature falls off, and air is a lot colder at 10 km altitude where ‘planes typically fly. This air therefore radiates less both up and down, and the net loss to space is determined by the vertical temperature structure of the atmosphere and the distribution of greenhouse gases.

Changes in energy balance over the past decade

With the new measurements from space, variability in the net radiative incoming energy at the top-of-atmosphere (TOA) can now be measured very accurately. Thus a key objective is to track the flow of anomalies in energy input or output through the climate system over time in order to address the question as to how variability in energy fluxes is linked to climate variability.  The main energy reservoir is the ocean (Fig. 2 below), and the exchange of energy between the atmosphere and ocean is ubiquitous, so that heat once sequestered can resurface at a later time to affect weather and climate on a global scale.  Thus a change in the energy balance has consequences, sooner or later, for the climate.  Moreover, we have observing systems in place that nominally can measure the major storage and flux terms, but due to errors and uncertainty, it remains a challenge to track anomalies with confidence.

Figure2

Figure 2. Energy content changes in different components of the Earth system for two periods (1961–2003 and 1993–2003). Blue bars are for 1961 to 2003; burgundy bars are for 1993 to 2003. Positive energy content change means an increase in stored energy (i.e., heat content in oceans, latent heat from reduced ice or sea ice volumes, heat content in the continents excluding latent heat from permafrost changes, and latent and sensible heat and potential and kinetic energy in the atmosphere). All error estimates are 90% confidence intervals. No estimate of confidence is available for the continental heat gain. Some of the results have been scaled from published results for the two respective periods.  From (IPCC 2007, Fig. TS.15 and Fig. 5.4).

A climate event, such as the drop in surface temperatures over North America in 2008, is often stated to be due to natural variability, as if this fully accounts for what has happened.  Aside from weather events that primarily arise from instabilities in the atmosphere, natural climate variability has a cause.  Its origins may be external to the climate system: a change in the sun, a volcanic eruption, or Earth’s orbital changes that ring in the major glacial to interglacial swings.  Or its origins may be internal to the climate system and arise from interactions among the atmosphere, oceans, cryosphere and land surface, which depend on the very different thermal inertia of these components. 

El Niño

As an example of natural variability, the biggest El Niño in the modern record by many measures occurred in 1997-98. Successful warnings were issued a few months in advance regarding the unusual and disruptive weather across North America and around the world, and were possible in part because the energy that sustains El Niño was tracked in the ocean by a new moored buoy observing system in the Tropical Pacific.  Typically prior to an El Niño, in La Niña conditions, the cold sea waters in the central and eastern tropical Pacific create high atmospheric pressure and clear skies, with plentiful sunshine heating the ocean waters.  The ocean currents redistribute the ocean heat which builds up in the tropical western Pacific Warm Pool until an El Niño provides relief.  The spread of warm waters across the Pacific in collaboration with changing winds in turn promotes evaporative cooling of the ocean, moistening the atmosphere and fueling tropical storms and convection over and around the anomalously warm waters. The changed atmospheric heating alters the jet streams and storm tracks, and influences weather patterns for the duration of the event.

The central tropical Pacific SSTs are used to indicate the state of El Niño, as in Fig. 3 presented below.  In 2007-08 a strong La Niña event, that spilled over to the 2008-09 northern winter, had direct repercussions for cooler weather across North America and elsewhere.  But by June 2009, the situation had reversed as the next El Niño emerged and grew to be a moderate event, with temperatures in the top 150 m of the ocean above normal by as much as 5°C across the equatorial Pacific in December 2009.  Multiple storms barreled into Southern California in January 2010, consistent with expectations from the El Niño. The El Niño continued until May 2010, but abruptly reversed to become a strong La Niña by July 2010.

Figure3

Figure 3.  Recently updated net radiation (RT=ASR-OLR) from the TOA http://ceres.larc.nasa.gov/products.php?product=EBAF.  Also shown is the Niño 3.4 SST index (green) (left axis); values substantially above the zero line indicate El Niño conditions while La Niña conditions correspond to the low values. The decadal low pass filter is a 13 term filter making it similar to a 12-month running mean.  Units are Wm-2 for energy and deg C for SST.

We can often recognize these changes once they have occurred and they permit some level of climate forecast skill. But a major challenge is to be able to track the energy associated with such variations more thoroughly: where did the heat for the 2009-10 El Niño actually come from?  Where did the heat suddenly disappear to during the La Niña?  Past experience suggests that global surface temperature rises at the end of and lagging El Niño, as heat comes out of the Pacific Ocean mainly in the form of moisture that is evaporated and which subsequently rains out, releasing the latent energy. 

The values and patterns of SSTs in the northern summer of 2010 undoubtedly influenced the extremes of weather, from excessive rains and flooding in China, India and Pakistan, the active hurricane season in the Atlantic, and record breaking rains in Colombia. Later the high SSTs north of Australia contributed to the Queensland flooding.  The La Niña signature has also been present across the United States in the spring of 2011 with the pattern of drought in Texas and record high rains further to the north, with flooding along the Mississippi and deadly tornado outbreaks.

Anthropogenic climate change

The human influence on climate, arising mostly from the changing composition of the atmosphere, also affects energy flows. Increasing concentrations of carbon dioxide and other greenhouse gases have led to a post-2000 imbalance at the TOA of 0.9±0.5 W m-2 (Trenberth et al. 2009) (Fig. 1), that produces “global warming”, or more correctly, an energy imbalance.  Tracking how much extra energy has gone back to space and where this energy has accumulated is possible, with reasonable closure for 1993 to 2003; see Fig. 2. Over the past 50 years, the oceans have absorbed about 90% of the total heat added to the climate system while the rest goes to melting sea and land ice, and warming the land surface and atmosphere. Because carbon dioxide concentrations have further increased since 2003 the amount of heat subsequently being accumulated should be even greater. 

While the planetary imbalance at TOA is too small to measure directly from satellite, instruments are far more stable than they are absolutely accurate.  Tracking relative changes in Earth’s energy by measuring  solar radiation in and infrared radiation out to space, and thus changes in the net radiation, seems to be at hand.  This includes tracking the slight decrease in solar insolation from 2000 until 2009 with the ebbing 11-year sunspot cycle; enough to offset 10 to 15% of the estimated net human induced warming.

In 2008 for the tropical Pacific during La Niña conditions, extra TOA energy absorption was observed as expected; see Fig. 3. The Niño 3.4 SST index is also plotted on this figure and the slightly delayed response of the OLR to cooler conditions in the record and especially in 2008 is clear. However, the decrease in OLR with cooler conditions is accompanied by an increase in ASR as clouds decrease in amount, leaving a pronounced net heating (>1.5 W m-2) of the planet in the cooler conditions.  And so this raises the question as to whether a coherent perspective that accounts for both TOA and ocean variability can be constructed from the available observations.  But ocean temperature measurements from 2004 to 2008 suggested a substantial slowing of the increase in global ocean heat content, precisely during the time when satellite estimates depict an increase in the planetary imbalance.

Since 1992, sea level observations from satellite altimeters at millimeter accuracy reveal a global increase of ~3.2 mm yr-1 as a fairly linear trend, although with two main blips corresponding to an enhanced rate of rise during the 1997-98 El Niño and a brief slowdown in the 2007-08 La Niña.  Since 2003, the detailed gravity measurements from Gravity Recovery and Climate Experiment (GRACE) of the change in glacial land ice and water show an increase in mass of the ocean. This so-called eustatic component of sea level rise may have compensated for the decrease in the thermosteric (heat related expansion) component.  However, for a given amount of heat, 1 mm of sea level rise can be achieved much more efficiently – by a factor of 40 to 70 typically – by melting land ice rather than expanding the ocean.  So although some heat has gone into the record breaking loss of Arctic sea ice, and some has undoubtedly contributed to unprecedented melting of Greenland and Antarctica, these anomalies are unable to account for much of the measured TOA energy (Fig. 4).   This gives rise to the concept of “missing energy” (Trenberth and Fasullo 2010). 

Figure4

Figure 4.  The disposition of energy entering the climate system is estimated.  The observed changes (lower panel; Trenberth and Fasullo 2010) show the 12-month running means of global mean surface temperature anomalies relative to 1901-2000 from NOAA (red (thin) and decadal (thick)) in °C (scale lower left), carbon dioxide concentrations (green) in ppmv from NOAA (scale right), and global sea level adjusted for isostatic rebound from AVISO (blue, along with linear trend of 3.2 mm/yr) relative to 1993, scale at left in millimeters).  From 1992 to 2003 the decadal ocean heat content changes (blue) along with the contributions from melting glaciers, ice caps, Greenland, Antarctica and Arctic sea ice plus small contributions from land and atmosphere warming (red) suggest a total warming for the planet of 0.6±0.2 W m-2 (95% error bars).  After 2000, preliminary observations from TOA (black) referenced to the 2000 values, as used in Trenberth and Fasullo (2010), show an increasing discrepancy (gold) relative to the total warming observed (red).  The quiet sun changes in total solar irradiance reduce the net heating slightly but a large energy component is missing (gold). Adapted from Trenberth and Fasullo (2010). The monthly global surface temperature data are from NCDC, NOAA: http://www.ncdc.noaa.gov/oa/climate/research/anomalies/index.html ; the global mean sea level data are from AVISO satellite altimetry data: http://www.aviso.oceanobs.com/en/news/ocean-indicators/mean-sea-level/ ; and the Carbon dioxide at Mauna Loa data are from NOAA http://www.esrl.noaa.gov/gmd/ccgg/trends/.

To emphasize the discrepancy, Fig. 5 presents an alternative version of Fig. 2 for 1992 to 2003, as a contrast to 2004 to 2008.  The accounting for all terms and the net imbalance is compatible with physical expectations and climate model results, with the net imbalance about 0.7 W m-2 at TOA for 1992 to 2003.  However, for the 2004 to 2008 period, the decrease in solar radiation associated with the sunspot cycle and the quiet sun in 2008 contributed somewhat, but the Ocean Heat Content (OHC) change is a lot less than in the previous period and a residual imbalance term: the missing energy, is required.

Figure5

Figure 5.  The energy entering the climate system is estimated for the various components: warming of the atmosphere and land, ocean heat content increase, melting of glaciers and ice caps (land ice), melting of the major ice sheets (Greenland and Antarctica), and changes in the sun. For 1993 to 2003 these are summed to give the total which is equivalent to about 0.7 W m-2.  For 2004-2008, TOA measurements are used to provide an increment to the total based on comparisons with 2000-2003, and the quiet sun has contributed, but the sum is achieved only if a spurious residual is included. Units are 1020 Joules/year.

Further inroads into this problem will no doubt become possible as datasets are brought up to date and refined.  In the meantime, we have explored the extent to which this kind of behavior occurs in the latest version of the NCAR climate model.  In work yet to be published (it is submitted), we have found that energy can easily be “buried” in the deep ocean for over a decade.  Further preliminary exploration of where the heat is going suggests that it is associated with the negative phase of the Pacific Decadal Oscillation and/or La Niña events. 

Clearly, tracking energy and how and where it is stored, and then manifested as high SSTs which in turn affect subsequent climate is an important thing to do.

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Comments 251 to 260 out of 260:

  1. MA Rodger  mea culpa, calculation was and is nearer 450 -  it seemed reasonable at the time so I didn't check.  Your reference to thermal conductivity was covered way back somewhere. It is multiplied at least tenfold by convection and forced convection. Every engine I know, whether it is air cooled or water cooled uses the same heat dissipation by physical movement of energy; to deny it occurs in the atmosphere is simply perverse when we see it in our daily lives and displayed on our TV screens all the time.

    I have no problem whatsoever with the absorption bands of any of the GG's which are bang up there in the i/r spectrum. Nor the extra absorption for that matter of carbon particulates which absorb all light. They add to atmospheric warming. I merely question the route out for all this energy. The same one in - absorption - is not available going out. e.g carbon black will not radiate visible light neither will CO2 gas radiate i/r from molecular agitation. You could argue that heat transported to earthly sinks warms them and increases the outgoing radiation by quasi BB methods (sufficiently, without man's intervention).  I merely propose that there is an unexplored radiation belt where a supplementary exit is provided and there are good reasons for believing it to be of account.

    Now I suggest we leave it at that, I can't be doing with unconstructive invective.

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  2. Old Sage "it seemed reasonable at the time so I didn't check."

    And therein lies the problem. Throwing around idea, or numbers, without checking and comparing with what's in the litterature, while displaying ignorance of fundamental principles of the subject a hand; suggesting that all the scientists studying the subject have it wrong and you have it right, all the while making basic mistakes that have to be pointed to your attention by others. Then resorting to possible mechanisms that have never been observed but just have to exist because it would be so satisfying to you personally that they do. And complaining about being invectived when your mistakes and lack of rigor are dissected in no uncertain terms and thrown back at you for what they are. Really, how can you expect to be taken seriously?

    So far, the one with the least constructive attitude on this thread lately has been you. Complaining about other's unconstructive invective is nothing but a way to escape coming to grips with your severe lack of understanding of the subject that you claim others have figured all wrong. I'm unimpressed. Perhaps you should leave it that indeed.

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  3. old sage @251.

    No. It would be remiss of us to leave it there. You say the effects of conduction "is multiplied at least tenfold by convection and forced convection." But it is also true that ten times nothing is still nothing.

    So what is the conductive element of Earth's cooling. Consider the simplistic model I constructed @249. Acording to Wikipedia, the thermal conductvity of air is 0.025 W/m/ºK. If the planet surface is say 300ºK and the insulation layer is just a tiny tiny 1,000m thick at that conductivity, the cooling from conduction will be 0.0075 W/m^2, an insignificant figure, even if multiplied 10 times, or 100 times.

    Just to emphasis the point, this model would suggest that if conduction entirely cooled the planet, the surface temperature would be 13,000,000ºK, and that is with just 1km depth of insulator.

    This is why Figure 1 in the post above shows, not "hardly a joule from conduction" as you described it in a previous thread, but it shows zero contribution from conduction!

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  4. MA Rodger - yes, an error but not germaine to my proposition. Also I have not said the transfer agent is conduction;  convection - forced and natural - is vastly more important and bulk transfer via weather systems - driven by such energy -we can witness on our TV's.

    I have no problem with the broad range of i/r absorption  by CO2, H2O etc, nor carbon particulates which can absorb visible light. But CO2 gas has no more capacity to emit i/r at atmospheric temperatures than have carbon particulates to emit visible light. In other words, the route in cannot be the same as that out.

    That means heat transported around the globe can only get out via surface radiation from the cool spots where wind water deposit it. I merely posit the existence of an additional route in which the energy is dissipated in a directly emitting electrically active shell which is known to exist as a belt of intensive radiation in the upper atmosphere. I am totally unconviced that ground radiation can do it on its own.

     

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  5. Old Sage,

    I have not claimed that IR is the only emissions from Earth.  You have pointed out that the thermosphere also emits hgher energy radiation and that is certainly true.  It has nothing to do with the greenhouse effect though so why discuss it here?  Are you suggesting that convection from the stratosphere (-60C) transfers energy to the thermosphere (2000C)?  Please explain this apparent violation of the second law of thermodynamics.  Your continued harping on this line simply demonstrates that you have no understanding of energy transfer in the atmosphere.

    CO2 emits IR due to the black body effect.  This is well known, basic physics.  It can easily be measured with an IR thermometer at home.  Your claim that there might exist a band of energy emissions emitting all the energy abosrbed from the sun into space that has not been discovered yet is simply absurd.  This is a scientific site.  People are expected to support their claims with references to the peer reviewed literature or with well supported calculations. Speculations on undiscovered paths of enormous amounts of energy make you look stupid. 

    Ask questions about what you do not understand and people will help you out.  Assertions of large, undiscovered energy flows will be greeted with derision.

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  6. I see that (-snip-)* continues his (-snip-).

    Let's ignore the fact that his central thesis, ie, that CO2 and other components of the atmosphere do not radiate at normal atmospheric temperatures and pressures has been demonstrated to be false by evidence which he has simply ignored.  Let us further ignore the fact that much of the US space program is based on gleaning signals from thermal radiation from the gases that compose the atmosphere, including of course the AMSU units which are used to detect the temperatures at various layers by detecting thermal radiation in the form of microwaves from oxygen or water vapour, further falsifying his claims.  Let us rather look at his theory that convection carries heat from the Earth's surface to the ionosphere.

    This structure of the vertical structure of the atmosphere:

     

    The important point is that the change in temperature with altitude (the lapse rate) in the troposphere is largely determined by convection.  Crucially, convection will not occur if the atmosphere above a parcel of air is warmer than that below it.  Therefore, convection does not occur in the stratosphere.  In fact, it is because of the lack of convection that the stratosphere consists of distince strata of air at different temperatures, and which gives the stratosphere its name.  The important point, however, is that convection simply cannot carry energy any higher in the atmosphere than the tropopause, one tenth of the altitude to which  (-snip-)'s theory requires it to be carried.

    (As a side note, the altitude of the tropopause can be, and has been calculated from first principles on the assumption that at least some atmospheric gases radiate thermal energy. (See Held 1981)  The principle by which this is done can be easilly summarized.  In essence, energy transfer by radiation and energy transfer by convection each generate their own characteristic lapse rates.  The lapse rate generated by convection is essentially constant with altitude.  In contrast, that generated by radiation depends on the average distance travelled by photons before being reabsorbed.  Consequently it becomes smaller (less temperature fall per km of altitude) with greater altitude.  When the radiation induced lapse rate becomes smaller than the convection induced lapse rate, convection ceases to be the most efficient means of transporting energy, and ceases.  Thus the existence of the tropopause proves the existence of thermal radiation emitted by atmospheric gases.)

    Even more troubling for  (-snip-) is the existence of convection at all.  Once the temperature profile associated with convection is established, further convection ceases.  It is only if the air above is further cooled that warm air will continue to rise.  The problem for  (-snip-) in this is that he has no basis for that cooling.  Certainly it is not by convection at the tropopause, which cannot happen.  Therefore it must be by radiation of thermal energy by atmospheric gases.  (-snip-), however, denies that that exists.  This places him in the position of claiming that a heat engine (the general circulation of the atmosphere) exists without a heat sink, a thermodynamic impossibility.

    The point of all this is that science is interconnected.  When you start denying one part of it, you are led inevitably to increasingly inconsistent positions in which you must deny more and more fundamental aspects of science.  Pseudo-science is a fools errand, which has not (of course) stopped (-snip-).

    * I have, of course, no objection to the person who calls himself "Old Sage" being old.  After all, so am I.  I have very serious objection to people giving themselves laudatory titles as internet names.  It is not for any many to call themselves a Sage - that being properly the judgement of others.  That the person calling himself "Old Sage" feels it necessary to call himself a sage shows, first, that he is arrogant, second, that he is foolish, and third, that it is unlikely that people would call him a sage (or sagacious) if he did not adopt it as title.  Given that, I will not call him sage, but will adapt his name to be, at least, honest.

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    Moderator Response:

    [DB] Inflammatory snipped.

  7. old sage @254.

    So we can agree, it would be silly not to, that conduction does zip to cool planet.

    I am not sure what you mean by "convection - forced and natural." I am only aware of the natural sort acting in the atmosphere. Could you explain what you mean by the term?

    And "bulk transfer"? I assume you mean 'insensible heat', the latent heat transferred by water vapour from the surface and left up in the atmosphere when it rains out. We know the average global annual rainfall is not far from 1,000mm. So we know the average insensible heat transfer will be something like 2.26 Gj/m^2 pa = 72 W/m^2, not at alldissimilar to the 80 W/m^2 proposed by Figure 1 in the post above. It is thus significant but not "vastly important" even if it does feature so prominantly on our TVs.

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  8. Tom@265

    "The point of all this is that science is interconnected. When you start denying one part of it, you are led inevitably to increasingly inconsistent positions in which you must deny more and more fundamental aspects of science. Pseudo-science is a fools errand, which has not (of course) stopped Old Fool."

    And this is precisely where the pseudoskeptics fail, every, single, time.

    To a rational mind, and a skeptic at that, it is simply mystifying that this simple and basic step of considering the whole, is time after time missed by those who so eagerly appoint themselves as skeptics as they attempt to surplant a part the known science with their own version of reality.

    Take for example the claim that 'warming has stopped'. This requires that both the claim of melting glaciers as well as warming seas are essentially false. And similary the sea rise must also be false, since both the warming and glacial melting are key components to it. A simple denial cascades into fullblown denial of reality as measured.

    The pseudoskeptics should in earnest develop an understanding what it really means when science says that there are 'Multiple sets of independent observations' of both warming, as well as the attribution, as it has been repeatedly also shown in this discussion thread.

    FWIW in each instance above, I only linked to single relevant page. To those readers who still are not impressed by the information of the specific topic: please take a moment, search through the site for related information, then come back. You might otherwise run the risk of argumenting out of ignorance. After all, a skeptic would take the time to actually understand what is proposed before possibly rejecting it.

    And returning to the topic, I also would be very interested in Old Sages alternative explanations to all the disrepancies brought up by various parties as arguments against his claims about the physical properties of CO2. I by no mean claim any expert knowledge of the matter, so it would be very educating to hear what all that 'Physics text books' actually says in relation (and to what extent) to the atmosphere and its components, as (s)he insofar has only brought them up in a non sequitur manner. In the appropriate topic, naturally.

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  9. Phillippe, a 252, a dit tout qu'il faut dire.

    Tom: I expect the "Sage" is a spice, not an IQ. A condiment accompanying large quantities of turkey, which is what his posts are looking like.

    Old Sage: I have spent years measuring the IR radiation you say "looked right" at 45 W/m2, and it was obviously wrong to me. I have also spent many years measuring the convective/turbulent energy fluxes you talk about, and you are obviously wrong about those, too. You appear to be the only one your vast misunderstandings aren't obvious to.

    I think Old Sage has gone deep into troll territory. I suggest DNFTT.

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  10. I'd just like to wrap up this exchange by saying there is evidence of energy exchange between the outer plasma and earth and it would be a very brave man who would deny its possibility. So more to be done, look up Van Allen for those interested.

    If the earth only had O2 and N2, there would still be a 'greenhouse' effect, their failure to absorb and emit means their take up by conduction and convection could only be lost through transport to a cooler place thus minimising the extremes of an empty atmosphere. I am surprised that you cannot look up tables of concentration v penetration depth for at least a few of the characteristic absorbing frequencies to give some idea of when absorption is 100 %. We might well be there and only soot particles be now contributing to the absorption of additional frequencies.

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  11. Sorry Bob@259, this piece is irresistable :-/

    Old Sage@260

    "I'd just like to wrap up this exchange by saying there is evidence of energy exchange between the outer plasma and earth and it would be a very brave man who would deny its possibility."

    Bluntly put, so what?

    Your claim is at most a red herring or straw man, since nobody has denied the existence of the said phenomen.

    What you have totally failed in is showing any evidence that the said phenomen is:

    1. Quantitatively relevant
    2. Any way fitting with the rest of the observed changes (see Tom's excellent point which I quoted in my previous writing)

    Simply put, you jump over the necessary step of actually validating your thoughts by checking whether there are any actual evidence that supports your belief. Another good example of this kind of shortcoming can be seen in the cosmic ray explanation.

    "If the earth only had O2 and N2, there would still be a 'greenhouse' effect"

    This is funny. And just as you redefine the 'greenhouse' effect to mean something else, I redefine funny meaning 'not even wrong'.

    "their failure to absorb and emit means their take up by conduction and convection could only be lost through transport"

    Alas, your failure, again, is to validate your thoughts against reality.

    Your setup is a planet with a pure N2+O2 atmosphere. This means that the atmosphere is transparent both in visible as well as IR spectrum. Since we know that the vast majority of the incoming energy comes in in these forms, the visible will either be absorbed by the ground/sea, or b) reflected (visible light), according to the albedo coefficient.

    What about the absorbed energy, now transformed to heat? How does it get re-emitted from ground/sea? Some of it undoubtedly can be transferred by conduction, but a notable amount is also transmitted by IR. If you don't accept this, then you need to explain how exactly the IR cameras works.

    Now since your atmosphere does not contain any element that can absorb IR radiation, it will dissipate to outer space. Compare this situation to our real atmosphere where the atmosphere contains GHGs which absorb and re-emit IR, and you should understand that logically this difference makes your example a cooler world when all other items are kept the same. In reality we do have both negative and positive feedbacks which alter the outcome, but these do not change the basic physical properties of N2, O2 nor CO2.

    Hence it is evident that you either have a very poor understanding of the reality, or you choose to dismiss a notable amount of inconvenient information even from our daily life.

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  12. "Alas, your failure, again, is to validate your thoughts against reality"

    Old Sage much prefers misconception to reality and by refusing to look at any evidence to the contrary is effectively got fingers in ears yelling "la, la, la". More what I would expect from a 8 year old.

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  13. I think Old sage has been trying to explain the importance of the Earths Dynamo Effect and it's production of electomagnetic field lines.

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    Moderator Response:

    [DB] Off-topic snipped.

  14. jmorpuss @263, no he is not.  Just because he mentions the ionosphere does not mean he was pursuing your particular brand of pseudo-science.  Further, the Earth's dynamo effect has nothing to do with the greenhouse effect, and nor is it maintained by the energy of the sun.

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  15. A previous thread was opened up to this discussion with jmorpuss by Moderator Decree although moderators were kept busy. The final act was a proposed jump to a more appropriate thread where a rebuttal remains unaddressed by any counter-argument 18 months on.

    Simply put, the tiny tiny fraction of the total energy-use of mankind that is present in radio waves sent into the atmosphere is incapable of impacting climate to any significant amount. Mankind's enhancement of the greenhouse effect is fifty-times greater than mankinds total energy-use. How then can a tiny tiny fraction of that already small fraction have a significant impact on climate?

    If jmorpuss wishes to answer that question, perhaps he should do so on the thread with the unaddressed rebuttal.

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    Moderator Response:

    [TD] Thank you for the detective work!  I had entirely forgotten that history, so I was baffled by jmorpuss's comments.  Further comments by jmorpuss or anybody on that topic must be on the thread MA Rodger pointed to.  Comments here, by anybody not just jmorpuss, will be deleted.

  16. I've stood back a bit to let my critics reflect on what I have said - and recant where appropriate!

    First, (-snip-).

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    Moderator Response:

    [DB] "I do not believe the waste heat theory has been refuted"

    Then take that portion of the discussion here:

    It's Waste Heat

    Be sure to read the ENTIRE discussion thread first.

    "Surely with so much invested in the subject, these should be standard engineer's tables"

    Please cease with arguments from personal incredulity.

    The remainder of your comment was snipped due to its inapprpriateness for this thread.  Feel free to repost those pertinent bits on the It's Waste Heat above.

  17. (-snip-) (see above) asks:

    "How, in the assertions that CO2 radiates spontaneously at NTP, did the measurements eliminate the background radiation from the container? And, where can I look up tables of penetration depth of i/r in CO2 against temperature and pressure? Surely with so much invested in the subject, these should be standard engineer's tables."

    Hitran is the equivalent of the engineering toolbox for CO2 emission and absorption in the IR spectrum.  The 15 micron emission spectrum of CO2 was measured by Gordon and McCubbin (1965).  The instrument used is described in McCubbin, Lowenthal and Gordon (1965).

    That  (-snip-) does not know of the science gives no information at all as to whether or not the science exists.

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    Moderator Response:

    [DB] Inflammatory snipped.

  18. Can anyone briefly explain to me how Trenberth's graph goes back to the late 19th century, if he's using satellite measurements from the TOA that have only been taken in recent decades:

    Net Radiation at the TOA

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  19. dvaytw @268.

    You present Figure 1c from Hansen et al (2005) "Earth’s Energy Imbalance: Confirmation and Implications". (Trenberth did not co-author.) The caption for Figure 1 in that paper runs as follows:-

    Fig. 1. (A) Forcings used to drive global climate simulations. (B) Simulated and observed temperature change. Before 1900, the observed curve is based on observations at meteorological stations and the model is sampled at the same points, whereas after 1900 the observations include sea surface temperatures for the ocean area, and the model is the true global mean. (C) Net radiation at the top of the atmosphere in the climate simulations. Five climate simulations are carried out that differ only in initial conditions.

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  20. MA Rodger, thanks.  But it seems there's some mis-labeling (or else mis-reading on my part) in "The Human Fingerprint in Global Warming", then, as that graph is labeled:

    "Figure 9: TOA Radiation (Trenberth 2009)"

    I also wonder if there is a nice graph for the satellite data from the top of the atmosphere.  This point (satellite confirmation of heat accumulation) has always seemed like a clincher to me because it clearly belies the "pause" talking-point in a way that all the nuanced responses about oceans and aerosols and volcanic eruptions and inadequate temperature arrays doesn't.  For that reason, a nice visual would be nice in underscoring it, but I can't find anything but charts incomprehensible to the climate-challenged such as myself in Trenberth 2009.

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  21. I am confused by figure 1 in which there is a net absorption of 0.9W/m2 by the Earth, but the top of the atmosphere is in energy balance.  This implies that global surface warming is extracting this energy from the atmosphere which seems odd if not impossible over the long term.

    Could it be rounding error? and if so, this seems unfortunately misleading (at least to me)

    Cheers

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  22. Tobirh @271 , 

    my impression is that the 0.9W/m2 is only an approximation.  You will note that the Fig. 1 description mentions that they are talking of the energy balance for the period 2000 - 2005 (so about 15 years before today).

    Today's imbalance is approximately twice that 0.9 amount.

    But the TOA [Top Of Atmosphere] energy flux, in and out, will only be in balance when the Earth has reached thermal equilibrium.   We are not at that point yet ~ even if CO2 (and other Greenhouse gasses) ceased rising immediately, we would still require a few decades for the planet to reach the new [higher] equilibrium point.

    There is no extraction of energy from the atmosphere ~ that question you asked is based on an entirely erroneous concept of the current global warming's mechanism.   If you will, picture the analogy of (say) 4 liters of water inside a sealed steel container ~ but within the water is an electrical immersion heater delivering a steady 20 watts of heat.  Over time, the water will rise to an equilibrium temperature, where the 20 watts in is balancing 20 watts out (the outward flux being by convection & radiation from the steel's outer surface.)  Then coat the steel container with a 1-inch layer of foam rubber.  Then - gradually - you find the water temperature rising to a new higher equilibrium temperature, where the same 20 watts is going in and the same 20 watts is leaving (by convection & radiation from the foam rubber's surface).   The foam rubber "slows down" the energy flux going outwards . . . and you can see how the watery interior needs to be hotter, to get the outermost surface up to the necessary 20 watt total.

    It is only a rough analogy, but it sort of represents a bare planet (without any greenhouse gasses) versus the actual presence of foam-rubber/greenhouse-gasses-in-the-atmosphere type of planet (which we really do have).

    If you wish, add a second 1-inch foam rubber coat on the outside of the first coat.  You can see how the interior water must get even hotter, in order to balance the energy inflow of the same old 20 watts.  [The 20 watts being the analogy to the same old solar radiation input that we've had for the past 50+ years.]

    As you see, the "atmosphere coat" does not generate any energy.  But it can produce a higher or lower temperature for the interior (i.e. the surface of the planet) according to the circumstances of the atmosphere.

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  23. Tobirh,

    If you look carefully at figure 1 the numbers are rounded.  Incoming 341.3 is rounded to 341.  Outgoing 101.9 is rounded to 102 and 238.5 is roumded to 239.  If you add up the unrounded numbers they leave 0.9 w/m2 absorbed.

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  24. There did not seem to be an obvious place to post these queries, so please redirect me if appropriate - links to references would be great thanks... Out of general curiosity..

    1) To what extent is earth cooling (heat emission from the surface - volcanoes, earthquakes, geysers, steam etc) contributing to surface warming?

    2) People generate heat from activity. I also read that energy use per person increases as countries become more developed. If we did not increase net CO2 (through burning etc) and used other energy sources (e.g. nuclear) how much heat per person at the surface would we still be contributing to surface warming? Put in another way, how much ∆AGW is directly atributable just to ∆population numbers?

    3) A general query re the atmopsphere - if we add gasses (like CO2) the atmosphere becomes heavier. At a given temperature does the atmosphere [by PV = nT] expand, or does sea level pressure increase (or both)? In a similar vein, if T increases, does the atmosphere expand or sea level pressure increase (or both)? Also what is the effect (if any) on atmospheric pressure and volume of adding particulate matter (e.g.smoke or dust)?

    4) Why are some gasses apparently well distributed within the atmosphere (like CO2) and some (like Ozone) form layers? Are some gasses proportionatey more prevalent in the Troposphere than the stratosphere? 

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    Moderator Response:

    [PS] See Underground temperatures control climate and Its waste heat and put any further questions on 1/ or 2/ there. Ditto for any responders. Please use the Search function (top left) or the "Arguments" menu topic to find appropriate threads.

    Since CO2 increase is from FF burning, O2 is also decreasing. n in PV = nRT isnt changing much. Even if not an increase of 100ppm in CO2 would be global change of hundredth % in pressure which I doubt could be measured.

    For ozone, try here. Short answer is that ozone layer where ozone is naturally produced but it is naturally destroyed rapidly as well.

  25. Thanks!

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