Sunday, 7 February 2021

Re: those experiments which purport to prove the Greenhouse Effect

Here's a typical example:

Can anybody see the 'glaring' error?

Agreed facts: the atmosphere is largely transparent to shortwave sunlight (wavelength less than 4 microns); the surface is warmed by shortwave sunlight; the surface emits longwave radiation (anything more than 4 microns).

Questionable claims: greenhouse gases reflect or reradiate 83% of this longwave back down to the surface; the surface receives twice as much 'back radiation' as it does actual sunlight (source). This is why the surface is 33 degrees higher than the 'effective temperature'. CO2 accounts for about one-fifth of this 'back radiation'*.

Does this experiment demonstrate back radiation or 'trapping'?

Nope.

What we see in this experiment is the two hot lamps warming up the two bottles and the gas in them. That's the 'glaring' error. The lamps are emitting lots of radiation at at wavelengths 14 - 16 microns, which CO2 absorbs (but N2 and O2 can't), warming up the CO2 (see bullet point 1 here). There is nothing magical about this; leave a piece of aluminium and a piece of wood in bright sunlight, the aluminium will reach a higher temperature.

A much fairer experiment would be to have three large greenhouse frames (the larger the better) covered in very thin, clear polythene (which allows most radiation through in both directions) in a shaded area, so that the only radiation they receive is longwave from the ground and from the surrounding atmosphere (which is much less intense than the light emitted by a hot lamp). UPDATE, it would be good idea to pipe water under the floor to keep it at the same temperature as nearby areas which receive sunlight /UPDATE. After all, the claim is that CO2 traps or absorbs longwave radiation emitted by the ground and the surrounding atmosphere. You have one full of normal air; one full of CO2; and one full of argon (monatomic and definitely not a greenhouse gas, as defined) as a control experiment.

CO2 and argon have a similar mass per unit volume and both have much lower specific heat capacity than normal air (see bullet point 5 of previous link); they also both have similar thermal conductivity, much lower than normal air (i.e. they are better insulators). Put your aluminium and wood in a freezer and the aluminium will cool down faster as it is a better conductor/worse insulator.

I'd be surprised if the greenhouse full of CO2 reached a steady state temperature (after a few days, averaged over a 24-hour period) higher than that of the greenhouse with normal air. That would be like putting our aluminium and wood in a larder and noticing a few days later that they are different temperatures. And even if it did, we have the argon-filled greenhouse as a control. The chances are, it would be a similar temperature to the one with CO2 i.e. most of the differences can be explained by their lower specific heat capacity (they warm up and cool down faster) and their lower thermal conductivity and higher mass per unit volume (they cool down more slowly).

To the extent that the 100% CO2 greenhouse is slightly warmer than the one with normal air, you adjust for its other properties by comparing it with the temperature in the 100% argon greenhouse (see previous paragraph) to arrive at a much smaller (and possibly negative) figure which will be the result of radiation 'trapping'. If it's negative, then stop right there.

If it's positive, let's be generous to the Alarmists and assume a logarithmic relationship between CO2 levels and temperature. You divide that extra temperature difference by 11.3 (going from 415 ppm to one million ppm is to double concentrations just over 11 times) to estimate the likely increase in temperature if CO2 levels were double their 'pre-industrial' level, i.e. 0.06% instead of 0.03%, and then  deduct the 1 degree that has already happened (we have already gone from 0.03% to 0.04%). Then - assuming we still have a positive number - count the zeroes after the decimal place! (If you assume a linear relationship - which is what the Alarmists' charts actually show - you'd divide the change by 2,500 and then subtract 1 degree). For completeness, normal air is 1% argon by volume, i.e. there's 2,500 times as much argon as there is CO2.
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Finally, I suppose you should repeat the experiment by setting up the greenhouses in the open, so that they also receive incoming sunlight during the day; that makes the downward adjustments more complicated because there will be a real greenhouse effect (no convection) but probably worth doing.
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* The precise fraction is never made clear, but clearly it's enough to make a difference if the explanation is correct.

While it is quite true that the atmosphere is radiating back at the surface and you can measure it, the atmosphere is cooler than the surface (because of the gravity induced lapse rate. If CO2 really 'trapped' warmth, the lapse rate would be higher than expected from first principles. Venus' atmosphere is 95% CO2 and the lapse rate is exactly what you'd expect from first principles) and the net transfer of heat (whether by radiation or conduction) will always be from warm to cool, but that's an aside, and even this basic truth is 'hotly' disputed by Alarmists, so let's concede on that to keep the peace. You can't just add radiation from different sources either, but hey.

2 comments:

Dinero said...

The video is not a good demonstration of the greenhouse effect. What it actually demonstrates the specific heat capacity of Co2.
A better demonstration of the greenhouse effect would be to show the different temperatures of heat sources placed inside the different bottles.
If the heat source is outside of the bottle , and the temperature of the gas is measured then what is actually demonstrated is the specific heat capacity of C02

The Three greenhouse experiment has the same problem because there is LW radiation coming from outside of the greenhouse, and that factor makes it more like a demonstration of the specific heat capacity of CO2

A Better set up for the three Greenhouse experiment would be to measure the temperature of a heat source placed inside the Greenhouse. And to make the heat source hot enough to reduce the significance of the LW radiation coming from outside of the greenhouse.
Better still would be to insulate them from outside LW radiation and warm the ground with sunlight but that would be impracticable probably.

Mark Wadsworth said...

Din: "A Better set up for the three Greenhouse experiment would be to measure the temperature of a heat source placed inside the Greenhouse. And to make the heat source hot enough to reduce the significance of the LW radiation coming from outside of the greenhouse."

That's still flawed; that would still depend on specific heat capacity etc, and the LW would be at different wavelengths to those occurring naturally.

"Better still would be to insulate them from outside LW radiation and warm the ground with sunlight but that would be impracticable probably."

Not really. All air receives LW from the surrounding air and gives off LW to the surrounding air, that is realistic, no need to insulate.

In my experiment, the surface might cool off slightly, that is true, but we are not measuring *absolute temperature* we are looking at whether the CO2 greenhouse is warmer (and if so, adjusting for the different specific heat capacity etc).

If you want, you could have water pipes running just under the surface which keep the floor at the same temperature as nearby areas which get sunlight? That way, the only thing warming the gas in the greenhouse is realistic level LW radiation, which is what we are trying to isolate.

I think that's best.

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