Climate change and Earth reflectivity

In summary: the study does not seem to support the idea that there has been a large decrease in reflectivity in the last two decades.
  • #1
Andre
4,311
74
Although we see threads starting supporting Green House Gas global warming, we tend to overlook the publications that counter them.

Here is one from May (almost overlooked):

Science, Vol 304, Issue 5675, 1299-1301 , 28 May 2004 Changes in Earth's Reflectance over the Past Two Decades

E. Pallé et al

Abstract
We correlate an overlapping period of Earth'shine measurements of Earth's reflectance (from 1999 through mid-2001) with satellite observations of global cloud properties to construct from the latter a proxy measure of Earth's global shortwave reflectance. This proxy shows a steady decrease in Earth's reflectance from 1984 to 2000, with a strong climatologically significant drop after 1995. From 2001 to 2003, only Earth'shine data are available, and they indicate a complete reversal of the decline. Understanding how the causes of these decadal changes are apportioned between natural variability, direct forcing, and feedbacks is fundamental to confidently assessing and predicting climate change

and some remarks in the conclusion:

If the changes in cloud properties responsible for the reflectance changes shown by the proxy were a result of secularly increasing atmospheric greenhouse gases, then they would signal a strong positive SW cloud feedback,
(…)
the reflectance increase from 1999 to 2003 would be difficult to attribute to monotonically increasing atmospheric greenhouse gases. Natural variability is a much more plausible explanation, given the size and time scale of the proxy changes.
(…)
These large variations in reflectance imply climatologically significant cloud-driven changes in Earth’s radiation budget, which is consistent with the large tropospheric warming that has occurred over the most recent decades. Moreover, if the observed reversal in Earth’s reflectance trend is sustained during the next few years, it might also play a very important role in future climate change.

Translation: there is a high correlation between global temperatures and Earth's reflectivity (Albedo) whilst there is no correlation between carbon dioxide increase and this reflectivity. The less light is reflected, the higher the (global) temperatures.

Now, is this the kind of pseudo-bad-scientific publications -conspiracy tales nonsense that the alarmists warn against?

like this?

Scientists Sick and Tired of Propaganda Games with ' the Only Planet We Have'
30-Jun-04
global warming
Dr. David Suzuki writes, "Lately, it seems the public has been burdened with yet another round of anti-global-warming conspiracy tales. I'm not the only one who's sick of this nonsense.
 
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  • #2
Dug out this old one, since it gives us a rather good idea about the reflectivity (Albedo) of the Earth in the last couple of decades. With that in view, let's go to the lastest scary scenario of the BBC that upset the UK to a great extend last week.

I wonder why the story did not made to these threads, but anyway.

The Earth is dimming.

We are all seeing rather less of the Sun, according to scientists who have been looking at five decades of sunlight measurements.

They have reached the disturbing conclusion that the amount of solar energy reaching the Earth's surface has been gradually falling.

Now why would that be? Let's follow the scientific method and formulate a possible hypothesis:

...Dimming appears to be caused by air pollution.

Burning coal, oil and wood, whether in cars, power stations or cooking fires, produces not only invisible carbon dioxide - the principal greenhouse gas responsible for global warming - but also tiny airborne particles of soot, ash, sulphur compounds and other pollutants.

This visible air pollution reflects sunlight back into space, preventing it reaching the surface. But the pollution also changes the optical properties of clouds.

Because the particles seed the formation of water droplets, polluted clouds contain a larger number of droplets than unpolluted clouds.

Recent research shows that this makes them more reflective than they would otherwise be, again reflecting the Sun's rays back into space.

Having formulated the hypothesis, next step is to test it against independent evidence. So if pollution is making the Earth moere reflective, we should be able to find evidence of that. So:

This proxy shows a steady decrease in Earth's reflectance from 1984 to 2000, with a strong climatologically significant drop after 1995.

:bugeye: Oops, I'm afraid that hypothesis did not last very long. It would be an understatement that hypotheses that oppose reality 180 degrees, are not really commended for their reliability.

So in what perspective need we to see?

Dr. David Suzuki writes, "Lately, it seems the public has been burdened with yet another round of anti-global-warming conspiracy tales. I'm not the only one who's sick of this nonsense.
 
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  • #3
This proxy shows a steady decrease in Earth's reflectance from 1984 to 2000, with a strong climatologically significant drop after 1995.

Do you have a link to the article/paper in which you found this? I was having a discussion about this with someone the other day, and I think it could be helpful.
 
  • #4
OK: Science, Vol 304, Issue 5675, 1299-1301 , 28 May 2004 Changes in Earth's Reflectance over the Past Two Decades, Pallé et al

The abstract is here, but you need a (free) subscribtion.

http://www.sciencemag.org/cgi/content/abstract/304/5675/1299
 
  • #5
Interesting, thank you for the post.
 
  • #6
The first thing I notice about the Palle et al. graph is that it registers no effects from the Pinatubo eruption. Curious. The ISCCP graph shows a large fluctuation in albedo from the Pinatubo eruption as would be expected.

Second is the huge peak in 2003, which I understand the authors have backed up somewhat from that and have admited that it may be caused by undersampling of the data, even though that year was one of the highlights the Palle et al., 2004 article.

George Tselioudis, a NASA scientist at the Goddard Institute for Space Studies, states: "The ISCCP group produces an indpendent estimate of the albedo, from performing a full radiative flux calculation that takes into account observations of all radiative forcings and produces top of the atmosphere, surface, and in-atmosphere fluxes. This has been shown to be in excellent quantitative agreement with satellite measurements at the top-of-atmosphere and with surface measurements. The year-to-year variations of these values show some qualitative agreement with the Earth'shine-trained ISCCP reconstruction but very large quantitative differences." (Palle et al. base their claim on Earthshine data, which is a measurement of the glow of the dark side of the moon that they use to deduce the Earth's reflectance and on proxy derived from ISCCP parameters after they are regressed with two years of overlapping, but not global,
Earth'shine observations.)

Tselioudis further points out that "satellites can see actual low clouds only when high clouds are not present. Second, the satellites retrieve the radiative, not the physical top of the clouds. As a result, a low cloud with a cirrus cloud overhead can be classified as a midlevel cloud in satellite observations. All these issues must be taken into account when calculating the radiative effect of clouds, as is done in the radiative calculations by the ISCCP group. More importantly, not all high-level and almost none of the middle-level clouds are radiative-warming agents. There is an optical depth threshold that depends on the cloud top height, above which the cloud becomes a cooling agent even with tops at high altitudes. Therefore the use of combined middle-plus-high clouds as a measure of the warming potential of the cloud field is a substantial overestimate of the effect. Moreover, a more careful look at the changes of ISCCP clouds by cloud type shows that the increase in total cloud cover from 2000 to 2004 is due to a small increases in high-level clouds and a larger increase in middle-level clouds that are mostly thermally neutral and therefore could not cause warming."

He explains further "The increases in both high-level and middle level clouds are caused by increases in the optically thicker cloud types, cirrostratus and cumulonimbus for the high-level and altostratus and nimbostratus for the mid-level clouds, that due to their large optical depths, cause radiative cooling. In fact, the same radiative calculations performed by the ISCCP group show that the outgoing longwave radiation increases during this time, opposite to the effect claimed. Therefore, the qualitative explanation given in the article is contrary to the quantitative analysis results derived from the ISCCP data.

The reconstruction of radiative fluxes from atmospheric properties is a very difficult and tedious job and both the ISCCP and ERBE/CERES groups are putting a great deal of effort into producing detailed and carefully evaluated radiative flux datasets. Both datasets show little or no albedo trend in the last four years. Thus explanations for how the albedo trends of the last four years are consistent with the surface warming and the ocean heat content increases are not necessarily required at this point in time."
 
  • #7
Hi, S, Thanks for the elaboration. Maybe you intended to post that in this thread?

https://www.physicsforums.com/showthread.php?t=108165

it would be good to know what the difference is exactly in the interpretation of the same data of Palle et al 2006. After all, you would expect a peer review of experts familiar with ISCCP data handling.

Both datasets show little or no albedo trend in the last four years.

I believe that also temperature graphs don't show a trend the last four years, temperatures remained roughly constant.

Thus explanations for how the albedo trends of the last four years are consistent with the surface warming and the ocean heat content increases are not necessarily required at this point in time.

Surely, considering trends in those short periods has little statical value indeed. However, the oceans apparently also reacted to the change in trend of the last four years:

http://www.ocregister.com/ocregister/opinion/columns/article_1245606.php [Broken]

The world's oceans cooled suddenly between 2003 and 2005, losing more than 20 percent of the global-warming heat they'd absorbed over the previous 50 years. That's a vast amount of heat, since the oceans hold 1,000 times as heat as the atmosphere. The ocean-cooling researchers say the heat was likely vented into space, since it hasn't been found stored anywhere on Earth.
 
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  • #8
Palle's Earthshine Paper, Why there are less clouds?

Attached is a link to Palle's Earthshine Data (Palle et al measured the planet's albedo by using telescopes and the brightness of the moon.)

http://solar.njit.edu/preprints/palle1266.pdf

The conclusion of Earthshine analysis is that from 1994/1994 to 2001 planetary cloud cover decreased by 5% +/-1.7%, which would result in an increase in planetary temperature. This finding is consistent with Palle's research that show satellite data support the same conclusion.

The areas where the cloud decrease was observed to decrease is consistent with the mechanism "electroscavenging" where an increase in the global electric current, removes ions from the atmosphere and hence reduces cloud cover. As the continents are slightly radioactive there which continual creates ions, the affect is strongest over the ocean.

Attached is a paper by Brian Tinsely the explains the mechanism. (See the picture of the global electric circuit.)

Expanded version of a paper by Tinsley and Yu, “Atmospheric Ionization and Clouds as Links between Solar Activity and Climate”

http://www.utdallas.edu/physics/pdf/Atmos_060302.pdf [Broken]
 
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  • #9
Solar Changes & Cloud Cover

The following is a hypothesized cause to explain why there was an observed reduction in low cloud planetary cover for the period 1993 to 2001. (See my above comment, that asserts that an increase in the global electric current, which removed cloud forming ions through the process of "electroscavenging", caused the observed reduction in cloud cover 1993 to 2001.)

Attached is a paper that shows there is close correlation between the solar wind speed and changes in the planetary temperature. The high speed solar wind is caused by cornal holes which have began to appear at the end of the solar cycle. Because of the high speed winds from coronal holes, there is no longer correlation with sun spot number and planetary temperature. See figure 6 in the attached paper that shows there is close correlation between observed global temperature anomalies and the solar index "ak".

From the attached paper:

"It has been noted that in the last century the correlation between sunspot number and geomagnetic activity has been steadily decreasing from - 0.76 in the period 1868-1890 to 0.35 in the period 1960-1982, ... According to Echer et al (2004), the probable cause seems to be related to the double peak structure of geomagnetic activity. The second peak, related to high speed solar wind from coronal holes (my comment: For example coronal hole 254 that produced the Dec 16, 2006 peak in solar wind, during a sun spot minimum, see attached link to Solar Observation Data), seems to have increased relative to the first one, related to sunspots (CMEs) but, as already mentioned, this type of solar activity is not accounted for by sunspot number. In figure 6 long term varations in global temperature are compared to the long-term variations in geomagnetic activity as expressed by the ak-index (Nevanlinna and Kataga 2003). The correlation between the two quantities is 0.85 with p< 0.01."

2005 paper by Georgieva, Bianchi, & Kirov “Once again about global warming and solar activity”

http://sait.oat.ts.astro.it/MSAIt760405/PDF/2005MmSAI..76..969G.pdf

http://www.dxlc.com/solar/ [Broken]
 
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  • #10
Highest Solar Activity in 8000 yrs & affect on Climate

In further support of the assertions that solar activity is responsible for a significant portion of the 20th century warming, attached is a link to the 2004 paper by Solanki, Usokin, Kromer, Shussler, Beer "Unusual activity of the Sun during recent decades compared to the previous 11,000 years"

http://cc.oulu.fi/~usoskin/personal/nature02995.pdf

The following is an excerpt from that paper:

"According to our reconstruction, the level of solar activity during the last 70 years is exceptional, and the previous period of equally high activity occurred more than 8000 years ago. We find during the past 11,400 years the Sun spent only of the order of 10% of the time at a similar high level of magnetic activity and almost all of the earlier high-activity periods were shorter than the present episode." In the paper they also note that based on historical records there is only a 8% probablility +3%/-4% the current high solar level will continue for the next 50 years.

Solanki et al, also state that the current high level of solar activity is not likely to account for planetary warming in the last 30 years, however, the data from Palle (see my above comments) from both satellite observation of clouds and the Earth'shine data, contradicts Solanki et al's statement. What is clear is that the sun has for the last 100 years been at very high activity levels. It appears based on information over the last year, the sun has began to move to a low activity state.

Attached is a paper, by Lockwood, Stamper, and Wild that notes the sun's large-scale magnetic field has doubled in the last 100 yrs. As noted in the attached paper the solar large scale magnetic field reaches out into interplanetary space and helps shield the Earth from Galactic Cosmic Rays (GCR). Palle's satellite data supports the assertion that GCR changes affect cloud formation, higher GCR more cloulds as clouds reflect the sun, less or more clouds would result in warmer or colder temperatures. A doubling of the sun's large scale field has resulted in less GCR which will reduce low level cloud cover.

As noted in my previous comment cloud cover is also reduced by the process of "electroscavenging" which removes ions from the atmosphere.

Doubling Sun’s Coronal Magnetic Field in Last 100 years
http://www.nature.com/nature/journal/v399/n6735/abs/399437a0.html
 
  • #11
End of Global Warming?

The papers referenced above provide data and analysis to support the assertions that there:

Has been very significant Solar Changes in the 20th Century.
1. That the solar activity in the 20th century is at its highest level in 8000 kyrs. (see papers for details.)
2. That the solar large scale magnetic field has more than doubled in the last 70 years. (An increase in the large scale solar magnetic field reduces the number of Galactic Cosmic Rays (GCR) that reaches the Earth's atmosphere. (See next comment as to how that affects cloud cover.)
3. That the solar coronal holes have started to move towards the solar equator at the end of the solar cycle, which increases the solar wind at a period in the solar cycle when it would normally have been reduced. (The high speed solar wind from the coronal holes, causes an increase in the global electric current, which through the Tinsley's named process of "electroscavenging" removes cloud forming ions.)
4. That there is direct correlation with planetary temperature and solar activity. (i.e. When the solar activity was reduced in 1950 to 1970, the planetary warming was abated and the planet cooled. See solar paper for details.)

That the Solar Changes Affects the Amount of Low Level Clouds
1. Svensmark and Palle have both used satellite data to show that there is an 99.5% correlation between Galactic Cosmic Rays (GCR) and low level clouds for the period 1983 to 1994. (Increase in GCR, causes an increase in clouds particularly over the oceans were there is a lack of ions to form cloud nucleus.) A decrease in low level clouds causes the planet to warm.
2. From 1993 to 2001 "electroscavenging" results in a reduction in clouds which Palle theoretically calculates:
"Our simulations suggest a surface average forcing at the top of the atmosphere in the albedo from 1994/1995 to 1999/2000, of 2.7 +/- 1.4 W/m2 (Palle et al 2003), while observations give 7.5 +/- 2/4 W/m2. The Intergovernmental Panel on Climate Change (IPCC, 1993) argues for a comparably sized 2.5 W/m2 which is attributable to greenhouse gas forcing since 1850.

The next set of questions to ask, do stars have cycles? Do stars move to an inactive stage after an active stage? (i.e. Solar cycle stops, solar large scale magnetic field decays, and solar iridescence is reduced.) How rapidly and how sever will the planet cool, based on the proxy climatic data or based on observations of sun like stars?
 

1. What is Earth reflectivity and how does it impact climate change?

Earth reflectivity, also known as albedo, refers to the amount of sunlight that is reflected by the Earth's surface and atmosphere. This is important for climate change because different surfaces have different reflectivity levels, which can impact the amount of heat absorbed by the Earth. For example, ice and snow have a high reflectivity and can help cool the Earth, while dark surfaces like forests and oceans have a low reflectivity and can contribute to warming.

2. How has Earth's reflectivity changed over time?

Over the past few decades, Earth's reflectivity has decreased due to human activities such as deforestation and the burning of fossil fuels. This has caused more heat to be absorbed by the Earth, contributing to the current climate change crisis. Additionally, as the Earth's ice caps and glaciers melt, they also contribute to a decrease in reflectivity and further warming of the planet.

3. Can Earth's reflectivity be changed to mitigate the effects of climate change?

Yes, Earth's reflectivity can be altered through various methods to help mitigate the effects of climate change. For example, planting more trees and using reflective materials for buildings and roads can increase reflectivity and help cool the Earth. Additionally, reducing greenhouse gas emissions can also help prevent further warming and changes in Earth's reflectivity.

4. How do scientists measure Earth's reflectivity?

Scientists use a variety of tools and techniques to measure Earth's reflectivity, including satellites, ground-based sensors, and aircraft. These instruments measure the amount of sunlight that is reflected by the Earth's surface and atmosphere at different wavelengths. By comparing these measurements over time, scientists can track changes in Earth's reflectivity.

5. What are the potential consequences of declining Earth reflectivity?

Declining Earth reflectivity can have several consequences, including further warming of the planet and changes in weather patterns. This can lead to more intense and frequent heatwaves, droughts, and hurricanes, as well as disruptions to ecosystems and agriculture. It can also contribute to sea level rise, as the melting of ice caps and glaciers reduces Earth's ability to reflect sunlight and further warms the planet.

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