Olson gives Spoerl Lecture on geoengineering, climate change solutions | The Lawrentian

[Andrew Lockley]

http://www.lawrentian.com/archives/1002557

Olson gives Spoerl Lecture on geoengineering, climate change solutions

POSTED ON FEBRUARY 7, 2014 BY DANNY DAVIS 

Last week, the environmental science department held a lecture by guest speaker Robert L. Olson from the Alternative Futures Institute. The lecture was part of the Spoerl Lectureship in Science and Society and discussed the problems of climate change and the implications of the solutions presented. The lecture was held on Thursday, Jan. 30 at 7 p.m. in Steitz Hall.The first half of the lecture discussed an emerging technology called climate geoengineering. Climate geoengineering is a category of technologies that could aggressively alter the course of global warming, technology that is both feasible and currently in development. These technologies serve as a ‘quick fix’ to climate change. Rather than try and take preventative measures, such as expanding green energy and reducing greenhouse gas emissions, climate geoengineering aims to directly reverse the effects of global warming.The associated technologies fall under two categories: Those that aim to reduce sunlight to prevent warming and those that remove carbon from the atmosphere to mitigate greenhouse effects. The technologies that Olson presented varied in potential effectiveness. The weakest, but also least potentially harmful technology was aggressive reforestation. By planting trees in massive numbers, the aim is to increase the amount of plants that scrub carbon from the atmosphere and convert it into oxygen.Another possible technology involves injecting iron into the oceans, which would cause large algae blooms which would absorb carbon. As the phytoplankton die, the carbon it absorbs would become part of the seafloor rather than reenter the atmosphere. However, this would come with the ramifications of algae blooms, which may cause harm to the atmosphere. Another strategy would be to plant lighter-colored crops and paint cities white to absorb less heat.The most powerful geoengineering technology that was speculated, however, was the use of stratospheric sulphate aerosols. Stratospheric sulphate aerosols are chemicals that would be sprayed into the atmosphere by aircraft. The concept of this technology would be to create a global dimming effect. In the lecture, Olson cited a large volcanic eruption that released so many sulfates into the air that it created a cooling effect. Even a one percent reduction in sunlight, as Olson discussed, could potentially mitigate the effects of global warming. However, the ramifications of injecting sulfates are unknown and could potentially be extremely dangerous. Olson argued that the best and safest way to mitigate the effects of global warming would be to cut greenhouse gas emissions and simply prepare for what he strongly alluded to be the inevitable effects of global warming. Olson cited alarming studies which showed the environmental impacts of small raises in average global temperatures. One study he cited suggested that if global temperatures rise enough, the amount of land area affected by severe drought could increase from fifteen percent to forty-four percent by the year 2100.Olson discussed issues with why preventative technologies have not been mobilized, despite the alarming evidence that was presented. Olson took a directly partisan stance and argued that the political right has catered to the interests of the energy industry and climate change deniers. As Olson argued, politics have been a major obstacle in enacting environmental policies. Part of what makes geoengineering so controversial is that the political right has recently shown support of geoengineering, even if the ramifications aren’t fully known yet, he said.Junior Conor Sexton, an environmental studies major, discussed the political situation around geoengineering. “In the current political arena, it’s a very viable option that’s going to become lucrative as time goes on. There are lot of unknowns, but that’s the path we’re headed down if we’re unwilling to take long term steps to prevent climate change,” he said.Though, politically, climate change has not gained much traction, Olson pointed out that even some conservative think-tanks are beginning to favor environmental policies that would not harm businesses. One such policy is carbon taxing, in which taxes from other areas in the economy are shifted onto a company’s carbon emissions to incentivize them to take environmentally friendly steps. Additionally, Olson said he was optimistic that something can be done about climate change. “It’s really important for us to have a dialogue between people who are concerned about climate change and people who are skeptical.”

[Stephen Salter]

Hi All

Olson writes:

"Rather than try and take preventative measures, such as expanding green
energy and reducing greenhouse gas emissions, climate geoengineering
aims to directly reverse the effects of global warming."

Why not 'as well as' rather than 'rather than'? I have been working on
green energy for nearly 40 years.

Stephen

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Emeritus Professor of Engineering Design School of Engineering
University of Edinburgh Mayfield Road Edinburgh EH9 3JL Scotland
S.Sa...@ed.ac.uk Tel +44 (0)131 650 5704 Cell 07795 203 195
WWW.see.ed.ac.uk/~shs

The University of Edinburgh is a charitable body, registered in
Scotland, with registration number SC005336.

[em...@lewis-brown.net]

Yes, frustrating. This 'either, or' mentality sits entirely Outside the geo-eng field from every experience i have had.
We can only contiune to consistently frame geo-eng as a group of possible 'as well as' technologies.
I wonder if the Sokolovs (sorry if spelling is wrong) wedge approach would adaptable to showing the possible contribution to reducing temperatures (directly or indirectly) through different geo-eng AND standard mitigation (emissions reductions) options, show how they can contribute alongside one another and how standard mitigation may not act fast enough now.
Best wishes,
Emily
Sent from my BlackBerry® smartphone on O2

[William Calvin]

A rather lame assessment. 

Solar radiation management will have a big problem: an uneven application will rearrange the winds and thus precipitation. Guess who they will blame for the droughts.

Doubling forests is the right amount of carbon but keeping it from returning to the air via fire and rot is impractical; we cannot even do it in rain forests.

WHC

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Emeritus Professor of Engineering Design School of Engineering University of Edinburgh Mayfield Road Edinburgh EH9 3JL Scotland S.Sa...@ed.ac.uk Tel +44 (0)131 650 5704 Cell 07795 203 195 WWW.see.ed.ac.uk/~shs

The University of Edinburgh is a charitable body, registered in
Scotland, with registration number SC005336.

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  William H. Calvin
    WCa...@UW.edu      WilliamCalvin.org

[William Calvin]

Oops, cut and paste left out the rest. Here again:

A rather lame assessment. 

Solar radiation management will have a big problem: an uneven application will rearrange the winds and thus precipitation. Guess who they will blame for the droughts.

Doubling forests is the right amount of carbon but keeping it from returning to the air via fire and rot is impractical; we cannot even do it in rain forests.

Iron blooms sink only 25% of the carbon into deep water and less than 1% into sediments. Better to get nutrients by pumping up and then pumping down the new green stuff --before it can decompose-- into deep waters that take a thousand years to begin resurfacing and then are spread out over 10k years.

-WHC

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[em...@lewis-brown.net]

Hi, thanks for the query on co2.
I refer to ocean acidification as only part of my concern about rises in co2 levels. The impact on temp seems established also, and i refer you to ipcc for further info on the links and concerns on this.
Regarding past changes in atmospheres and climates, yes these have ocurred and large and rapid ones are linked to mass extinctions. I dont wish that one our heavily populated world, especially where the most vulnerable and least to contribte pollution are hit soonest and hardest. Thus my concern for reducing co2 emissions, levels and avoiding rapid temperature rises is driven by concern for the welfare and suffering of people and animals. I think this is a widely shared driver behind climate campaigns and geo-eng developments?

Best wishes,
Emily

Sent from my BlackBerry® smartphone on O2

---

From: eugg...@comcast.net

Date: Sat, 8 Feb 2014 15:13:08 +0000 (UTC)

To: <em...@lewis-brown.net>

Subject: Re: [geo] Olson gives Spoerl Lecture on geoengineering, climate change solutions | The Lawrentian

Why is it so clear to you that there is a problem? For the past 400,000 years there has been one warm cycle every roughly 1000 years and CO2 levels were low. Some cycles produced global temperatures warmer than now; the last cycle 1000 years ago was quite warm; much warmer than now. Greenland was much greener. The cycles last several hundred years. If the current warming is related to the next cycle in the series then CO2 is not the issue but local control of temperature might have some value (certainly not by CO2 emission reduction.) All the work on eliminating fossil fuels might simply be for naught. Safer to work on local temperature reduction and if not that at least have an open mind.

 

This group is clearly wedded to CO2 emission as the source of the problem but in my opinion should have a more open mind,.i.e., focus on cooling techniques.

---

[Ronal W. Larson]

Dr.  Calvin:

1.  I’d like to follow up on your statement below:

Better to get nutrients by pumping up and then pumping down the new green stuff --before it can decompose-- into deep waters that take a thousand years to begin resurfacing and then are spread out over 10k years.

2.   Since you wrote on this list about push-pull pumping 13 months ago, Michael Hayes and others have been talking on this list about harvesting the produced ocean biomass and using it on land - probably via pyrolysis and biochar.   The costs would be greater than for your approach,  but also the benefits - in useful energy (backup for wind/solar) and soil productivity improvement.   Also I have seen concerns about your down-pushed biomass decomposing at depth.  

    3.   What are your thoughts on this single pump-up approach - with CDR in soils, not deep oceans?

Ron

On Feb 8, 2014, at 7:08 AM, William Calvin <wca...@uw.edu> wrote:

Oops, cut and paste left out the rest. Here again:

A rather lame assessment. 

Solar radiation management will have a big problem: an uneven application will rearrange the winds and thus precipitation. Guess who they will blame for the droughts.

Doubling forests is the right amount of carbon but keeping it from returning to the air via fire and rot is impractical; we cannot even do it in rain forests.

Iron blooms sink only 25% of the carbon into deep water and less than 1% into sediments. Better to get nutrients by pumping up and then pumping down the new green stuff --before it can decompose-- into deep waters that take a thousand years to begin resurfacing and then are spread out over 10k years.

-WHC

On Sat, Feb 8, 2014 at 5:31 AM, Andrew Lockley <andrew....@gmail.com> wrote:

http://www.lawrentian.com/archives/1002557

Olson gives Spoerl Lecture on geoengineering, climate change solutions

<snipped by RWL>

--
  William H. Calvin
    WCa...@UW.edu      WilliamCalvin.org

[Keith Henson]

On Sat, Feb 8, 2014 at 6:08 AM, William Calvin <wca...@uw.edu> wrote:
>
> Solar radiation management will have a big problem: an uneven application
> will rearrange the winds and thus precipitation. Guess who they will blame
> for the droughts.

Let's think about droughts.

Reducing the effect of rainfall on food production is an old idea.
It's called irrigation. But to make irrigation long term independent
from climate takes lots of capital and prodigious amounts of energy,
to desalinate sea water and pump it thousands of miles inland.

Or to take a Mississippi flood, clean out the silt and pump it into
the Ogallala Aquifer or over to the Colorado River (or both).

A really rich society could do that, especially one with oceans of
very low cost energy.

Should we put some numbers on what it would take?

Keith

PS BIo char from any source is darn good idea, even if we didn't need
to remove carbon.

PPS Andrew, it would help readability if you could preserve the
paragraph breaks.

[Stephen Salter]

Keith Henson

The climate models show that marine cloud brightening can affect
precipitation in both directions depending on when and where you spray.
We may not know where and when this should be but we can learn. Perhaps
we get blamed for not doing it.

Stephen Salter

Emeritus Professor of Engineering Design School of Engineering
University of Edinburgh Mayfield Road Edinburgh EH9 3JL Scotland
S.Sa...@ed.ac.uk Tel +44 (0)131 650 5704 Cell 07795 203 195
WWW.see.ed.ac.uk/~shs

--

[William Calvin]

For energy production, ocean has a number of possibilities. But I am focused on hauling down the atmospheric CO2 in a manner that is big, quick, and sure-fire. No amount of cleaner energy is going to clean up the excess CO2 accumulation in the air, though it is a good plan for the long-run. 

[Ronal W. Larson]

Dr.  Calvin:

    My apologies.  I failed to add CDR in my list of benefits for biochar.  I failed because CDR is what I usually am pushing on this list.  A good example I found today of where some folks place biochar for quantity and speed (what you are after) is this figure from a respected ocean acidification source:

 http://www.whoi.edu/OCB-OA/page.do?pid=112161#0

Note that biochar is in the upper right hand corner, where we all want CDR to be.  I would put biochar even higher than shown, because 1) it can heavily impact forestry as well as agriculture, and 2) it can start with ocean as well as land-based resources.

    See also a few inserts in your response below.

On Feb 10, 2014, at 6:46 AM, William Calvin <wca...@uw.edu> wrote:

For energy production, ocean has a number of possibilities.

      [RWL1:    Yes, and we should be pushing for all of them.  But I don’t believe that many give the three big advantages of biochar produced from the ocean biomass you are promoting:  1) CDR, 2) energy, 3) out year soil-related advantages well beyond the initial placement of char in soils.  I am just claiming that putting that produced carbon into soil can provide better economics and better benefits than putting it back into the ocean.

But I am focused on hauling down the atmospheric CO2 in a manner that is big, quick, and sure-fire.

      [RWL2:  Agreed we are way behind schedule.  But I think biochar can move as fast as any technology.  All of the developing world understands charcoal.   There are huge employment opportunities.  Soil scientists are available the world over.  Pyrolysis is one of the world’s oldest technologies.  Projects are going in all over the place - and no-one is asking for permission of anybody.  These are strictly private transactions.

No amount of cleaner energy is going to clean up the excess CO2 accumulation in the air, though it is a good plan for the long-run. 

     [RWL3.  Again - I apologize for not making it clear that I was on the same page with you - with ocean resources being used for new biomass production - primarily done for CDR purposes, but also having the other two non-competing benefits - one being energy.  Actually biochar does reduce the amount available for energy, but we have enough photosynthesis potential to handle both global carbon neutral and global carbon negative needs - by a huge factor (solar input being 10^4 greater than today’s global annual energy consumption).

    I’d still like your opinion on placing the photosynthesis products back on land rather than back in the ocean.

Ron

[Brian Cartwright]

To Keith and group,

Responding at bottom to these points of yours about irrigation, droughts and biochar, 

On Monday, February 10, 2014 8:11:39 AM UTC-5, Keith Henson wrote:

[snip]

Let's think about droughts.

Reducing the effect of rainfall on food production is an old idea.
It's called irrigation.  But to make irrigation long term independent
from climate takes lots of capital and prodigious amounts of energy,
to desalinate sea water and pump it thousands of miles inland.

Or to take a Mississippi flood, clean out the silt and pump it into
the Ogallala Aquifer or over to the Colorado River (or both).

A really rich society could do that, especially one with oceans of
very low cost energy.

Should we put some numbers on what it would take?

Keith

PS BIo char from any source is darn good idea, even if we didn't need
to remove carbon.

[snip] 

[Brian:] I think deployment of biochar allows us to reduce irrigation, because its structure allows buffering and storage of moisture in the soil. That gives security against both drought and flooding. It also supports the microbial life in the soil which has been depleted in decades of excessive chemical inputs, thus restoring another major carbon sink. These are low-impact technologies, and far cheaper in money and side-effects than desalination, irrigation, and energy production. Production of biochar also is a renewable energy source displacing fossil carbon with carbon already in the biosphere.

Brian

[William Calvin]

I start from urgency: lots of climate change in a decade with something of a hiatus in near-surface air warming. Anything effective we do will have a lead time and then a drawdown time. 

If that is to be no more than 25 years, we have to both counter the additional emissions (say, 350 GtC) in that period but also remove 300-400 GtC of the existing accumulation. So we are looking at more than 30 GtC/yr of removal from the air, some of which will come from ocean surface bicarbonate buffers reversing.

This time frame says we don't have time for anything that requires time for trees to grow or a lot of development: known processes like photosynthesis are preferable. 30GtC/yr requires a lot of space; on land, it requires a lot of water. That's why I suggest ocean, using local organisms that are sunk into the depths before they can rot.

I've sketched out such a process using push-pull pumps driven by wind and wave, but I would expect a Second Manhattan Project to come up with something better.

I can see biochar etc for longer term approaches, especially for stabilizing CO2 once drawn down. But it does not pass my Big, Quick, and Surefire Test.

 

[Ronal W. Larson]

Dr. Calvin and ccs

   See few inserts below

On Feb 12, 2014, at 1:34 PM, William Calvin <wca...@uw.edu> wrote:

I start from urgency: lots of climate change in a decade with something of a hiatus in near-surface air warming. Anything effective we do will have a lead time and then a drawdown time. 

[RWL1:  Agreed.

If that is to be no more than 25 years, we have to both counter the additional emissions (say, 350 GtC) in that period but also remove 300-400 GtC of the existing accumulation. So we are looking at more than 30 GtC/yr of removal from the air, some of which will come from ocean surface bicarbonate buffers reversing.

[RWL2:   I agree with your numbers, but have been thinking 50 years - on the theory we should perhaps go down at about the same rate we have come up.   I think biochar could do all of the 15 Gt C/yr half, if it expands to include ocean biomass, which is not on very many plates.  I concede not many people are thinking many GtC/yr from biochar - but there are quite a few.  I think we will want more than one CDR approach; but I have come to the conclusion that biochar has the most potential - and can be much larger than is generally realized.  Biochar application practice is known in many countries over millennia.

This time frame says we don't have time for anything that requires time for trees to grow or a lot of development: known processes like photosynthesis are preferable. 30GtC/yr requires a lot of space; on land, it requires a lot of water. That's why I suggest ocean, using local organisms that are sunk into the depths before they can rot.

[RWL3:  I believe the time delays will not be in finding the necessary raw biomass in time.  I predict the time delay will be in finding the needed funding.  My vision for the long term biomass supply is first ag residues, then coppicing, then rapid-growth perennials harvested annually (as with sugar cane), then CAM-type photosynthesis (agaves, etc).  All this possibly supported by macro and micro algae (being more photosynthetically efficient), both freshwater and oceans.  With all of this, especially oceans, maybe 15 GtC/yr is possible.  If you are correct that you can do 30GtC/yr with push-pull ocean resource, then about the same might be (should be??) possible with that same resource placed into soils, rather than back in the ocean.  I say the same because the CO2 amount lost in pyrolyzing can/will be offset with out-year increased productivity (especially through improved fungi growth).  And since BECCS can be coupled with biochar, even the initial loss can be lower.

The issue of water is of course one to worry about, but biochar is touted as saving water, which in any case is totally recaptured upon pyrolysis.  But I am totally supportive of using ocean water/nutrients to the maximum extent possible.

I've sketched out such a process using push-pull pumps driven by wind and wave, but I would expect a Second Manhattan Project to come up with something better.

[RWL4:  I am only proposing that further analysis might show that one pull pump plus pyrolysis and soil deposition might be that “something better”.  My reading on your approach suggests there will be opposition, that would not be there if the new biomass is transferred to soils.

I can see biochar etc for longer term approaches, especially for stabilizing CO2 once drawn down. But it does not pass my Big, Quick, and Surefire Test.

       [RWL5:  Well I suppose any CDR approach can “stabilize” - and the most likely for that will be the one found to be least cost during the “Second Manhattan Project”.

As to whether biochar passes your “Big, Quick, and Surefire test”, let me offer these points in biochar’s favor for doing so  (in addition to my 10-15 Gt C/yr comments above):

a.  It has the important attribute of half the carbon being available for carbon neutral energy (of any type);  most CDR approaches consume energy.

b.  There is more existing carbon in soils than the atmosphere and above ground biomass combined.  And there is a cry for increasing that amount which has been generally going down every year.  So there is both room for and a need for the CDR carbon.

c.   The practice of biochar is applicable to essentially every hectare of the 10+ Gha available.  Inland labor is also ready, and already knowledgeable about charcoal.

d.  There is a (small but growing) flow of funds for energy and soil improvement already for biochar.  I believe the remaining needed funds for CDR is as low as for any other approach, including push-pull.

e.  Looked at from the social science side, I believe there are many more supporters than detractors.  I hope that push-pull won’t have to face international approval processes, but I think it will.  I doubt biochar will have to - hundreds or thousands of biochar tests going on now and no complaints that I know of.

f.  The biochar name is only 6 + years old; it is not yet well known - but is growing very rapidly (as can be seen at www.biochar-international.org)

g.  There is a longer list.

Ron

 

On Tue, Feb 11, 2014 at 12:08 AM, Ronal W. Larson <rongre...@comcast.net> wrote:

Dr.  Calvin:

    My apologies.  I failed to add CDR in my list of benefits for biochar.  I failed because CDR is what I usually am pushing on this list.  A good example I found today of where some folks place biochar for quantity and speed (what you are after) is this figure from a respected ocean acidification source:

 http://www.whoi.edu/OCB-OA/page.do?pid=112161#0

Note that biochar is in the upper right hand corner, where we all want CDR to be.  I would put biochar even higher than shown, because 1) it can heavily impact forestry as well as agriculture, and 2) it can start with ocean as well as land-based resources.

    See also a few inserts in your response below.

<PastedGraphic-1.png>

[Brian Cartwright]

To William, Ron and group,

Permit me to add some points in favor of biochar to Ron's list. He mentions that soils are a larger sink for carbon than the atmosphere, and there is a need to increase soil carbon. Indeed about half the CO2 in the atmosphere came from soil sources, and the absence of soil carbon causes many ill effects. Sterile and saline soil resulting from overuse of fertilizer which kills off microbial life, desertified soil lacking vegetation that should buffer moisture and cool landscapes, deforested lands whose soil undergoes massive oxidation of newly exposed biota; these are cases of imbalances created in the carbon cycle which need to be corrected not only to control CO2 levels but to restore hydrology to normalize climate patterns.

Biochar is a valuable tool to boost and speed the process of re-establishing soil carbon. I hope that consideration of using biochar can be put in the bigger context of the many problems that can be solved by building carbon-rich living soil in the great variety of earth's landscapes.

Brian