[geo] Re: Crop residue ocean permanent sequestration

[Stuart Strand]

30-40% of the crop residue must be left on the land to prevent erosion.  So 
removal for biochar could reach 60-70%, not 100%.

Decadal sequestration is not enough, 100 years is not enough.  1000 years is 
barely enough.

I am not seeing much discussion of numbers here.  Can you please refer me to 
peer reviewed literature that in your opinion does the best estimate of carbon 
flows in biochar/biomass pyrolysis?


  = Stuart =

Stuart E. Strand
167 Wilcox Hall, Box 352700, Univ. Washington, Seattle, WA 98195
voice 206-543-5350, fax 206-685-3836
skype:  stuartestrand
http://faculty.washington.edu/sstrand/

Using only muscle power,  who is the fastest person in the world?
Flying start, 200 m  82.3 mph! http://en.wikipedia.org/wiki/Sam_Whittingham
Hour                            http://en.wikipedia.org/wiki/Hour_record
  55 miles, upside down, backwards, and head first!


-----Original Message-----
From: geoengineering@googlegroups.com [mailto:geoengineer...@googlegroups.com] 
On Behalf Of Sam Carana
Sent: Thursday, February 05, 2009 5:23 AM
To: geoengineering
Subject: [geo] Re: Crop residue ocean permanent sequestration


Stuart,

If we only looked at the percentage of carbon was kept out of the
atmosphere, then we should look at methods such as using crop residue
and other organic material to produce bricks, pavement, tiles and
similar building components. I wrote about Timbercrete in an article
on carbon-negative building at:
http://gather.com/viewArticle.jsp?articleId=281474977316789
Timbercrete is used to build houses, garden walls, for pavement and
the like. It is made from sand and recycled timber waste, such as
sawdust or other cellulose material. It is designed to last for
generations, so for its lifetime it will store 100% of the carbon that
was removed from the atmosphere by vegetation. I suppose that, if the
building is taken down, the material could be recycled into new
Timbercrete, but by that time we may have developed even better
methods to reduce greenhouse gases.

Anyway, my point is that this figure of 90% efficiency in keeping
carbon out of the atmosphere should not be taken as the sole measure
to assess methods. If we took such a narrow view, then the above
Timbercrete would seem superior to ocean sequestration. But again, my
point is that we should instead look at the wider picture. If we can
pyrolyze three times as much material and bury it in the form of
biochar, then that method would store a greater net amount of carbon.

In conclusion, we should get communities to grow more vegetation and
keep as much of the carbon contained in the vegetation out of the
atmosphere for a long time, at least for decades to come. We can only
suggest methods, but what works best locally depends on the benefits
that communities each see in the various methods. Part of that bigger
picture is illustrated by the image of my article Four Cycles of a
Sustainable Economy, at:
http://gather.com/viewArticle.jsp?articleId=281474977561808

Don't just look at the figures for two specific methods in isolation.
We need to give it all we've got and many methods can work together
and, by complementing each other, increasing the result in terms of
reducing greenhouse gases.

Cheers!
Sam Carana



On Thu, Feb 5, 2009 at 4:06 AM, Stuart Strand <sstr...@u.washington.edu> wrote:
> Sam,
>
> In your first point you touch on one problem:  pyrolysis is about 50% 
> efficient use of crop residue carbon for sequestration.  CROPS is about 90% 
> efficient.  Perhaps a combination of the two would be synergistic.
>
>   = Stuart =
>
> Stuart E. Strand
> 167 Wilcox Hall, Box 352700, Univ. Washington, Seattle, WA 98195
> voice 206-543-5350, fax 206-685-3836
> skype:  stuartestrand
> http://faculty.washington.edu/sstrand/
>
> Using only muscle power,  who is the fastest person in the world?
> Flying start, 200 m  82.3 mph! http://en.wikipedia.org/wiki/Sam_Whittingham
> Hour                            http://en.wikipedia.org/wiki/Hour_record
>  55 miles, upside down, backwards, and head first!
>
>
> -----Original Message-----
> From: geoengineering@googlegroups.com 
> [mailto:geoengineer...@googlegroups.com] On Behalf Of Sam Carana
> Sent: Wednesday, February 04, 2009 6:21 AM
> To: geoengineering
> Subject: [geo] Re: Crop residue ocean permanent sequestration
>
>
> Stuart, you conclude that ocean burial was more efficient in reducing
> greenhouse gases than biochar, but you draw that conclusion by looking
> at only one small part of what is a much bigger picture.
>
> 1. As we get better in pyrolysis, it should be no problem capturing
> half of the carbon in the form of biochar. It depends partly on what
> material is pyrolyzed, but that's also the beauty of this method, i.e.
> many things can be treated this way, such as agricultural waste,
> animal manure, sawdust, etc.
>
> 2. Apart from this, biochar enriches soil, allowing more vegetation to
> grow and draw carbon dioxide from the atmosphere. This will raise the
> net effect of this method well beyond the 50%. This also goes hand in
> hand with afforestation, prevention of erosion, less emissions of
> nitrous oxide (N2O) by fertilisers, the ability to feed a growing
> world population and preservation of rainforest and water resources.
>
> 3. Thirdly, pyrolysis also produces biofuel and hydrogen. Quite
> frankly, I cannot imagine a cleaner way to power shipping than by
> means of hydrogen. If you take into account the carbon that would
> otherwise result from ships burning (a typically very polluting type
> of) oil, this alone could very well make the pyrolysis method
> worthwhile as a method to reduce greenhouse gases.
>
> Combine the above three, and the combined net effect of pyrolysis,
> biochar and hydrogen seems more efficient than ocean sequestration,
> which requires substantial transport and logistics. Similarly, the
> biofuel produced by pyrolysis could be used in transport, and perhaps
> we can even capture some of the carbon that is released in the
> process.
>
> If you look at each of these three points in isolation, there may seem
> to be better alternatives than biochar, in the sense that each such
> alternative may either seem to sequester more carbon, act as a better
> fertiliser or produce energy cheaper. But if you look at the bigger
> picture of what difference biochar could make, it is superior in all
> respects, i.e. in its capacity to reduce greenhouse gases from the
> atmosphere, as a way to enrich soil and as a way to produce energy,
> e.g. for the transport sector.
>
> For a local community there may be many reasons to welcome pyrolysis
> and biochar burial. It can deliver many local benefits, such as:
> - thinning forests, removing crop residue and getting rid of waste,
> thus reducing the risk of wildfires, pests and diseases,
> - providing renewable energy on demand,
> - enriching soil, which allows farmers to stay on their land and
> reduces slash-and-burn of further forest;
> - preventing long diseases (people can stop practices like burning cow
> dung and wood in open fires, for cooking and heating).
> People will welcome solar cookers together with pyrolysis and biochar,
> and start to plant more vegetation, rather than to breed more
> livestock (and the associated nomadic lifestyle). The fact that this
> new lifestyle also reduces greenhouse gases in many ways may not be an
> argument for them, but all the other benefits do weigh heavily.
>
> Try convincing a local community to carry their agricultural waste and
> surplus wood to the sea, for dumping into the ocean, and they will see
> no benefit in doing that.
>
> By contrast, local communities will see the benefits of less need for
> fertilisers, as this saves money and also because this means less dead
> zones in the sea and thus results in better yield of fish. So, local
> communities will welcome biochar, even if they are unaware of
> greenhouse gases. And of course, biochar and the associated change in
> lifestyle as pictured above will also reduce global warming in many
> ways, such as by:
> - reducing the use of cow dung as fuel, meaning less methane due to
> less livestock;
> - reducing the use of fossil fuel such as oil, e.g. to power ships or
> for heating;
> - reducing the use of wood and conventional charcoal for heating and cooking;
> - increasing vegetation growth, thus drawing larger amounts of carbon
> dioxide out of the atmosphere;
> - reducing soot, which acts as a greenhouse gas and settles on top of
> glaciers and polar ice, causing albedo change;
> - reducing CO2 and methane emissions, compared to the alternative of
> leaving much organic material to rot away;
> - reducing emissions of nitrous oxide (N2O), due to less use of fertilisers;
>
> Cheers!
> Sam Carana
>
>
>
> On Tue, Feb 3, 2009 at 8:28 AM, Stuart Strand <sstr...@u.washington.edu> 
> wrote:
>>
>> I am reading the biochar literature now and it is fascinating stuff.  But 
>> first glance reveals that pyrolysis schemes return 20-50% of the total 
>> carbon originally in the biomass back to sequestration in the soil (ES&T 
>> Sept 1 2007, p 5932).  So already there is an efficiency problem compared to 
>> CROPS which is 90% efficient.  Also I am concerned about how often biochar 
>> can be done on a given soil without undesirable effects on agricultural soil 
>> ecology.  And how permanent is charcoal in soil?  Amazonian terra preta 
>> still contains charcoal, but how much was lost over the intervening 500 
>> years?  We would be storing biochar in soil in direct contact with the 
>> atmosphere.  If it decays there is no safety factor as there would be in 
>> deep sediments.  Safety factors and redundancy are important in engineering; 
>> although geoengineering doesn't seem much like any other engineering I am 
>> familiar with...
>>
>>   = Stuart =
>>
>> Stuart E. Strand
>> 167 Wilcox Hall, Box 352700, Univ. Washington, Seattle, WA 98195
>> voice 206-543-5350, fax 206-685-3836
>> http://faculty.washington.edu/sstrand/
>>
>> -----Original Message-----
>> From: geoengineering@googlegroups.com 
>> [mailto:geoengineer...@googlegroups.com] On Behalf Of Andrew Lockley
>> Sent: Monday, February 02, 2009 12:46 PM
>> To: dwschn...@gmail.com
>> Cc: Stuart Strand; markcap...@podenergy.org; geoengineering@googlegroups.com
>> Subject: [geo] Re: Crop residue ocean permanent sequestration
>>
>>
>> Isn't it more efficient to pyrolyse the waste first, recovering energy
>> and reducing transport carbon?
>>
>> A
>>
>> 2009/2/2 David Schnare <dwschn...@gmail.com>:
>>> Stuart:
>>>
>>> I've been studying notill agriculture that relies, in major part, on
>>> building soil carbon to hold nutrients in the soil (reducing application
>>> requirements and keeping it out of streams).  While a 14% sequestration
>>> (limited to only about 20 years before maxing out on sequestration
>>> potential) seems small compared to 100% if dumped into the ocean deeps, it
>>> seems to me that when used in places more than 150 miles from the ocean, it
>>> is carbon reduction efficient (based on fuels needed for transport).
>>>
>>> As such, shouldn't we be narrowing the crop waste discussion to coastal
>>> agriculture only, and give credit for soil sequestration where that's as
>>> good as is available?
>>>
>>> David Schnare
>>>
>>> On Mon, Feb 2, 2009 at 11:54 AM, Stuart Strand <sstr...@u.washington.edu>
>>> wrote:
>>>>
>>>> By straw we are referring to the stalks of agricultural plants, wheat
>>>> stalks and corn stover.  The water and nutrients were expended to grow the
>>>> grain.  Straw has a low nutrient content (C/N = ca 50/1).  Presently straw
>>>> is wasted by allowing it to decay on the soil surface (only 14% or less of
>>>> the straw carbon is incorporated into the soil).
>>>>
>>>>
>>>>
>>>> A variety of processes are available to get energy out of crop residues,
>>>> but they are limited by the poor specific energy of biomass.  Our focus is
>>>> how to efficiently remove Pg amounts of carbon from the atmosphere and
>>>> permanently sequester it in the least environmentally harmful manner.
>>>>
>>>>
>>>>
>>>>   = Stuart =
>>>>
>>>>
>>>>
>>>> Stuart E. Strand
>>>>
>>>> 167 Wilcox Hall, Box 352700, Univ. Washington, Seattle, WA 98195
>>>>
>>>> voice 206-543-5350, fax 206-685-3836
>>>>
>>>> skype:  stuartestrand
>>>>
>>>> http://faculty.washington.edu/sstrand/
>>>>
>>>>
>>>>
>>>> Using only muscle power,  who is the fastest person in the world?
>>>>
>>>> Flying start, 200 m  82.3 mph!
>>>> http://en.wikipedia.org/wiki/Sam_Whittingham
>>>>
>>>> Hour                    http://en.wikipedia.org/wiki/Hour_record
>>>>
>>>>   55 miles, upside down, backwards, and head first!
>>>>
>>>>
>>>>
>>>> From: geoengineering@googlegroups.com
>>>> [mailto:geoengineer...@googlegroups.com] On Behalf Of
>>>> markcap...@podenergy.org
>>>> Sent: Wednesday, January 28, 2009 7:16 PM
>>>> To: geoengineering@googlegroups.com
>>>> Subject: [geo] Re: Crop residue ocean permanent sequestration
>>>>
>>>>
>>>>
>>>> Stuart,
>>>>
>>>>
>>>>
>>>> Why bundle and stash terrestrial straw.  Growing straw requires
>>>> substantial fresh water and nutrients.  You could bundle and stash algae
>>>> instead.  How about sargassum or kelp?  A macro-algae can be bundled in
>>>> large mesh "tea bags" with much of the water being squeezed out during the
>>>> bundling process.
>>>>
>>>>
>>>>
>>>> Then, as long as you've got bundles of biomass, why not separate the
>>>> nutrients from the carbon before you stash the carbon?  That way, you can
>>>> recycle the nutrients back to the ocean surface for growing more biomass.
>>>> High-pressure anaerobic digestion will release the carbon in two separate
>>>> streams; one gaseous CH4, one dissolved CO2, which easily converts to 
>>>> liquid
>>>> CO2 at typical ocean temperatures and pressures.
>>>>
>>>>
>>>>
>>>> Would you or others be interested in a California Energy Commission grant
>>>> to run a few bench experiments on high-pressure anaerobic digestion?  I can
>>>> send a draft abstract.
>>>>
>>>>
>>>>
>>>>
>>>>
>>>> Mark E. Capron, PE
>>>>
>>>> Oxnard, California
>>>>
>>>> www.PODenergy.org
>
> >
>



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