POO POWER! Part 4: Pigs farting Power!

Even though assessment for this blog is over... I know I did this not for my environmental conscience, but because I was FORCED to... I feel the need to carry on posting because I love the many uses of poo...and here is another example of POO POWER!

So the video shows a great way to sustainably develop.... income from pig farming, waste management, and energy production on a decentralised scale... tick tick tick for the World Bank's Rural development initiatives!


This technology is being rolled out at a global level, it is happening in India and China where rural populations are increasing and require energy and income like anyone else.


More on this to come!! Hopefully! :D


Disclaimer.... I do not want any marks for these posts after the deadline of submission, I would just kind of like to carry on if possible??? Is that bad?

First an internet search engine... Now pig sh**?

Is there no end to the power that is google? Clearly there is and that is why they are investing in pig poo power (say that really fast 100 times without dying of lack of oxygen or boredom). As seen in this article.

The technology is simple, decompose the poo to produce methane (our favourite gas after oxygen and helium... *squeeeek!*) and then burn this highly potent GHG to produce heat to boil water to produce steam to turn a turbine to produce electricity! Loads of to-s!


Get this... it will produce enough to power an amazing 35 homes! That's right 3...5...! To be fair 1 american home is practically 20 European homes... WIN.


Highlighting the offsetting equivalent, the effect of 900 cars have been taken of the roads (and are now in China...lol!) no in all seriousness it shows the GHG producing potential of livestock.

Add a little P, get a load more Poo! Part 2: Video time!

This video summarises the main arguments around P, and it's in green (my favourite colour!). I particularly like the part about doing your part whilst sitting...just one letter away from what you're actually doing!

POO POWER! Part 3: Thames Water using our crap!

Thames Water are harnessing the power of sewage waste that comes from our toilets... that's right one man's waste is another companies fuel.

The article, from the guardian, explores the potential for energy production at the plant:

"The company estimates that 16% of its electricity needs will be covered in the current financial year by so-called poo power – enough to run about 40,000 average family homes – from a total energy requirement of 1,300 gigawatt hours."

Expanding this technology to all waste treatment works will save a lot of unnecessary carbon dioxide emissions from either producing energy from conventional combustion processes or letting the waste decompose anaerobically producing methane.

POO POWER! Part 2: Motorcycles, S**t whilst you ride?!?

Hold the toilet! What's this?!?


In an earlier post I said don't start peeing/crapping into your Mercedes... well now you can into your new toto motorcycle!


Ever had the urge to poo while riding down the motorway?


Do you get s**t scared when riding with your motorcycle buddies?


Well this is for you!

This new motorcycle, produced by toto operates using a "one in, one out" policy. You put food in one end (your mouth) and get fuel out the other (your... well if you don't know by now where it comes out SHAME ON YOU, I refuse to degrade this post to enlighten your curiosity about bowel movements).

The vehicle breaks down the poo into biogas (methane) and runs on the combustion of that fuel; reducing emissions from what would have otherwise been used, petrol/oil.

The only downside is privacy... and I really wouldn't want to be behind this driver in a traffic jam!

POO POWER! Part 1: Cars powered by poo!

For those of you who like to drive but are concerned about the rising costs of fuel and environmental issues around its production, this is for you!

This video and this news article in the Guardian explains all!

A water treatment plant in Bristol, part of the Wessex Water group of companies, is producing methane from human waste flushed down the loo! The biogas could resolve some sustainability issues around fuel for cars, as the man at the end of the video says:

 "As long as there are people, cows and chickens, they'll be methane."

I agree...

However! Even though biogas is sustainable and is beneficial in terms of dealing with increasing amounts of waste that we will produce, the fundamental problem is the fact that it is still a form of combustion; combustion = CO₂. 

So, on the one hand it's sustainable and uses the methane that would otherwise contribute a more to global warming in the short term. On the other, it doesn't address the underlying dependence on carbon dioxide producing processes which will inevitably exacerbate climate change. 

Fossilised farts (and other agroGHGs)! Part 3: The critiques of fart records: it’s ALL NATURAL.

Now both articles (Fuller et al., 2011; Ruddiman et al., 2011) and their side of the debate have critiques. From these graphs (from Ruddiman et al., 2011) they become evident:

In the first (A) graph you can see that the relationship between CH₄ concentrations and population is not constant. Initially CH₄ per capita increased proportionally, then methane rose steadily whilst population was rising exponentially. This decoupling is down to (what Ruddiman et al. 2011 note from Ellis and Wang in 1997) different land production efficiencies and priorities. With increasing intensification techniques, like rearing cattle, more land and plants are needed as well as primitive ruminants who haven’t been selectively bred to maximise meat or milk production yet. These inefficiencies which increase CH₄ release (IPCC, 2006) where only dealt with during the latter half of the Holocene, this is just one argument supporting anthropogenic methane emissions prior to the Anthropocene; this decouples methane and population, whilst explain the change in rates. Also land use per capita dropped, as seen in the second graph, that is not to say that the early human pastoralists had large herds of cows farting across the once green, bread-basket of the Sahara, it just highlights primitive techniques of farming. Quantifying the contributions of CH₄ into rice agriculture and livestock rearing category is hard as more research needs to be undertaken (Fuller et al., 2011; Singarayer et al., 2011).

Picking up on the point of the inter-polar gradient (IPG), Chappellaz et al. (1997) investigated the difference between the polar records of methane concentrations. Studying the Arctic GRIP ice core and the Antarctic BYRD and D47 ice cores, they attributed the changes in the IPG to initially (5.7 and 2.5 – 5 ka) lower atmospheric CH₄ levels due to the on-going drying of the tropical regions combined with massive peat land growth in the northern boreal regions after 5 ka. With a recent period (ca. 1 ka) increases due to increased wetness and significant anthropogenic emissions. Harder et al. (2007) investigates this further, coupling a GCM with information on the sinks of methane; volatile organic compounds (VOC) and the sea (changes in sea surface temperature, SST). Another vital sink, the largest in fact (and one I hope to investigate further is the hydroxyl radical (­^●OH). Stressing the importance of changes in the various other sources and sinks, Harder et al.’s research show that the IPG changes are the result of dynamics within the ‘methane cycle’, between the balance between the sources/sinks. However, they draw attention to the necessity to improve understanding about how methane may react with other GHGs especially considering the fact that the hydroxyl radical is the sink for many other GHGs. Any anthropogenic influence on the changing methane concentrations either at 5 ka or in the IPG has been sidelined.

This point is underlined by Singarayer et al. (2011) as concluding remarks describe the lack of model evidence successfully calibrating predicted and observed data sets, with an anthropogenic input providing a correct outcome. It goes even further saying, and I quote:

“The late Holocene increase in methane can be primarily ascribed to increasing emissions from the Southern Hemisphere tropics. In the late Holocene, unlike the last interglacial, these increases are not counteracted by equivalent decreases in Northern Hemisphere emissions. We suggest therefore that direct anthropogenic influences are not necessary to explain the late Holocene methane record.”

Rather than the idea of cows farting (as it is quite hard to believe!); Singarayer et al. (2011) looks into possible overlooked variables. Exploring such variables like: glacial extent, and how it may effect subtle changes in the source regions; seasonality of the SH tropical wetland, and the resulting emissions; but most importantly, the link to the Eemian period where the orbital configuration is comparable to the present (and where models attempting to show the anthropogenic link fall short). They reaffirm their point that SH emissions were not counteracted with NH CH₄ emission decreases.

Even Burns (2011) discusses the possibility of an ‘all-natural’ 5 ka methane rise due to tropical produce methane causing the deviation from the expected. Burns looks at speleothem records to infer monsoonal strengths. It shows that the monsoons did migrate southwards, so making the highly productive tropics and areas south of the equator increasingly waterlogged and, ergo, greater CH₄ productive. It does seem that it is a one or the other theory approach… Neo can only take either the red or blue pill. There is no such thing as a purple one. But here, I would suggest that even though evidence is in favour of an all-natural approach. In my opinion one cannot exclusively write out the other, and the debate will go on for ages; but archaeological evidence shows the techniques expansion. Whether you like it or not, ruminants fart, producing methane, as well as humans might I add!

I would like to think that thousands of years ago my ancestors around the Mediterranean were herding farting sheep, farting cows and farting chickens, contributing to increasing methane concentrations in the atmosphere. It was a simpler time; it was a less fartier time!

Reference list for the 3 parts of Fossilised Farts (and other agroGHGs)!

Brook, E. J., Sowers, T. and Orchardo, J., 1996, Rapid variations in atmospheris methane concentration during the past 110,000 years, Science, 273, 1087-1091 pp.

Burns, S. J., 2011, speleothem records of changes in tropical hydrology over the Holocene and possible implications for atmospheric methane, The Holocene (special issue), 1-7 pp.

Chappellaz, J., Blunier, T., Kints, S., Dallenbach, A., Barnota, J., Schwander. J., Raynaud, D. and Stauffer, B., 1997, Changes in the atmospheric CH­₄ gradient between Greenland and Antarctica during the Holocene, Journal of Geophysical Research, 102, D13, 15,987-15,997 pp

Ellis, E. C. and Wang, S. M., 1997, Sustainable traditional agriculture in the Tai Lake region of China, Agriculture Ecosystems and Environment, 61, 177-193 pp.

Fuller, D. Q., Manning, K., Castillo, C., Kingwell-Banham, E., Weisskopf, A., Qin, L., Sato, Y. and Hijmans, 2011, The contribution of rice agriculture and livestock pastoralism to prehistoric methane levels: An archaeological assessment, The Holocene, 21, 743-759 pp.

Harder, S. L., Shindell, D. T., Schmidt, G. A. and Brook, E. J., 2007, A global climate model study of CH₄ emissions during the Holocene and glacial-interglacial transitions constrained by ice core data, Global biogeochemical cycles, 21, GB1011, 1-13 pp.

IPCC, 2006, CH4 Emissions from enteric fermentation,in Guidelinesfor National Greenhouse Gas Inventories Volume 4 Agriculture, Forestry andOther Land Use, writtenby Gibbs, M. J., Conneely, D., Johnson, D., Lasse, K. R. and Ulyatt M.J., , 297-320 pp. 

Ruddiman, W. F., Kutzbach, J. E. and Vavrus, A. J., 2011, Can natural or anthropogenic explanations of late-Holocene CO₂ and CH­₄ increases be falsified? The Holocene, 21, 865-879 pp.

Schlit, A., Baumgartner, M., Schwander, J., Buiron, D., Capron, E., Chappellaz, J., Loulergue, L., Schupbach, S., Spahni, R., Fischer, H. and Stocker, T., 2010, Atmospheric nitrous oxide during the last 140,000 years, Earth and Planetary Science Letters, 300, 33-43 pp.

Singarayer, J. S., Valdes, P. J., Friedlingstein, P., Nelson, S. and Beerling, D. J., 2011, Late Holocene methane rise caused by orbitally controlled increase in tropical sources, Nature, 470, 82-86 pp.

Sowers, T., 2010, Atmospheric methane isotope records covering the Holocene period, Quaternary science Reviews, 29, 213-221 pp.

Wolff, E. W., 2011, Methane and Monsoons, Nature, 470, 49-50 pp.

So what is the problem with excessive farting (also burping, urinating and excreting)?

Why is it even an issue worth discussing in a blog dedicated to the world of excrement? Well the fundamental problem we face, not just as a species, but as inhabitants of earth, is climate change. We humans use the planet as our only home, kitchen, garden and toilet. Like any other confined space, when you begin to change the chemical make-up of the gas enclosed in that volume, you begin to change the overall physical, chemical and thermal properties of that gas. In the case of excrement, methane (CH₄) and nitrous oxide (N₂O) is produced through a variety of processes (as is carbon dioxide, CO₂) which contribute to the greenhouse effect (Popp et al., 2010). Carbon dioxide is the most significant anthropogenic produced GHG due to the sheer quantity that is emitted into the atmosphere from human activities.  

However, as I touched upon in the previous post, over 100 years, the same amounts CO₂, CH₄, and N₂O have varying potencies due to their thermodynamic properties. This property is applied as a ration of heat trapped by one unit mass of the GHG compared to one unit mass of CO₂; this is called the Global Warming Potential (GWP) (Pitesky et al., 2009). As it a ratio, CO₂ has a GWP of 1; CH₄ has a GWP of 23 (in the previous post I wrote that the potency of methane was 20 times that of carbon, it was wrong sorry!); N₂O is 296 (FAO, 2006). From this data, it shows how important methane and nitrous oxide produced from livestock production, and in particular from poo, will be an increasing problem, not just as the total number of GHGs (CO₂ and non-CO₂) is set to increase from projected and modelled figures (Popp et al., 2010). In addition, with populations estimated to reach 9 billion by 2055 (World Bank, 2011) and increasing qualities of life reflecting greater demand for meat in the diet; livestock rearing is set to increase; that equates to a whole load of shhhhh… excrement.

The United Nations Food and Agriculture Organisation (FAO) commissioned a report on the impact livestock production has on the planet,Livestock’s long shadow (FAO, 2006). As a whole, livestock (either directly or indirectly) is responsible for 18% of total anthropogenic GHG emissions (FAO, 2006); those figures broken down into individual GHG include:

·  Carbon dioxide (CO₂) 9% of global anthropogenic emissions.

·  Methane (CH₄₎ 35 – 40% of global anthropogenic emissions.

·  Nitrous oxide (N₂O) 65% of global anthropogenic emissions.

·  Ammonia (NH₃) 64% of global anthropogenic emissions.

However, as I will investigate later on in the blog (or further towards the top of the blog), Excretion and everything  does not just play an integral role to GHG emissions, it also plays a vital role in the nutrient cycle, particularly phosphorous and nitrogen. Phosphorous (P), as well as nitrogen (N) in the form of nitrates and other vital macronutrients like magnesium (Mg), potassium (K) and calcium (Ca) are required as well as a variety of other micro nutrients (Robinson, 2004). Phosphorous is often a limiting factor in plant production, due to its vital role as an ingredient in deoxyribonucleic acid (DNA) and ribonucleic acid (RNA), the building blocks of life; and in the Adenine triphosphate (ATP) which is the primary method of intracellular energy release and storage (Biology-Online, 2011), so we can all move, keep warm and most importantly… LIVE! Also, specifically to plants, P is necessary for healthy root growth, vital for the uptake of water and the other nutrients. The role fertiliser plays is significant, and indeed focusing on one of the nutrients, phosphorous, an increasingly important point has surfaced. Livestock (cows for example) need to eat; feed is created from plants; high amounts of land and biomass is required to produce vast amounts of feed; limited land resources dictates more intensive farming methods; greater dependence on higher yields; synthetic fertilisers created to provide the vital nutrients for plant growth; mining of phosphates from a finite source requires large amounts of energy whilst depleting the source.

As you can see, just from scratching the surface, cow (and other animals’) farts and poo pose a more serious problem than the humorous connotations applied to them suggest. Over the next few weeks and posts I hope to show you a greater insight in to the world of climate change, nutrients (re)cycling, pollution, eutrophication, renewable energy and many, many more uses, and subjects, which poo influences.

This blog may overlap with others, in fact it will. A post by fellow GEOG3057 blogger Emma (I hope she is Ok with me using her name), touches on the renewable potential of methane gas from… well cow farts. Another blog dedicated to the debate around biofuels can also shed light on the increasing diversification of energy sources, by another fellow GEOG3057 blogger Yulia. But those topics are for another time!

Next I hope to give you an insight into past methane releases and the relationships between the potent GHG and the atmosphere, looking at palaeo records of methane…essentially fossilised cow farts… Ok well some of the methane was produced by pre-modern time cows farting. Until then… watch those deadly emissions!

References:

Biology Online, 2011, ATP Definition. Available from: http://www.biology-online.org/dictionary/Atp. [Online] accessed 24/10/2011.

FAO, UnitedNations, Food and Agriculture Organisation, 2006, Livestock’s Long Shadow: Environmental issues and options, FAO-UN:Rome.

Pitesky, M. E., Stackhouse, K. R. and Mitloehner, F. M. 2009, Clearing the Air: Livestock’s contribution to climate change, Advances in Agronomy, 103, 1-40 pp.

Popp, A., Lotze-Campen, H., Bodirsky, B., 2010, Food consumption, diet shifts and associated non-CO₂ greenhouse gases from agricultural production. Global Environmental Change, 20, 451-462 pp.

Robinson, G. 2004, Geographies of Agriculture: Globalisation, restructuring and sustainability. Harlow: Pearson Publications Limited.

World Bank, Development Research Group, Human Developmentand Public Services Team, (Das Gupta, M., Bongaarts, J. and Cleland, J.) 2011, Population, Poverty and SustainableDevelopment: A Review of the Evidence, World Bank: Washington D.C., WPS5719.

If you find this sh.... stuff interesting then you might find these blogs interesting to! 

Please check them out, as I try to myself!

Agriculture: Human Health and Earth Health: http://robs-agriculture.blogspot.com/ 

Biofuels: Way Ahead or Blind Alley: http://biofuels-wayaheadorblindalley.blogspot.com/

Fixing Climate Change: http://fixingclimatechange.blogspot.com/