Bug Power

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3 Jun 2005 19:28:57 -0000

 

Bug Power

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ISIS Press Release 03/06/05

 

Bug Power

 

Waste-gobbling bacteria may be our dream ticket to clean

renewable energy. Dr. Mae-Wan Ho

 

A fully referenced version of this paper is posted on ISIS

members' website.

http://www.i-sis.org.uk/full/BugPowerFull.php

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Resources and energy from wastes

 

Bacteria that gobble wastes are a godsend. They prevent the

build up of wastes in our environment and play an

indispensable role in making wastewater safe for domestic

animals, wild life, and human beings. In many Third World

countries, these same bacteria are working miracles turning

manure and other wastes into valuable resources to support

highly productive farms that require no input and generate

little or no waste ( " Dream farm " , this series). When these

bacteria are confined in anaerobic digesters with limited or

no access to oxygen, they ferment the wastes, release and

conserve nutrients for livestock and crops, and produce

`biogas' as by-product, which typically consists of about

60% methane (CH4) and a small amount of hydrogen (H2), both

of which can be burnt as smokeless fuel.

 

Within the past two years, these same bacteria are showing

even more remarkable potential for producing clean and

renewable energy while reducing greenhouse gas emissions.

 

Hydrogen economy on potato waste

 

The " hydrogen economy " is on everyone's lips as the answer

to the ultimate clean energy. Burning hydrogen produces pure

water instead of green house gases, and it is by far the

most energetic fuel on earth, weight for weight. But in

order to really reduce green house gas emissions, hydrogen

must be produced sustainably with renewable sources such as

sun, wind and biomass. About half of all hydrogen produced

currently is from natural gas, the rest is produced

primarily using other fossil fuels. Only 4% is generated by

splitting water using electricity derived from a variety of

sources.

 

At BIOCAP Canada's First National Conference in February

2005, a research team at the Wastewater Technology Centre

and the University of Waterloo in Ontario, Canada, presented

a poster describing a prototype process for producing

substantial amounts of hydrogen as well as methane from

potato waste [1].

 

The team used a two-stage anaerobic digestion to get first

hydrogen and then methane. In this way, it was possible to

optimize the first stage for producing hydrogen. The key

appears to be an acidic pH of 5.5 in the hydrogen reactor,

instead of pH 7 in the methane reactor. Both reactors were

run at 35C.

 

They pulped the potatoes bought from a store and treated the

slurry with peptone (an enzyme that breaks down protein),

then seeded the two reactors – one for hydrogen the other

for methane - with digested sludge from the local wastewater

treatment plant to get the bacteria in place. For the

hydrogen reactor, the seed sludge was pre-cultivated in a

sucrose medium for a few days before switching to potato

waste when high hydrogen production was confirmed. For the

methane reaction, no precultivation of the sludge was

required.

 

From the 4th day, the potato pulp replaced sucrose and

hydrogen biogas was produced continuously for a further 90

days. The maximum production rate from the one litre reactor

was 270ml/h on the 17th day, and the average rate over the

entire 90-day period was 112.2ml/h. The hydrogen fraction

fluctuated between 39 and 51 percent of the biogas (v/v).

The average chemical oxygen demand (COD) concentration (a

measure of the amount of waste present) of the fluid coming

out of the hydrogen reactor was 7 220mg/L, at an input

concentration of 12 800mg/L. So more than 40 percent of the

waste was removed.

 

Once hydrogen production became stable after the 20th day,

the outflow from the hydrogen reactor was transferred to the

second, bigger (methane) reactor, 5 litres in volume. During

the 70 days of operation, methane biogas was produced

continuously; the maximum rate was 410ml/h, and the average

rate, 213 ml/h. The concentration of methane in the biogas

was between 69 and 79 percent. The average COD concentration

in the methane bioreactor outflow was 4 130 mg/L. Again, the

process removed more than 40% of the wastes. Together, the

two reactors removed 68% of the waste.

 

Based on the hydrogen and methane production rates, the

average energy yield from each kilogram dry weight of potato

waste was 4.96 MJ (1.4kWh) and the maximum energy yield,

9.58 MJ (2.7kWh). For comparison, burning 1 kg wood yields

about 20MJ [2]. But because the energy is generated from

waste, it is essentially free, and does not require chopping

down trees.

 

Potato is the third largest food crop in the world, and

Canada is one of the leading producers (4.7million tonnes

annually). Large amounts of potato waste come from food and

potato processing plants. This is potentially a huge source

of renewable, clean energy.

 

Dual purpose microbial fuel cell

 

A research team in Pennsylvania State University has also

discovered how to coax the same bugs to make plenty of

hydrogen while they are gobbling wastes [3].

 

When the bacteria ferment glucose, they generate a maximum

of 4 molecules of hydrogen per molecule of glucose and end

up at best with two molecules of acetic acid that they

cannot convert further to hydrogen due to an electrochemical

barrier. But, given a little electrical boost, the bacteria

can jump over the barrier to generate more hydrogen.

 

The research team, led by Dr. Bruce Logan, already made news

in 2004 [4], when they succeeded in getting the bacteria to

produce electricity while removing wastes.

 

The bacteria were put into a microbial fuel cell that

generated 26mW m2 of electricity while removing up to 80% of

the wastes that flowed through.

 

These waste treatment bacteria, numerous species belonging

to many genera including Geobacter, Shewanella, and

Pseudomonas, have the ability to transfer electrons obtained

by fermenting wastes to external metals [5]. When the

bacteria are attached to electrodes, the electrons are

transferred to the electrodes (the anode), to flow through

an external circuit to the cathode where they combine with

oxygen from the air and protons (hydrogen ions) to form

water.

 

The reactor then used was a single cylindrical plexiglass

chamber the size of a soda water bottle in which the anode,

consisting of eight graphite rods, was placed in a

concentric arrangement surrounding a central cathode that

was exposed to air. The air-porous cathode consisted of a

carbon/platinum catalyst/proton exchange membrane layer

fused to a plastic support tube.

 

The efficiency of the system, based on waste removal and

current generation was less than 12%, indicating that a

substantial fraction of the organic matter was lost without

generating current; perhaps in producing more bacteria. But

as the bacteria were doing their intended job, which was to

remove waste, any electricity generated at the same time was

an extra bonus.

 

Excluding air and boosting electric potential

 

Now, the team has discovered that by excluding air from the

cathode, and by giving the bugs a boost of about 250mV, they

can make the bugs produce hydrogen at high efficiency. They

refer to this process as electrochemically assisted

microbial production of hydrogen.

 

Normal fermentation converts glucose to dead end products

such as acetic and butyric acid:

 

see equation in http://www.i-sis.org.uk/BugPower.php

 

In the first case, four molecules of hydrogen are generated,

and in the second, only two molecules. The greatest

theoretical yield possible is four molecules of hydrogen per

molecule of glucose.

 

The microbial fuel cell, however, offers a new solution to

the problem. By augmenting the electric potential in the

microbial fuel cell circuit, it gave just the little help

needed for the bacteria to make hydrogen out of acetic acid.

 

In a typical fuel cell, the open circuit potential of the

anode is about –300mV. If hydrogen is produced at the

cathode, the half reactions occurring at the anode and the

cathode with acetic acid oxidized at the anode, are as

follows:

 

see equation in http://www.i-sis.org.uk/BugPower.php

 

In order for the bugs to donate electrons to the anode from

acetic acid, however, the anode potential has to be made

less electronegative.

 

To improve the efficiency of the intended process, the

researchers also created a two chamber microbial fuel cell

instead of the one-chamber version they had previously

constructed. One chamber contained the anode, the other the

cathode, separated by a proton exchange membrane. A major

advantage of housing anode and cathode in separate chambers

is that the hydrogen produced at the cathode is separated

from the carbon dioxide at the anode at source. Instead of

being exposed to air, the cathode chamber was sealed. A

voltage of 250mV or greater was applied to the circuit by

connecting the positive pole of a power supply to the anode,

and the negative pole to the cathode.

 

The external power supply increased the anode potential from

–300mV to -291mV with a boost of 250mV and to –275mV with a

boost of 850mV, producing hydrogen and degrading more than

95% of the acetate in the process. The recovery of electrons

as hydrogen was over 90%. The Coulombic efficiency - defined

as the recovery of total electrons in acetate as current -

ranged from 60 to 78% depending on the applied voltage. Thus

2.9 of the theoretical maximum 4 molecules of hydrogen are

obtained from the acetic acid reaction with water by an

injection of 250mV of electricity (see equation 3). This

compares favourably with the costly1800-2000 mV needed for

getting hydrogen from splitting water [6].

 

A combined fermentation and bioelectrochemically assisted

anaerobic microbial fuel cell has the potential to produce

as much as 8 to 9 molecules of hydrogen starting from a

molecule of glucose (The theoretical maximum is 12, see

equations 1, 3 and 4.)

 

With this bioelectrochemically-assisted reactor, hydrogen

can be produced from any type of biodegradable organic

matter. Combined hydrogen production and wastewater

treatment will offset the substantial costs of wastewater

treatment as well as provide a contribution to the hydrogen

economy. As the technology is rather simple, it can be

adapted for use at different scales, in third world

countries as well as industrialised countries.

 

At the BIOCAP Canada conference referred to earlier, another

poster pointed out that 45 of 56 wastewater treatment plants

in large urban areas of Ontario, Canada incorporate an

anaerobic digestion process to reduce the volume of

disposable sludge; but the methane produced is mostly wasted

by being flared off to the atmosphere. A conservative

estimate suggests that if all the wastewater sites were to

use anaerobic digesters and simply recover the methane to

generate electricity, this would produce 1.51 GWh/day [7].

It was a small percentage of the total of 317GWh consumed

each day in Ontario. But on average, 0.3kg of CO2 is emitted

per kWh energy produced from Ontario Power Generation, so

simply recovering the biogas energy from the current sites

using anaerobic digesters represents a saving of 432 tonnes

of CO2 per day.

 

Imagine what can be achieved if waste treatment were

optimised for hydrogen production.

 

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