Paul O'Connor -- Bioecon -- improved pyrolsis of wood to oil
-- article, 2 patents

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**Paul O'CONNOR**

**Bio-Crude Oil**

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**<http://www.technologyreview.com/Energy/19694/page2/>** **Friday, November 09, 2007****

**Oil from Woo****by Erika Jonietz**

***Startup Kior has developed a process for creating
"biocrude" directly from biomass.***
**Dutch biofuels startup Bioecon and Khosla
Ventures have launched a joint venture called Kior, which
will commercialize Bioecon's process for converting
agricultural waste directly into "biocrude," a mixture of
small hydrocarbon molecules that can be processed into fuels
such as gasoline or diesel in existing oil refineries. The
process, Kior claims, boasts numerous advantages over other
methods of producing biofuels: it could prove relatively
cheap, relies on a nontoxic catalyst, taps into the present
fuel-refining and transportation infrastructure, and
produces clean-burning fuels that can be used in existing
engines.

Biofuels are widely seen as a key
stepping-stone on the path from fossil fuels to renewable
energy sources, particularly for transportation. Their use
could also reduce emissions of carbon dioxide and other
greenhouse gases. But ethanol, the most widely produced
biofuel, contains little energy compared with gasoline or
diesel. And a great deal of energy goes into its production:
growing the grain from which it is fermented, distilling it,
and transporting it. Many biofuels boosters have pinned
their hopes on finding ways to produce ethanol from
cellulose, the tough polymer that makes up much of plant
stems and wood. In practice, though, cellulose must be
broken down into simple sugars before it can be fermented
into ethanol or converted into synthetic gas and turned into
fuels. Despite three decades of research, these remain
difficult, expensive, and energy-intensive processes that
are not yet commercially viable. Additionally, recent
research shows that ethanol, which is highly volatile, may
actually exacerbate smog problems when it evaporates
directly into the air instead of burning in vehicle engines.

The way to make cellulosic biofuels viable,
says Bioecon's founder, Paul O'Connor, is to use catalysts
to convert biomass into a hydrocarbon biocrude that can be
processed into gasoline and diesel in existing petroleum
refineries. After decades developing catalysts for the
petroleum industry, O'Connor started Bioecon in early 2006
to develop methods for converting biomass directly into
biofuels. His first success is a catalytic process that can
convert cellulosic biomass into short-chain hydrocarbons
about six to thirteen carbon atoms long. Khosla Ventures
agreed to provide an undisclosed amount of series A funding
to spinoff Kior in order to commercialize the process. Vinod
Khosla, founder of the venture fund, believes that
converting biomass into liquid transportation fuels is key
to decreasing greenhouse-gas emissions and compensating for
dwindling petroleum reserves. Khosla is funding a number of
biofuels startups with competing technologies and says that
Kior's approach is unique. "They have some very clever
proprietary catalytic approaches that are pretty
compelling," he says. "They can produce relatively cheap
crude oi l --- that's attractive."

The most effective method of converting
biomass into fuel requires subjecting it to high
temperatures and high pressure to produce synthetic gas, or
syngas. In the presence of a catalyst, the syngas reacts to
produce fuels such as ethanol or methanol (used as an
additive in biodiesel). But this is a costly process that
often results in a product that is too low quality to be
used as fuel without further processing. And catalysts able
to withstand the high temperature of the syngas are
expensive and frequently toxic.

Attempts to produce fuel by directly exposing
agricultural cellulose to a catalyst have had little success
because most of the cellulose is trapped inside plant stems
and stalks. O'Connor says that while the Bioecon researchers
are developing new catalysts, their "biomass cracking"
process is the real breakthrough. Using proprietary methods,
they have been able to insert a catalyst inside the
structure of the biomass, improving the contact between the
materials and increasing the efficiency of the process.
While O'Connor won't go into details, he says that the most
basic version of the technique might involve impregnating
the biomass with a solution containing the catalyst; the
catalyst would then be recrystallized. "What we're doing now
is improving the method to make it easier and cheaper,"
O'Connor says.

Such a method would eliminate the need for the
superhigh temperatures and toxic catalysts used in other
thermochemical methods for cellulosic-biofuel production.
While O'Connor says that he is still improving Kior's
catalyst, his first versions are different kinds of modified
clays, which are both cheap and environmentally friendly.
The product is high quality as well, containing less acid,
oxygen, and water. These characteristics make it suitable
for burning as heating oil or for use in petroleum
refineries, which can use existing processes and equipment
to convert it into the longer hydrocarbon chains of gasoline
and diesel fuel.

Bioecon has produced lab-scale quantities of
its biocrude, a few grams at a time, from materials such as
wood shavings, sugarcane waste, and various grasses. While
the input material affects the yield somewhat, O'Connor says
that the output is "all very similar, so we do not have a
real preference." This means that the process can work
around the world, with whatever biomass is locally
available, almost year-round.

Kior is already in talks with at least two oil
companies to establish partnerships to further develop the
technology. It is starting a pilot plant with one company
that should produce around 20 kilograms of biocrude a day
within six to twelve months, says Kior CEO Rob van der Meij.
If all goes well, the process could scale up to production
of hundreds of kilos per day by 2009, and refined versions
of Kior's biocrude might be blended into gasoline or diesel
by 2010. In addition to being renewable, these fuels would
have lower sulfur and nitrogen content, which should
decrease smog in cities such as Los Angeles and Houston.

Because of its ability to slide into the
existing petroleum refining and delivery infrastructure, the
technology has a huge cost advantage, says O'Connor. It
could also be adopted much more rapidly, according to
Khosla. "If you can do a solution that's compatible with the
oil companies and their current refineries, it becomes much
easier for them to get comfortable with it," he says.
"Getting them into the game would be a big addition."

Steve Deutch, a senior research scientist at
the National Renewable Energy Laboratory, says that the
little information Kior has released about its process is
plausible enough, but that until the details are available,
the company's claims are "not really possible to evaluate."
The main challenge for Kior, or anyone working on cellulosic
fuels, Deutch says, is to develop a process simple enough to
bring close to the sources of biomass-farms. "Collecting
biomass and getting enough of it in one place to make a
difference is a problem in the biomass world," Deutch says.
"Trucking costs can become exorbitant. You want to
preprocess it at the farm and then ship a high-density,
high-energy intermediate to processing plants."

The answer is of course harvesting of seaweed.
You have huge refinary ships that process the seaweed
collected with smaller boats. You pump the ready fuel to
tankers and the waste products can be shipped as fertilizers
(?) Land can be used for more constructive things. e.g.
forests.

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**Hydrothermal Treatment of Carbon-Based Energy
Carrier Material**

**EP 1852493 [ [PDF](1852493.pdf)
]**   
**2007-11-07**

**Abstract ---** Disclosed is a
hydrothermal treatment process for conversion of a
carbon-based energy carrier material. The process comprises
a step for sensitizing or activating the carbon based energy
carrier material to increase its susceptibility to
hydrothermal conversion. As a result of the sensitization
step, the hydrothermal conversion step itself may be carried
out under relatively mild conditions. The process comprises
the steps of sensitizing the carbon-based energy carrier
material to increase its susceptibility to hydrothermal
conversion; and subjecting the sensitized carbon-based
energy carrier material to hydrothermal conversion at a
temperature of less than 300 degrees centigrade in a
hydrothermal treatment reactor.

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**Method of Making a Polymeric Material of
Photosynthetic Origin Comprising Particulate Inorganic
Material**

**EP 1852492 [ [PDF](1852492.pdf)
]**   
**2007-11-07**

**Abstract ---** Disclosed is a method of
making a polymeric material of photosynthetic origin
susceptible to defibrillation and/or depolymerization. The
method is particularly suitable for use in processes whereby
the polymeric material is converted to fuels in liquid or
gas form, and/or to valuable specialty chemicals. In a
specific embodiment, the polymeric material comprises
biomass, more specifically, the polymeric material comprises
cellulose and lignocellulose.

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**Mild Pyrolysis of Carbon-Based Energy Carrier
Material**

**EP 1852491 [ [PDF](1852491.pdf)
]**   
**2007-11-07**

**Abstract ---** Disclosed is a pyrolysis
process for conversion of carbon based energy carrier
material. The process comprises a step for sensitizing or
activating the carbon based energy carrier material to
increase its susceptibility to pyrolytic conversion. As a
result of the sensitization step, the pyrolysis step itself
may be carried out under relatively mild conditions. The
process comprises sensitizing the carbon-based energy
carrier material to increase its susceptibility to pyrolytic
conversion, and subjecting the sensitized carbon-based
energy carrier material to thermal conversion.

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**Pretreatment of Particulate Carbon-Based Energy
Carrier Material**

**EP 1852490 [ [PDF](1852490.pdf)
]**   
**2007-11-07**

**Abstract ---** Disclosed is a process for
pretreating a particulate carbon-based energy carrier
material. The pretreatment results in a sensitized energy
carrier material that is susceptible to conversion to a
liquid fuel under mild conditions.****---

**Polymeric material of Photosynthetic Origin
Comprising Particulate Inorganic Material**

**EP 1852466 [ [PDF](1852466.pdf)
]**

**Abstract** --- Disclosed is a new
composition of matter comprising a polymeric material of
photosynthetic origin having embedded therein small
particles of an inorganic material. The composition of
matter is particularly suitable for use in processes whereby
the polymeric material is converted to fuels in liquid or
gas form, and/or to the valuable specialty chemicals. In a
specific embodiment, the polymeric material comprises
biomass. More specifically, the polymeric material comprises
cellulose or lignocellulose.

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