Field Trials, Schemes and Calls for Transparency: November Geoengineering Updates
by Anja Chalmin
Recent Geoengineering research activities
In mid-September, a US$ 110 million U.S. Federal Support Programme for CCUS1 was announced by the United States Department of Energy (US-DOE)’s Office of Fossil Energy. The funding opportunity is explained as “commitment to strengthening coal while protecting the environment”i. The federal programme consists of three pillars:
| Programme | Description |
Project sites |
Budget |
| 1 |
Conducts Front-End Engineering Design (FEED) studies for retrofitting post-combustion CO2 capture technology on five coal and four natural gas powered plants. |
9 plants |
US$ 55 M |
| 2 |
Formation of Regional Carbon Sequestration Partnerships (RCSP). Research and development (R&D) to foster and accelerate the deployment of new regional CCUS initiatives. |
4 regions |
US$ 20 M |
| 3 |
Assessment of: commercial-scale CO2 storage sites, CO2 capture technologies, and CO2 purification technologies. |
Not yet available |
US$ 35 M |
Table 1: Overview of the US-DOE US$ 110 million funding programme
Programme 2 is focussing on Regional Carbon Sequestration Partnerships (RCSP) and the four selected projects have been given the task to form regional partnershipsii. However, most partnerships have been in place since 2003 and the programme may be better described as continued financing for such RCSPs as SECARB (Southeast Regional Carbon Utilization & Storage Partnership) or PCOR (Plains Carbon Dioxide Reduction Partnership)iii.
The FEED studies in programme 1 are expected to provide data on the deployment of different CO2-capture technologies and their economic viability.
Among the project sites is the Elk Hills Power Plant, a natural gas-fired plant, located in Kern County, California. The California Resources Corporation, the owner of Elk Hills, plans to capture 75% of the emitted CO2 by retrofitting the plant with post-combustion CO2 capture technology and suggests delivering the captured CO2 for Enhanced Oil Recovery (EOR). Elk Hills has seen similar plans in the past: The Hydrogen Energy California Project intended to capture CO2 at the plant and to transport it via a pipeline for EOR. The project was cancelled in 2016, because it failed to find customers for the captured CO2.
Another project site, Project Tundra at the 705 MW Milton R. Young plant in North Dakota, received the second seven-figure federal grant for studies on retrofitting the coal-fired plant with a post-combustion CO2 capture system. In 2018, the US-DOE supported the determination of costs, the design and the testing of a carbon capture retrofit at the plant with US$ 6 million. In 2019, the US-DOE announced US$ 9.8 million of funding; additional US$ 15 million will be provided by the North Dakota’s Lignite Research Fund. Project Tundra intends to capture 95% of the emitted CO2 and would involve an investment of US$ 1 billioniv. Information on how the financing of the US$ 1 billion investment may be ensured is not available.
|
Case studies |
Costs per MW |
Costs for 705 MW |
|
Costs for carbon capture: Project Tundra aims to invest US$ 1 billion in CO2 capture technology at Milton R. Young, a 705 MW plant. |
US$ 1.14 million |
US$ 1,00 billion |
|
Costs for onshore wind: In 2017, the 2 GW Wind Catcher onshore wind park in Texas was financed at US$ 2.9 billion. |
US$ 1.45 million |
US$ 1.02 billion |
|
Costs for offshore wind: In 2017, average investment costs for offshore wind were at US$ 3.7 million per MW. |
US$ 3.7 million |
US$ 2.61 billion |
Table 2: Investment comparisonv
The proposed US$ 1 billion investment in carbon capture technology for Project Tundra should be critically scrutinised for economic reasons relative to investments in emissions reductions and renewable energy. It also raises major concerns for the following reasons:
-
The
extraction process and transportation of coal creates additional CO2
emissions; -
More
coal is burnt – and additional pollution caused – to
fuel the energy-intensive CO2-capture
process; -
The
negative public health effects of coal would be ongoingvi.
Considering
these extra costs and emissions, a US$ 1 billion investment
in renewable energy seems a much more effective tool to reduce CO2
emissions compared to the proposed carbon capture solution.
The US-DOEs “commitment
to strengthening coal while protecting the environment“
does not sufficiently clarify the fate of the captured CO2:
CCUS does not effectively remove and store CO2.
For example, if CO2
is used to produce synthetic fuel, the CO2
will be released back to the atmosphere as soon the product is
consumed. The effectiveness of storing CO2
underground or using it for EOR has been broadly questioned due
to the risk of CO2-leakages
or the further increase in production of crude oil (and CO2)vii.
A few days after the US-DOE announcement, the Canadian Pacific Institute for Climate Solutions (PICS) announced CAD 1.5 million of funding for a four-year project named “Solid Carbon: A Climate Mitigation Partnership Advancing Stable Negative Emissions”viii. The project plans to design a floating platform that would capture CO2 from ambient air and inject it beneath the seafloor for CO2 sequestration. The project is headed by Ocean Networks Canada (ONC), an initiative founded by the University of Victoria (BC). The project partners include research institutions from Canada, the USA and Germany. In addition, the Texas-based K&M Technology Group will contribute oil and gas drilling expertise, and Carbon Engineering its Direct Air Capture (DAC) technology.
|
Table 3: Comparing energy use efficiency |
| 1.311 kWh can serve: • to capture 1 tonne of CO2 with Carbon Engineering’s DAC technology • to complete more than 650 load of laundry • to cover domestic energy consumption of an individual in British Columbia for over 1.5 monthsix |
The
Canadian start-up Carbon
Engineering Ltd.
was founded by David Keith (Harvard University) and is
based in British Columbia. The company’s CO2 capture
technology uses a strong hydroxide solution as a chemical sorbent.
According to a paper, published by David Keithx
in 2018, the CO2 capture
and separation process alone needs 1.311 kWh per tonne of CO2.
This figure does not yet take into account additional energy
requirements, e.g. the compression of CO2
and
pumping it through a 2.7 km pipe beneath the seafloor.
The
research partnership plans to deliver a demonstration project in the
Cascadia Basin, off the shore of Vancouver Island, in 2025 and has
started to look for investors. The project’s long-term goal is to
produce a large fleet of floating platforms by 2050. This concept
requires adding large structures to the ocean which could cause
issues for marine life, shipping and fisheries. The energy
requirement would be enormous; the entire annual domestic energy
consumption in British Columbia would be required to capture and
separate 35 million tonnes of CO2,
excluding the energy required to compress and pump it beneath the
seafloor. Moreover, the question of the fate of the CO2
must be asked: Leaking pipes or leaking CO2
from the seafloor will further aggravate ocean acidification.
The
Canadian Government announced the project “Carbon
Capture, Utilization and Storage in Mine Tailings”.
The objective of the project is to mineralize CO2
in silicate-rich mine tailings, e.g. in tailings from nickel,
diamond, or platinum mining. The research programme is led by the
University of British Columbia and involves field trials at
two Canadian mines: Trials in the Gahcho Kué
Diamond Mine,
owned by the De Beers Group and situated in the Northwest
Territories, will focus on capturing CO2
from flue gases produced by the mine’s power plant. The FPX Nickel
Corporation
owns and operates three nickel mines in north-western British
Columbia. One of the sites will be selected for trials, capturing CO2
from ambient airxi.
Call
for more transparency in geoengineering research
Last
month, the European
Geothermal Emission Control Project (GECO)
was celebrating its 1st birthday.
The research programme is based upon the European CarbFix
project at the Hellisheidi Geothermal Power Plant, nearby Reykjavik,
Iceland. Since 2012, Hellisheidi is used as a pilot site for
capturing CO2
and H2S.
The captured gases are injected into basaltic formations nearby the
plant, with the purpose of storing the gases in mineral form in the
bedrock. In 2018, a group of authors argued that the injections
at Hellisheidi led to induced seismic activityxii
– one of the risks associated with underground storage of CO2.
Nevertheless,
GECO aims to further advance the technology trialled at Hellisheidi,
in terms of costs, resource consumption, and purity of the
captured CO2.
The CarbFix technology will be established and tested at
four additional geothermal demonstration sites, each with a
distinct geology: Nesjavellier
plant in Iceland, Castelnuovo
in Italy, Kizildere
plant in Turkey, and the Ruhr Metropolitan Underground
Laboratory (TRUDI)
in Germany. Little information is available on detailed project
planning and the progress at the respective project locations –
even though the project is financed by EU taxpayers and has
been running since October 2018. The blog on the project website
is empty; the news section has rarely been updated. The GECO
demonstration sites also provide little information.
In 2009, Members of the Oxford Geoengineering Programme at the University of Oxford proposed a set of principles for the governance of geoengineering, the so-called “Oxford Principles”.
Principle three
has not yet been implemented by the GECO project. The situation is
similar for further Geoengineering programmes, for example for the
projects Greenhouse
Gas Removal by Enhanced Weathering (GGREW)
and Greenhouse
Gas Removal Instruments & Policies Project (GRIP).
GRIP
was carried out at the University of Oxford and looked into policy
issues related to carbon capture, enhanced weathering, and natural
carbon sinks. The duration of the project was from 2016 to 2019; to
date, the results of the project are not readily available to the
publicxiv.
GGREW
has been running since 2017 and is also carried out at the
University of Oxford, in cooperation with partner universities in UK.
The project aims to explore the technological, environmental,
economic and social feasibility of enhanced weathering in oceans. The
project activities include research, modelling, laboratory
experiments in Oxford and Israel, and field experimentsxv.
A detailed research plan is not available, although more than half of
the project duration has passed.
Recent proposals for shading the Great Barrier Reef
The
Great
Barrier Reef Foundation
refers to the Great Barrier Reef as the rainforest of the sea,
because it is home to many species. The foundations’ annual working
plan 2019/2020 is a reef protection programme to reduce the
impact of and adapt to climate change and local stresses. The
programme encompasses an environmental assessment and a proof of
concept phase for decreasing solar radiation on reefs. The assessment
includes technical, environmental and regulatory considerations and
will consider shading the reef through clouds, mist, fog, or surface
films. The project’s budget to date is AUD 1.6 millionxvi.
A
collaboration between the University of Melbourne, the Australian
Institute of Marine Science and the Great Barrier Reef Foundation
developed a Floating
Sunscreen.
The surface film consists of calcium carbonate and is designed to sit
at the water surface, directly above the reef. Researchers at the
Sydney Institute of Marine Science have suggested Marine
Cloud Brightening above the Great Barrier Reef
as a protection measure for the reef. The German company
gM-Engineering has recently proposed a trial with Iron
Salt Aerosols
in the Bass Strait, north of Tasmania. The approach combines marine
cloud brightening and ocean fertilization. The company is presently
looking for sponsors to fund the trial.
Further updates on new and ongoing geoengineering initiatives
The
UAE
Rain Enhancement Programme
was established back in 1983. The National Centre of
Meteorology (NCM) is the responsible governmental body for cloud
seeding activities in the United Arab Emirates. Recently, NCM
conducted a new test campaign: airborne cloud seeding was carried out
with salt crystals, coated with a titanium dioxide nanoparticle
layer. The research aircraft based at Al Ain airport have
conducted flights over the Northern and Eastern parts of UAE.
The
Australia-based Ocean
Nourishment Foundation Ltd (ONF)
announced plans to fertilize the ocean in Moroccan waters. ONF states
that the addition of nutrients has been discussed with local
fisherman and that ONF is “about to demonstrate to the fishermen of
El
Jadida
in Morocco the techniques of injecting new nutrients into surface
waters of the deep oceans”.
The Gorgon
CCS Project
on Barrow Island, Australia, started injecting CO2
in the Dupuy Formation, a saline aquifer. The commissioning of the
CCS project was several times delayed due to technical problems.
The natural gas plant emits annually up to 10 million tons of
CO2;
the CCS project aims to reduce the amount of emitted CO2 to
6 million tons per year.
The
Northern
Lights CCS Project,
carried out by Equinor (former Statoil), Shell and Total, intends to
transport captured and liquefied CO2
over 700km by ship from Oslo area to a hub nearby Equinor’s
Kollsnes plant. From Kollsnes the CO2
will be sent offshore by a 110km pipeline and injected into a
depleted well in the Johansen formation (Norwegian sector of the
North Sea, about 30km off the shore of Norway). In September, Equinor
signed preliminary Memoranda of Understanding for handling the
captured CO2
with seven potential industrial
partners: Air Liquide,
Arcelor Mittal, Ervia, Fortum Oyj, HeidelbergCement AG,
Preem, and Stockholm Exergi.
The Swiss
Climeworks AG
announced its merger with Antecy B.V. The Dutch company
develops CO2
capture and DAC technology.
SINTEF, a
Norwegian research organization, and C-Capture, a
spinoff from the department of chemistry at the University of Leeds,
announced a six-month collaboration at SINTEFs Tiller
research facility.
C-Capture will send its carbon capture technology to the Tiller plant
in order to validate its solvent by comparative analysis with
alternative carbon capture approaches.
The
Canadian company CarbonCure
Technologies Inc.
formed partnerships with concrete producers in Hawaii, for example
HC&D Ready Mix, and with Linde, a large industrial gas
supplier. CarbonCure provides technology to existing concrete plants
that allows producers to inject captured CO2
into wet concrete while it’s being mixed. According to CarbonCure,
the CO2
forms a mineral with calcium ions and remains captured in the
concrete. The new partnerships aim to introduce the CarbonCure
technology to new countries in Europe and Asia.
Yale University
announced the foundation of the Carbon
Offset Laboratory (COLab).
The new laboratory will focus on the development of technologies,
such as reduction of greenhouse gas emissions, carbon storage, carbon
sequestration, and solar radiation management.
A
Chinese government delegation, led by the Chinese Ministry of Ecology
and Environment, studied CCS in Australiaxvii.
The delegation visited various CCS projects, among them the
Global CCS Institute
in Melbourne and the PICA project
at the Loy Yang plant.
PICA was established in 2008 and is testing post-combustion CO2
capture technologies.
Resources
for further information:
Geoengineering Monitor: http://www.geoengineeringmonitor.org/ – information
and background on climate geoengineering technologies, research,
experimentation and implications
Interactive Geoengineering Map: https://map.geoengineeringmonitor.org/ – contains details and references for the above mentioned (highlighted in bold characters) and further climate geoengineering projects.
References
1
Carbon Capture, Utilization and Storage
i
US-Department of Energy (September 13, 2019):
U.S. Department of Energy Announces $110M for Carbon Capture,
Utilization and Storage. Link:
https://www.energy.gov/articles/us-department-energy-announces-110m-carbon-capture-utilization-and-storage
ii
US-Department of Energy (accessed: October 22, 2019):
FOA 2000: Regional Initiative to Accelerate CCUS
Deployment. Link:
https://www.energy.gov/fe/foa-2000-regional-initiative-accelerate-ccus-deployment
iii
MRCSP (May 2016): Regional Carbon Sequestration
Partnerships. Link:
https://irp-cdn.multiscreensite.com/5b322158/files/uploaded/pjcAZKYFTtGktS7eYNxF_03_MRCSP_Regional%20Carbon%20Sequestration%20Partnerships.pdf
iv
Project Tundra (accessed October 22, 2019):
Project Website. Link: https://www.projecttundrand.com/
v
Frankfurt School – United Nations Environment Programme
Collaborating Centre (2018): Global trends in renewable energy
investment 2018. Link:
https://europa.eu/capacity4dev/unep/documents/global-trends-renewable-energy-investment-2018
(page 50)
vi
James Conca, in Forbes (November 5, 2015): Choking
Our Health Care System With Coal. Link:
https://www.forbes.com/sites/jamesconca/2015/11/05/choking-our-health-care-system-with-coal/#520c5ffd6de4
vii
Geoengineering Monitor (May 22, 2018): Carbon Capture
Use and Storage (Technology Factsheet). Link:
http://www.geoengineeringmonitor.org/2018/05/carbon-capture-use-and-storage/
viii
University of Victoria (September 26, 2019):
Rock-solid climate solutions: Negative emissions technology. Link:
https://www.uvic.ca/news/topics/2019+solid-carbon-partnership+media-release
ix
Canadian Geographic (accessed October 22, 2019):
Energy use in Canada. Link:
http://maps.canadiangeographic.ca/energy-use-in-canada/
x
David W. Keith, et al., in Joule (June 7,
2018): A Process for Capturing CO2
from the Atmosphere. Link:
https://www.cell.com/joule/fulltext/S2542-4351(18)30225-3
xi
University of British Columbia (July 23, 2019): UBC-led
project combats emissions by locking carbon dioxide in mine waste.
Link:
https://science.ubc.ca/news/ubc-led-project-combats-emissions-locking-carbon-dioxide-mine-waste-%C2%A0
xii
D. Juncu, et al., Journal of Volcanology and Geothermal
Research (2018): Injection-induced surface deformation and
seismicity at the Hellisheidi geothermal field, Iceland. Link:
https://www.sciencedirect.com/science/article/pii/S0377027317304080
xiii
Oxford Geoengineering Programme at Oxford University (accessed
October 22, 2019): Oxford Principles. Link:
http://www.geoengineering.ox.ac.uk/www.geoengineering.ox.ac.uk/oxford-principles/principles/
xiv
Oxford University (accessed October 22, 2019): Greenhouse
Gas Removal Instruments & Policies Project (GRIP). Link:
https://www.insis.ox.ac.uk/greenhouse-gas-removal-instruments-policies-project-grip
xv
Oxford University (accessed October 22, 2019): GGREW.
Link:
https://www.insis.ox.ac.uk/greenhouse-gas-removal-instruments-policies-project-grip;
Oxford University (accessed October 22, 2019): Project
description by research staff. Link:
https://www.earth.ox.ac.uk/people/sophiejgill/
xvi
Great Barrier Reef Foundation (2019): Annual Work
Plan 2019-2020. Link:
https://www.barrierreef.org/science-with-impact/reef-partnership,
https://www.barrierreef.org/uploads/RTP_Annual%20Work%20Plan%202019-2020_FINAL.pdf
xvii
Global CCS Institute (August 2, 2019): Chinese government
delegation visits Australia to learn from CCS experience. Link:
https://www.globalccsinstitute.com/news-media/latest-news/chinese-government-delegation-visits-australia-to-learn-from-ccs-experience/