The development of low carbon energy
sources
Filip Černoch
cernoch@mail.muni.cz
Decarbonization
• Politicaly driven, with the climate change reasoning.
• Specified goal, in search for suitable technologies - vs. previous energy transitions.
• Muscles + fire → draft animals → waterwheels and windmills → coal (oil, natural gas) → (coal)
electricity → ?
Life cycle CO2 equivalent of selected electricity supply
technologies
Technology Median Technology Median
Coal 820 Geothermal 38
Biomass co-fired
with coal
740 Concentrated solar
power
27
Gas – combined
cycle
490 Hydropower 24
Biomass – dedicated 230 Wind offshore 12
Solar PV – utility
scale
48 Nuclear 12
Solar PV – rooftop 41 Wind onshore 11
Arranged by decreasing median values. In gCO2eq/kWh
Energy investments in selected regions, 2015 and 2018
Investments in power generation, 2018
Overnight construction costs (OCC) in 2015USD/kW, USA
(left) and France (right)
Learning curve
• Decreasing costs due to:
• Research and development itself.
• Learning by doing – a byproduct of manufacturing and deployment, with
companies incrementaly improving industrial operations, installation procedures,
sales, and financing processes.
• Economy of scale – companies and industries getting larger, spreading some
fixed costs over a larger volume of product sales.
• Learning by waiting – harnessing the spillover effect from other industries,
technologies, or countries.
Learning curve
Construction duration, USA and France
OCC of global nuclear reactors in USD2010
Experience curve of USA/Fr NPPs
Distribution of construction
overrun costs by technology
• 401 electricity infrastructure projects
build between 1936 and 2014 in 57
countries.
• USD 820 bn. worth of investments,
323 515 MW of installed capacity, and
8495km of transmission lines.
LCOE for base load technologies, at different discount
rates
NPP in the EU in progress
• Flamanville NPP – construction started in 2007, with schedulled commissioning in
2012 and planned costs €3,3bn. Last information (from 2015) – commissioning in
2022 for €10,5bn.
• Olkiluoto NPP – construction started in 2005, with schedulled commissioning in
2010 and planned costs of €3bn. Commissioning expected in 2020 for €8,5-10bn+.
• Mochovce NPP – construction re-started in 2009, with schedulled commissioning in
2012 and 2013 and planned costs of €2,775bn. Commissioning expected in 2020 and
2021 for €3,8bn.
16
Strongly
positive
Positive Neutral Rather
negative
Strongly
negative
Finland UK Luxemburg Greece Ireland
France The Netherlands Denmark Sweden Germany
Slovakia Estonia Belgium Austria
Romania Portugal Italy
Bulgaria Poland - Latvia Malta
The Czech
Republic
Slovenia - Lithuania Cyprus
Hungary Spain -
- -
Nuclear phase-outs
• Austria – 1997
• Germany – 2011
• Italy – 1987 (after Chernobyl)
• Sweden - 1980 (after Three Mile Island), renounced in 2010.
• New Zealand – 1987
• …
• …
Position of nuclear in the EU
• Liberalized market emphasizes less risky and shorter investments.
• Limited role of the governments in energy.
• Public scepticims on the nuclear technology.
• Pricing of elektricity not able to valuate the reliability and predictability of sources.
• European companies (AREVA/EdF) absent in global investments.
• Vs. some investment in developing world.
Global PV module
price trends 2009-
2016
Global PV module
price trends 2009-
2016
Total installed costs of onshore wind by country 1983-
2014
Global levelised costs of electricity from utility-scale RES
technologies, 2010 - 2018
LCOE for base load technologies, at different discount
rates
LCOE for RES technologies, at different discount rates
LCOE vs. variable elektricity household tariff
Ownership of global power generation capacity
commissioned in 2015
Ownership of installed RE capacity in Germany (2012)
RES position in the EU
• Smaller unit costs, mechanisms driving prices down (auctioning).
• Positive, albeit changing public acceptance.
• Prosumers.
• Current price mechanisms not capable to accomodate RES.
• Support mechanisms in line with the EU rules.
• Cannibalization of price
• Intermittent production.
Discussion
• Future of nuclear sources?
• Future of RES?
• Other options?
Sources
• Sovacool, B.K.; Gilbert, A.; Nugent, D. (2014): An international comparative assessment of
construction cost overruns for electricity infrastructure.
• Lovering, J.R.; Yip, A.; Nordhaus, T.(2016): Historical construction costs of global nuclear
power reactors.
• Suna, D.; Resch, G.(2016): Is nuclear economical in comparison to renewables?
• Khatib, H.(2016): A review of the IEA/NEA projeted costs of electricity – 2015 edition.
• Hall, S.; Foxon, T.J.; Bolton, R.:(2016): Financing the civic energy sector: How financial
institutions affect ownership models in Germany and the United Kingdom.
• IRENA (2019): Renewable Power Generation Costs in 2018.
• O´Connor, P. (2016): What is the learning Curve – and What Does it Means for Solar Power
and for Electrict Vehicles?
• IEA (2019): World Energy Investment 2019
• IEA (2019): Renewables 2019: Analysis and forecast to 2024