Common Road to 2050 Energy Networks and Policy (ENP2050) UK ENERGY SCENARIOS A study at
August 14th, 2013 LONDON, UK Prepared by: Dr. Catalina Spataru
with contributions from:
Mr. Paul Drummond Dr. Mark Barrett Dr. Michael Emes
Table of Contents
1 Introduction .................................................................................................................................... 2 2 Review of Selected Studies ............................................................................................................. 3
2.1 GDP growth ............................................................................................................................. 4
2.2 Fuel prices ............................................................................................................................... 4
2.3 Electricity Demand Growth ..................................................................................................... 5
2.4 Conventional Fossil Fuel Generation ...................................................................................... 6
2.5 Nuclear Generation ................................................................................................................. 8
2.6 Renewable Electricity Generation .......................................................................................... 9
2.7 Electricity Generation ........................................................................................................... 10
2.8 Carbon Dioxide Emissions ..................................................................................................... 11
2.9 Conclusions ........................................................................................................................... 12
3 Overview of the current UK energy sector ................................................................................... 13 3.1 Primary Energy Consumption ............................................................................................... 13
3.2 Energy Consumption by Fuel ................................................................................................ 13
3.3 Electricity Mix in UK by Fuel .................................................................................................. 14
3.4 Primary Energy Production ................................................................................................... 15
3.5 Production versus Consumption ........................................................................................... 16
4 ‘ENP2050 Project’– Proposed Descriptive Scenarios .................................................................... 17 4.1 Scenario Objectives ............................................................................................................... 17
4.2 Main Future Transformations that Influence Scenarios Development ................................ 17
4.3 ‘ZORBA’ and ‘KALINKA’ scenarios ......................................................................................... 18
5 Key Policies Required by Energy Industries as a result of the Workshop ..................................... 21 6 Exploratory Scenarios Results using the ‘DECC 2050 Pathways Calculator’ ................................. 23
6.1 Modelling approach and assumptions .................................................................................. 23
6.2 Results ................................................................................................................................... 30
6.2.1 Energy and Electricity Demand ..................................................................................... 30
6.2.2 Primary Energy Supply .................................................................................................. 33
6.2.3 Electricity Supply ........................................................................................................... 34
6.2.4 GHG Emissions .............................................................................................................. 35
6.2.5 Energy Security ............................................................................................................. 37
6.2.6 Energy Flows in 2050 .................................................................................................... 37
7 Comparison between ‘Kalinka’ and ‘Zorba’ with Existing Scenarios ............................................ 39 8 Conclusions ................................................................................................................................... 43 9 References .................................................................................................................................... 45
1 Introduction
The development of a low-carbon energy system, coupled with security and reliability, is of crucial
importance if we are to provide deep emission cuts by 2050 to prevent dangerous anthropogenic
climate change. Grand challenges such as climate change mitigation and energy supply security
require substantial changes to current policy. Renewable energy supply and reduction in energy
consumption are essential, as more than half of the world’s population already lives and consumes
energy in cities. Moreover, there are different opportunities and benefits surrounding gas and
electricity. Gas networks store huge amounts of energy and react slowly over time to changes in
demand, whilst electricity networks require real-time responses and tariffs to reduce peak demand.
However, to enable consumers to optimize their energy use, various solutions like dual fuel-
electricity and gas appliances, biomethane and hydrogen injection into the gas grid, and use of
cogeneration should be considered as part of the technology mix; alongside significant integration of
‘conventional’ renewable energy. In addition, there are new possibilities to extract unconventional
fossil fuels such as shale gas, tight gas, coal bed methane, tight oil and shale oil. These challenges will
require tight coupling of different energy sources - nuclear, fossil, and renewable - to match energy
production and demand at any time, and to meet the challenging ‘sustainable’ ambition.
The aims of the ‘ENP2050 Project’ were to:
Analyse the role of different energy resources in order to reduce system costs and emissions
and further increase the proportion of renewable energy.
Review existing energy scenarios
Highlight challenges and propose a horizon time framework for action to manage various
resources integration.
Explore options which reduce carbon emissions and analyse potential feasible options for
energy system development
Discuss policies needed for different energy industries (gas, coal, oil, nuclear, wind and other
renewables industries), to enable different development trajectories
Objectives
The main objective of the ‘ENP2050’ Project is to produce a range of basic options for the
development of a low-carbon energy system in UK, and draw together an assessment of their
benefits and challenges from technical and policy perspectives. The approach considers only
technologies which currently exist on the market but not currently available or which are awaiting
large-scale deployment.
2 Review of Selected Studies
With the purpose of determining the background, assumptions, and outputs of scenarios produced
in previous studies for the development of the UK energy system, literature review was conducted.
This section summarises this review, and aims to highlight the similarities and differences between
these aspects in selected studies. Three studies which attempt to assess the future development of
the UK electricity system1 were selected for review: a study conducted by ILEX, one by the
Department for Trade and Industry (DTI), and one produced by Friends of Earth (FOE). All studies
were published in 2006, and all hold 2010 as an intermediate assessment horizon, allowing
projections to be assessed against actual values.
The ILEX and FOE studies both aim to evaluate development trajectories of the electricity system
under CO2 emissions constraints. The ILEX study also prohibits the construction of new nuclear
capacity in its investigation. The DTI study aims to evaluate the development of the energy system in
the UK as driven by various fuel price assumptions, based on the UK’s Climate Change Programme
(since replaced). Each study assesses multiple scenarios, which differ by aspects such as policy
assumptions, fuel prices and technological development. Table 1 summarises the key characteristics
of these three studies2, and the main differences are outlined in the sections bellow.
Table 1: Summary of the three comparison studies (ILEX, FOE, DTI)
1 DTI is the only study that examines the whole energy sector. The results compared in this report are based on
electricity. 2 See report for a more detailed description and evaluation of these studies
2.1 GDP growth
Assumptions for GDP growth are well matched between ILEX (2006) and DTI (2006) in which all
scenarios (unless explicitly stated), assume an annual economic growth rate of 2.55% from 2004 to
2015. The FOE study makes no reference to a GDP input. The World Bank states that the actual GDP
growth for the UK between 2004 and 2010 was 1.25%. There is clearly a large discrepancy between
these two values. A significant explanation for this is the global financial crisis that began in 2008,
which heavily impacted the UK economy. Such ‘shocks’ to the system are difficult, if not impossible
to predict and include in scenario design. Therefore, such ‘shocks’ can render the results of a
scenario application largely irrelevant. This is amplified with increasingly distant assessment
horizons.
2.2 Fuel prices
Fuel prices are a common input in both ILEX (2006) and DTI (2006) studies; however it is not
explicitly discussed in the FOE (2006) report, and thus cannot be assessed here. The general
assumptions taken by the studies were:
DTI-assumed that oil prices would remain as high as they were at the time of the study, with
variations tracked by the gas price. Coal prices were projected to fall slightly towards 2010 in
response to experienced investment in coal production resulting from high prices in 2005.
These assumptions are common in 2010 for all DTI scenarios (discussed below), with
increasing price divergence between scenarios occurring after this date.
ILEX- projections based on historic analyses and estimations for a rational balance between
gas and coal price differentials, common to all scenarios produced by this study.
Table 2 presents the fuel prices for the two ‘central’ fuel price scenarios in the DTI study (one
favourable towards gas, the other towards coal), and ILEX assumptions common to all scenarios.
Fuel prices in the ILEX study are much higher than DTI projected figures, in 2010. As the ILEX study
was published a few months later than the DTI Study, it is possible that the intervening significant
increase in fuel prices had altered the relative ‘baselines’ and trends, producing this discrepancy. The
ILEX study does not present a price for oil in 2010 as it is assumed no oil-based power generation by
this time.
Table 2: Fuel Prices Projections in ILEX and DTI (2006) reports for 2010
£/GJ DTI ILEX
Year:2010 Central (1) Central (2) Common
OIL 2.55 2.55 -
GAS 2.26 2.75 3.25
COAL 0.89 0.89 1.54
Figure 1 illustrates the data tabulated above, along with the actual data for 2010, as published by
(National grid, 2012) and (DECC, 2012c). It is clear that DTI projections for coal prices were highly
accurate, whilst ILEX projections were nearly double the actual price in 2010. However, ILEX
projections for gas prices were relatively close, along with the Central (2) DTI scenario.
Figure 1: Projected Fuel Prices Comparison for 2010
2.3 Electricity Demand Growth The rate of electricity demand growth may be determined endogenously in a model by using
factors such as GDP projections and demographic changes, or it may be applied as an exogenous
assumption. Figure 2 below, presents the electricity demand growth rates used until 2010 in the
three studies.
Figure 2: Electricity Demand Growth Rate Comparison
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Fuel Prices Comparison of 2006 studies with 2010 data
Gas Coal 2010 Data Gas 2010 Data Coal
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Electricity Demand Growth Comparison of 2006 studies with 2010 data
Figure 2 presents two values for the DTI study, ‘with measures’ and ‘without measures’. The two
‘central’ scenarios discussed for this study apply the ‘with measures’ value, calculated endogenously,
which assumes measures contained in the UK’s Climate Change Programme (as existed at the time),
were implemented and their targets achieved. The ‘without measures’ assumes this is not the case,
and applies to the ‘Business as Usual’ scenario. The ‘BAU’ scenario in the ILEX study uses the average
rate applied to the DTI’s ‘without measures’ scenario, at 1.15% annual demand growth (from 2011,
the DTI ‘without measures’ growth rate changes from 1.49% as illustrated in the graph, to 0.74%).
Similarly, ILEX’s ‘PS1’ scenario uses the average DTI estimation for the ‘with measures’ (0.44% p.a.),
with the ‘PS2’ scenario using a rate of 0.11% across the full assessment horizon (2004-2025). The
FOE report includes values for electricity demand that can be characterised as exogenous and they
were based on the ‘Performance and Innovation Unit’s 2003 report along with some additional
assumptions related to the implementation of new energy efficient technologies that affected their
results to some extent. This study distinguishes between its ‘good progress’ and ‘slow progress’
scenarios, however until 2010 the difference is negligible, both using a growth rate of around 0.43%.
2.4 Conventional Fossil Fuel Generation
Each study makes assumptions on when certain generation capacity will close, either because it
reaches its end of life, or due to policy considerations. The DTI study assumes the closure of 2 GW of
coal and 1 GW of other fossil fuel capacity (principally gas), between 2005 and 2010. This is the case
in all the scenarios included in the study, as a result of both end-of-life retirement and policies that
oblige reduction of the use of fossil fuels. The ILEX study assumes the closure of 14 GW of coal-fired
capacity by 2026, but does not present particular assumptions by 2010 (all scenarios), whilst the FOE
study assumed the continued operation of existing capacity with efficiency upgrades by 2010. In the
‘gas’ favoured FOE scenarios ( “good gas” , “slow gas”), the Drax coal-fired installation closes in 2018,
but this does not impact results at the 2010 projection horizon.
Figure 3 and Figure 4 present the coal and gas-fired power generation projections from these three
studies in 2010. The ‘maximum’ and ‘minimum’ values produced by the various scenarios within
each study are given. The FOE ‘Slow Progress’ and DTI Central ‘Favourable to Gas’ scenario, both
match very closely with what actually came to pass in 20103. DTI projects a decrease in coal
generation by 2010 from 2005 due to the retiring of coal-fired stations, and there is little variation in
their projections (probably arising from the limited variation between the scenarios in 2010). This is
also the case for the FOE scenarios. ILEX projections for coal consumption vary significantly, with the
‘maximum’ projection a result of ‘Business as Usual’, and the ‘minimum’ projection resulting from a
scenario (‘Policy Switch’ - Policy Delivered) which assumed all targets in 2010 for CO2 emissions
abatement and renewable penetration were met. In the ‘BAU’ scenario, low relative coal prices
incentivise its use to satisfy high energy demand, whereas the ‘Policy Switch’ scenarios assume
decreased electricity demand, and therefore decreased demand for coal consumption. This
explanation applies to the gas consumption variation in ILEX, displayed in Figure 4, in which the
‘BAU’ scenario projects the most accurate consumption profile, with 18% increase between 2005
3 2010 Data for electricity consumption by fuel taken from DECC 2012a. Electricity generation and supply
figures for Scotland, Wales, Northern Ireland and England, 2008 to 2011. Departmenet of Energy and Climate Change.
and 2010. The DTI and FOE studies again produce little variation (for the same reasons), and are
both significantly below actual consumption.
Figure 3: Projected Coal Generation Comparison for 2010
Figure 4: Projected Gas Generation Comparison for 2010
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2.5 Nuclear Generation
The ILEX study assumes the closure of nuclear installations as per 2006 expectations (licence
expirations, etc.) as presented in Table 3. By 2010, this equals a closure of 1.389 GW of nuclear
capacity. The DTI study makes similar, specific assumptions, whilst the FOE assumes a higher
reduction in capacity of around 2GW, in line with the DTI’s Energy Paper 684. The FOE also explicitly
states that no new nuclear capacity may be built.
Table 3: ILEX study – Nuclear Installation Assumed Dates of Retirement
Plant Type Capacity (MW) Closure date
Dungeness A Dungeness B Hartlepool Heysham 1 Heysham 2 Hinkley Point B Hunterston B Oldsbury Sizewell A Sizewell B Tomess Wylfa
Magnox AGR AGR AGR AGR AGR AGR Magnox Magnox PWR AGR Magnox
444 1,070 1,207 1,165 1,322 1,297 1,238 475 470
1,220 1,270 1,082
2006 2018 2014 2014 2023 2011 2011 2008 2006 2035 2023 2010
Figure 5 illustrates the maximum projected electricity generated from nuclear in 2010, for the three
studies compared with actual data from the UK government (DECC, 2012a). The FOE study has
proven the most accurate projection at around 60TWh, although there is little variation between the
three studies (and indeed, little if any difference between scenarios within each study). This is to be
expected, as decommissioning dates for existing plants were known, no new capacity was planned
and therefore extremely unlikely to come online by 2010, and fuel prices do not vary (in the same
manner as fossil fuel). The small difference experienced is a result of other factors such as total
electricity demand, for example.
4Source: http://webarchive.nationalarchives.gov.uk/+/http://www.dti.gov.uk/files/file11257.pdf
Figure 5: Projected Nuclear Generation Comparison for 2010
2.6 Renewable Electricity Generation
DTI projected that renewables will be the only energy source with rapid development until 2010,
stating that "the Government is committed to ensuring that the contribution from renewables
increases over time". This statement is consistent with the other two studies as well. The ILEX study
refers to the Renewable Obligation (Ofgem, 2013) as the key driver of the RES installation, whilst
FOE mentions that: “We believe that the growing public awareness and concern about climate
change is likely to result in increasing public support for the speedy deployment of
renewable schemes of all types".
Figure 6 illustrates the maximum and minimum projected electricity generated from renewables in
2010, produced by the various scenarios in each study. According to the previous statements, all
scenarios in the three studies project an increase in the penetration of renewables into the
electricity market, to different degrees. Both DTI and FOE display little difference between their own
scenarios, and between each other, each projecting around 33 TWh of renewable generation in
2010. This is well above the actual value of just over 25TWh (DECC, 2012a). Only the ILEX ‘Business
as Usual’ projection accurately matches actual 2010 renewable generation, whilst the ‘Policy Switch
– Policy Evolution’ scenario projected over 40TWh generation, under conditions of additional policy
instruments.
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Figure 6: Projected Renewables Generation Comparison for 2010
2.7 Electricity Generation Figure 7 presents the ‘maximum’ and ‘minimum’ electricity generation projections for 2010 from the
three studies, along with the actual generation in 2010. The FOE projections are by far the highest at
around 410TWh, well above the 382TWh actually generated in 2010 (BP, 2013). There is also very
little discrepancy within the study itself, as demand growth is uniform between the scenarios. It is
likely that the 2008 economic crisis and the drop in electricity demand are responsible for this
difference. The ‘Power Switch – Policy Evolution’ scenario in the ILEX study produces the most
accurate projection, around 25 TWh lower than its ‘Business as Usual’ projection. The ‘Policy
Evolution’ scenario assumes the application and achievement of new (as of 2006), ambitious targets
and policies, above those that were already in place or announced. This is an ambitious trajectory
that was not achieved, and it is again probable that the financial crisis was the cause of this
apparently ‘successful’ result. The DTI scenarios project 2010 electricity consumption well below
what came to pass. One reason for this divergence between DTI and the other two studies is possibly
the amount of electricity imports and combined heat and power capacity (CHP) not included in the
DTI study. Additionally, DTI results are based only on the "with measures" electricity
growth assumption and on the Climate Change Programme which acts to reduce electricity demand.
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Figure 7: Projected Total Electricity Generation Comparison for 2010
2.8 Carbon Dioxide Emissions
Figure 19 8 presents the ‘maximum’ and ‘minimum’ CO2 emissions from the power sector produced
by the three studies. The FOE projected emissions are the highest, and well above actual emissions
in 2010 taken from DECC (2013) (although again, with little divergence between the maximum and
minimum projections – resulting from ‘slow coal’ and ‘good gas’ scenarios, respectively). This is
largely a function of demand illustrated in Figure 2. However, this does not necessarily follow for the
DTI and ILEX studies, in which the latter projects lower emissions in 2010 in all cases, despite much
higher electricity demand across the board. This stems from higher nuclear and renewables
generation over the DTI scenarios, along with a preference for gas over coal – especially in the
‘Policy Switch – Policy Delivered’ scenario. The assumption of more efficient generation also
contributes to this trend. In that sense, the DTI study, constrained by CO2 targets (CC Programme),
matches actual CO2 emissions most closely.
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Figure 8: Project CO2 Emissions from Electricity Generation Comparison for 2010
2.9 Conclusions
This relatively brief, high-level analysis of three similar studies, conducted at similar times and with a
very close assessment horizon (2006 to 2010), highlights the significant differences among input
values (e.g. GDP growth projections), calculation methodology and the subsequent production of
highly varied results (e.g. CO2 emissions) that are reasonably possible. It was discovered through the
evaluation of their assumptions and results that DTI and ILEX are rather similar, as they present
comparable assumptions based on similar sources. Whilst many of the scenarios examined are not
what the authors would necessarily expect to happen (e.g. Business as Usual, or ambitious additional
policy), the relatively close assessment horizon might lead to the expectation of relatively accurate
projections with only small variations between studies and scenarios, pivoting around the eventual
actual outcome. This highlights another important weakness related to the projection of future
developments. The financial crisis lead to a significant drop in energy demand (especially electricity),
amongst other things, which is extremely difficult, if not impossible to account for in projections-
produced before the fact. This will have rendered many assumptions and subsequent outputs
irrelevant. Care must then always be taken to develop future scenarios, and interpretation of their
assessments, with such things in mind.
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CO2 Emissions from Power Sector Comparison of 2006 studies with 2010 data
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3 Overview of the current UK energy sector
The targets and modifications established over the last two decades through policies such as: UK’s
Kyoto Protocol, the 2008 ‘Climate Change Act’, along with economic differentiations such as changes
in fuel prices, have affected the various energy trends in the UK.
3.1 Primary Energy Consumption
According to the UK Government statistics, presented in Figure 9, between 1990 to 2001 energy
consumption was constantly growing, following economic growth. Since 2004 however, there has
been a consistent decline in energy consumption. In 2011 overall UK primary energy consumption
was 209.6 Mtoe, 1.7% below 2010 levels. Such a low level has not been reached since 1984. The
decreased energy consumption since 2007 reflects a considerably reduced UK GDP growth between
2007 and 2009, maybe due to the recession. However, environmental policies introduced since the
year 2000 in particular, have also contributed to energy generation and demand reduction.
Figure 9: Primary Energy Consumption (1990-2011) (Source: DECC (2012b))
3.2 Energy Consumption by Fuel
Figure 10 shows no considerable changes in the UK’s energy supply profile, aside from a progressive
penetration of renewables, mainly observed after 2008. Oil and gas remain the principal sources for
transportation and heating (amongst others), respectively, whilst the use of coal over the time tends
towards minimal consumption in the context of overall primary energy consumption.
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Figure 10: Total Primary Energy Consumption by fuel, UK (1990-2011) (Source:DECC (2012b))
3.3 Electricity Mix in UK by Fuel The last 20 years experienced high industrialisation powered by the electricity sector, which is
dominated by fossil fuels. Between 1990 and 2000 a number of significant transformations occurred
in the UK’s electricity generation profile. The use of solid fuels decreased and natural gas became an
important player fuel as illustrated in Figure 11. Gas participated by 45% in the electricity
consumption and represented 41% of the entire energy consumption in the UK (primarily through its
dominance as a heating fuel, in addition to electricity generation). The share of renewables in the
electricity sector accounts for 8.7% of the final consumption by 2011, a significant growth since
2000.
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Figure 11: Fuel input for Electricity Consumption in UK for milestone dates (1990, 2000, 2011)
(Source: DECC (2012d))
3.4 Primary Energy Production
Total production of primary fuels in the UK has been experiencing a constant decrease since 2002
(49% reduction in 2011 compared to 2002), as shown in Figure 12. The highest peak was recorded in
1999 for total energy production (and for petroleum as an individual fuel), whilst domestic
production of natural gas peaked in 2000. The key reasons for subsequent decreases, particularly for
petrol and gas, are the reducing North Sea oil and gas reserves, and several maintenance issues that
occurred, forcing a reduction in oil and gas recovery. The latest statistics for 2011 show that overall,
fossil fuels account for 83% of total domestic production while primary electricity (consisting of
nuclear, wind and natural flow hydro) accounts for 13%. As presented in the following figure it is
evident that there was a boost of 60% in wind energy between 2006 and 2011. This is a trend
projected to increase further over the next years.
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Figure 12: Annual Indigenous Production of Fuels in UK (1995-2011) (Sources: DECC (2012b), UK Goverment (2013), UK Goverment (2013))
3.5 Production versus Consumption
A comparison between domestic energy production and consumption in the UK from 1990 to 2011 is
provided in Figure 13. In 1990 the levels of production and consumption were roughly the same
(around 220Mtoe). From 1990 to 2004, UK energy production was larger than consumption, making
it possible for the UK to export energy to other European markets, whilst providing domestic energy
security. After 2004 however, although consumption did not record any increase, the levels of UK
energy production were reduced significantly, requiring the UK to increase its reliance on energy
imports.
Figure 13: Total Primary Energy Production and Consumption in the UK from 1990 to 2011 (Sources:DECC (2012b), UK Goverment (2013))
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4 ‘ENP2050 Project’– Proposed Descriptive Scenarios
4.1 Scenario Objectives
The aim of these scenarios is to describe a vision of the UK between 2020 and 2050 by exploring
energy trends’ fluctuations through the time. These scenarios are designed to help a range of
stakeholders to address the ‘Energy Trilemma’ of achieving environmental sustainability, energy
security and social equity. Regarding Energy Trilemma please see the World Energy Council report
and website.
Figure 14: The Energy Trilemma angle (Source: World Energy Council (2012))
We need to balance the 3 challenges of energy supply reliability, energy affordability and climate
change, and there are increasing demands and targets on all three aspects. According to the World
Energy Council (WEC) report (2012) on the ‘Energy Trilemma’, United Kingdom in 2012 had rank 15
in the energy sustainability index, which was higher than in 2011 and 2010 (see Figure 14). According
to the WEC analysis, the improvement in the rank was due to an improved performance across all
dimensions. Energy security scores increased substantially, due to an increase in the wholesale
margin of gasoline and diversity of electricity production. Lower emissions from electricity and heat
generation conducted to improvements in environmental impact mitigation. Economic strength
decreases substantially due to less credit availability and lower macroeconomic stability. The
analysis makes use of the following energy performance dimensions: energy security, social equity,
environmental impact mitigation and of the following contextual performance dimensions: political
strength, societal strength, economic strength. Information on Energy Trilemma, as well as results
and country profiles can be found on the World Energy Council (WEC) website at
www.worldenergy.org/data/sustainability-index.
4.2 Main Future Transformations that Influence Scenarios Development
Historically, the UK is a country that has relied on coal, nuclear and off-shore natural gas. Within this
context, we looked at the UK policies aiming to transform the current system. The existing UK energy
policies also aim to transform the current situation and are set out in the ‘Energy White Paper’, ‘Low
Carbon Transition Plan’, ‘Energy Bill’ and ‘Climate Change Act’. In the ‘Energy White Paper’, the
policy recognizes that UK will call for approximately 30-35 GW of new electricity generation capacity
over the next two decades. Moreover, the ‘UK Low carbon Transition Plan’ details the actions to be
taken to cut carbon emissions by 34% by 2020 (based on 1990 levels); while 40% of electricity will be
generated from low carbon sources. The ‘Energy Bill’ aims to close a number of coal and nuclear
power stations over the next decades’ and be replaced by renewable reaching 30% of electricity
share by 2020. A summary of the main targets for emissions for two milestone years 2030 and 2050
are included in the ‘Fourth Carbon Budget’ report proposed by the Committee on Climate Change
(2010) (60% reduction in 2030) and in the Climate Change Act imposing 80% reduction by 2050,
compared to 1990 emissions.
The UK’s Office of Gas and Electricity Markets (Ofgem), the UK’s energy regulator, mentioned that
the statistical probability of major power shortages in the UK could increase to about once in 12
years in 2015, from once in 47 years at present, as a result of closing power plants (especially coal
and nuclear). In the next decade a fifth of Britain’s existing capacity is scheduled to close (Wintour
and Inman, 2013). North Sea oil and gas is in decline, and the global market for these products is
volatile and extensive (Simms (2013)). Recently the Government issued 197 new licenses for oil and
gas exploration in the North Sea, which is the largest number since 1967 (Adams, 2013). Shale gas is
proposed as a major additional source of gas, potentially for decades. The exact potential is
unknown for geological, economic and environmental reasons. In June 2013, it was confirmed that
negotiations between the Government and the UK Onshore Operators Group had resulted in a new
industry charter. Its key provisions mean that if new gas is discovered, local communities could
receive financial benefits: £100,000 for every well that is fracked as part of exploration, and 1% of
revenues if things prove to be commercially viable (Harris, 2013). With all of these current facts and
plans working, as yin and yang, with opposing forces which both conflict and reinforce, giving rise to
each other as they interrelate to one another, we present two alternative scenarios for the
development of the UK energy system, a ‘cauldron of contradictions’ which will work together as
‘yin-yang’.
Part of the ENP2050 Project two scenarios and their steps for two pathways were proposed and
presented at the Common Road to 2050 Workshop in July 2013 (Spataru, 2013). A description of
these scenarios is provided in the next section 4.3.
4.3 ‘ZORBA’ and ‘KALINKA’ scenarios
‘Zorba’ (Zorba’s dance) is a Greek dance song that entered the popular imagination through, the
motion picture ‘Zorba the Greek’. In the Greek tradition, dance is considered as a ‘way of life’, an
authentic integration of mind, body and spirit.
‘Kalinka’ is a Russian song, with which has a speedy tempo, light-hearted and cheerful lyrics. It is
believed that the nature of the Russian dance comes from a need to stay warm during the long
winters. The dances accompanying the Kalinka are a series of varied steps depending on the
choreographer, the region and the company performing them.
We use these two iconic dances as a metaphoric basis for our proposed scenarios.
ZORBA: Predominant Renewables (with Storage) + Nuclear
Encourage long term energy security and promotion of environmental issues - need of a
rapid uptake of renewables.
Key driver: achieve environmental goals, a long term economic growth, with significant
investments by 2030 in low-carbon technologies (including energy storage), with significant
support and direction from the Government.
KALINKA: Predominant Fossil Fuels (with Carbon Capture and Storage (CCS))
Energy security and affordability as a short-term priority, prevents stress of immediate
technological revolution.
Key driver: recovering economic growth and meeting short term demand. Well known
technologies; but CCS not well known, with limited carbon reduction in short term.
Both in long term not clear which one will be the most affordable and secure.
We looked at a time horizon from the present to 2050. Until 2020 is a period full of uncertainties, by
2030 policymakers will need to devise, implement and commit to policies, towards 2040 everything
becomes clear and by 2050 we become green.
Within the ‘Energy Trilemma’, policymakers need to ask:
1. What are the main needs of the country?
2. What are the economic goals?
3. What industries do we need to support over the next 20 years?
4. Where are investments needed?
5. Which instruments will we choose to address needs?
We explored four steps for each scenario, in order to identify ways to address the future emission targets and evaluate energy security in the UK from now until 2050.
Table 4: Description of ‘Kalinka’ Steps
KALINKA – predominant fossil fuels Steps’ Description
2020 – The Black step Current system configuration with high investments in CCS R&D and lower in energy storage Nuclear still in use in low levels- some new nuclear power plants will be built
2030 – The Grey step CCS has been retrofitted to many existing gas-fired plants and included in all new gas-fired plants. Some of the existing power plants will be used along with many that will be replaced with new ones Use of efficient methods to extract fossil fuels Renewables are being installed with average rates Government provides and implements policy options to
2020 2030 2040 2050
support different industries5
2040 – The Blue step CCS established mostly in new power plants Higher proportion of renewables Use of renewables to produce Hydrogen Peak-load electricity back-up provided by fossil fuels Most of the existing nuclear plants are improved plus use of new power plants Use of geosequestration in low levels
2050 – The Green step Predominant use of Hydrogen (from renewables) in transportation Extensive use of CCS in the majority of gas-fired power plants Use of shale gas as a back-up for energy security with CCS Renewables in higher proportion Nuclear continues with slightly increased share compared to the previous decades-2050 all power plants are efficient Use of geosequestration
Table : Description of ‘Zorba’ Steps
ZORBA – predominant renewables Steps’ Description
2020 – The Black step Current system configuration with high investments in energy storage, renewables and lower in CCS Nuclear increases new power plants will be built
2030 – The Grey step Significant improvements in energy storage technologies. Use of nuclear Use of less fossil fuels More renewables incentives taken and more low-carbon technologies implemented in existing buildings (such as, insulation techniques domestic wind turbines, PV) through different policy schemes Government provides and implement policy options to support different industries Use of carbon sequestration techniques in high levels
2040 – The Blue step Energy storage implemented Higher proportion of renewables than in Kalinka Use of renewables to produce Hydrogen Back-up from nuclear with new nuclear plants Some success in extracting shale gas Extensive use of carbon sequestration techniques
2050 – The Green step Predominant renewables with well establish energy storage options, with use of hydrogen for transportation , Use of nuclear from new more efficient facilities Use of natural gas and shale gas in relatively small proportions as peak-load back-up in the electricity system Extensive use of carbon sequestration techniques
5Assumption level 3: high electrification and CCS in industry sector while the industry grows in
parallel with today (assumption level B)
5 Key Policies Required by Energy Industries as a result of the Workshop
Regardless of the path taken to develop the UK’s energy system to meet low-carbon ambitions and
energy demand in 2050, each energy-generating industry focuses around a particular energy product
(nuclear, fossil fuels, wind, etc.) that will face difficulties– alongside overarching challenges of a
changing energy mix overall. This may include uncertainty surrounding technological development
(e.g. CCS or energy storage), energy distribution infrastructure (e.g. grid management and
connection), public acceptance (e.g. onshore wind, nuclear, fracking), security of supply, and
economic viability. These challenges will vary in their prominence depending on the energy resource
and technology, and the emphasis placed on them by the two proposed scenarios (Kalinka and
Zorba).
Many challenges are likely to require proactive strategies and policy instruments to reduce their
impact. This may include the provision of funding for R&D into CCS, the roll out of ‘smart meters’
and the development of smart grid led by government, information campaigns and benefits targeted
at local communities impacted by infrastructure, or price stability delivered by feed-in tariffs or
contracts for difference, to encourage private investment.
As part of a workshop undertaken in July 2013, expert participants were divided into six groups,
reflecting the key energy resource industries (‘Coal’, Oil’, ‘Gas’, ‘Nuclear’, ‘Wind’ and ‘Other
Renewables’). Each group was given time to consider the key challenges to their industry in meeting
the ‘required’ proportion of energy supply in 2050 as described by the ‘Zorba’ and ‘Kalinka’
scenarios, taking into consideration the three ‘points’ of the energy trilemma (energy security,
energy affordability and emissions reduction targets), beginning with the approximate proportion
each accounts for in the present energy supply system. Based on these challenges, each group was
tasked to put forward five key policy instruments to overcome these challenges, for each scenario. It
was assumed that the existing and planned policy landscape is ‘wiped clean’, and that the five
instruments may overlap between scenarios. Policies that are currently in place or planned for
introduction may be ‘reinstated’. Table illustrates the ‘most important’ policy options (one per
group, per scenario), as voted for by the full participation group.
Table 6: ‘Most important’ policy instrument options for energy supply industries
Energy industry Zorba Kalinka
Coal Full-scale CCS Demonstration Full Scale CCS Demonstration
Oil Increased vehicle fuel efficiency Increased vehicle fuel efficiency
Gas Pre-combustion CCS
Demonstration Pre-combustion CCS
Demonstration
Nuclear R&D for grid management
technologies and strategies Extend existing plant life
Wind Energy Storage R&D -
‘Other’ Renewables Feed-in tariff for full expected
lifespan Feed-in tariff for full expected
lifespan
The development and demonstration of commercially viable CCS was voted as the key priority for
both the coal and gas industries, in both scenarios. This indicates the belief that the reduction of CO2
emissions is the key challenge for these industries, over other issues such as security and cost of
supply, and incentives to invest in new installations, where required. Such an incentive was voted as
the key policy priority for ‘other’ renewables (e.g. solar, marine, biomass). The extension of the
lifespan of existing nuclear plans was voted as the priority for nuclear power under ‘Kalinka’, in
which nuclear is not a major electricity generator. For ‘Zorba’ however, where nuclear plays a more
significant role, the most important policy was considered to be provision for R&D into grid
management, to enable the combination of relatively static nuclear generation with stochastic
renewables. The most important policy for the use of oil in both scenarios (largely in transport), was
encouraging end-use efficiency (i.e. increased vehicle efficiency). This has the dual result of reducing
carbon intensity of oil end-use, and reducing exposure to security of supply and affordability issues.
Whilst these are presented as the most important policy considerations for each energy supply
industry, it does not necessarily follow that these are the five policy priorities overall, in each
scenario. Overall, policy priority might fall to the promotion of renewables, for example, whilst
policies focussed on the oil industry may be relatively unimportant in light of its decreasing share in
consumption.
6 Exploratory Scenarios Results using the ‘DECC 2050 Pathways Calculator’
The DECC ‘2050 Pathways Calculator, used to assess the two scenarios. Different options of how the
UK can best meet energy needs and reduce emissions can be explored with this tool. The DECC 2050
Pathway Calculator has a web-tool version which provides user the possibility to create their own
pathway and an Excel version for users who want to look at the underpinning model.
On the demand side, the users can choose between various choices, such as: insulation level, lighting
and appliances efficiency, travel mode and kind of vehicles. On the supply side the users can choose
how the UK produces its energy. Four trajectories have been developed for each choice. This ranges
from no effort or little to reduce emissions to extremely ambitious changes that push towards the
physical or technical limits of what can be achieved. More information on DECC 2050 Pathway
Calculator please see https://www.gov.uk/2050-pathways-analysis.
6.1 Modelling approach and assumptions
The analysis with the DECC calculator is calibrated against 2010 data. Apart from the assumptions
individual to each scenario, such as the penetration of different energy sources, improvements in
energy efficiency and development of various energy technologies, the calculator considers the
following common assumptions:
a. The UK population increases by 25% (to 77 million by 2050).
b. The number of households grows by 50% (to 40 million by 2050).
c. GDP growth is assumed to be a standard rate of 2% per annum, and does not integrate
positive or negative feedback implications from the assumptions selected in a specific
scenario (e.g. rate of industrial growth). UK GDP is projected to reach £3 trillion by
2050(DECC, 2010a).
These scenarios are focussed on different manifestations of policy routes to the long-term
decarbonisation target (80% reduction in emissions by 2050). However, the DECC calculator does not
include a detailed description of the required policies in order to achieve the several transformations
proposed by the trajectories. According to HM Government (2010), “a detailed policy roadmap
covering such a long timeframe would be neither possible nor plausible. Instead, we have described
the shape of trajectories as they might be experienced on the ground under the assumptions of the
associated levels”. Nonetheless, the major UK energy policies such as: Climate Change Act, 2008 the
EU-ETS, the Renewable Obligation, etc., are integrated in the options although not thoroughly
explored.
The key outputs of the DECC 2050 Pathways Calculator are: energy demand (by sector), energy
supply (by fuel) and GHG emissions by 2050. Also, the impact each step will have in the electricity
sector and on energy security in the UK is assessed by analysing energy flows and mapping the
required areas to develop renewables across the UK. To calculate these results, it is considered that
both scenarios have the same demand side assumptions. These reflect the UK efforts to reduce
emissions and move towards energy efficiency, through change in human behaviour in combination
with policies, without neglecting basic needs for transportation, heating and cooling.
Table 7: ‘Kalinka’ and ‘Zorba’ demand side assumptions from 2020 to 2050
KALINKA & ZORBA SCENARIO Demand Side Assumption
Trajectory6 Value/Technology
2020 2030 2040 2050
Domestic Transport Behaviour (Energy Required) (3)
312.8 TWh 144.4 TWh 115.1 TWh 71.9 TWh (Increase of 900km/p.a.by 2050/Shift towards bikes and public transportation)
Shift to zero emission transport (3)
20% conventional cars, 32% plug-in hybrid vehicles, 48% of zero emission vehicles (hydrogen), 22% fuel cell busses by 2050
7
Choice of fuel cells or batteries
(3) 20% of vehicles fully electric, 80% of vehicles with hydrogen fuel cells
Domestic Fright (Energy required)
(2)
114.3 TWh 101.0 TWh 105.7TWh 110.6 TWh (66% reduction in freight by road and 11% in the proportion of train. Goods moved in 2050 increased by 33%)
International Aviation (Aviation Fuel Use)
(3)
153 TWh 161 TWh 169 TWh 164 TWh (130% increase in international passengers using UK airports compared to 2010 and 31% increase in fuels )
International Shipping (Marine bunkers- Fuel use) (3)
51 TWh 55 TWh 59 TWh 63 TWh (16% increase in emissions from shipping by 2050)
Average Temperature of homes
(3) Mean temperature decreases by 0.5°C compared to 2007 in 2050
Home insulation (3) 8 millions of 11.5 millions 15 millions 18 millions of
6 Trajectories are divided in 4levels 1-4. This default range of options including decimal numbers that constitute
linear interpolations shows an increase in the values or technological efficiency from 1-4. Values from A-D symbolise choices related to quality or a combination of quality and quantity. 7Influenced by policy instrument option from ‘ENP2050’ Workshop-Oil industry
homes adequate insulated with 4.3 millions of homes having triple glazing
of homes adequate insulated with 7.5 millions of homes having triple glazing
of homes adequate insulated with 11 millions of homes having triple glazing
homes adequate insulated with 14 millions of homes having triple glazing
Home heating electrification
(C) Technologies used:58% air source heat pump, 30% ground source heat pump, 1% Geothermal, 11% district heating from power source Demand for heating & Cooling:
Home heating that isn’t electric
(C) 375 TWh 365.2 TWh 365.4 TWh 371.1 TWh
Home lighting and appliances-Demand
(2)
81.8 TWh 82.6 TWh 87.9 TWh 93.5 TWh (Demand per household decreases by 34%/10% increase in demand for commercial lighting & appliances)
Electrification of home cooking
(B) Complete electrification of home cooking
Growth in industry
(B) UK industry grows in parallel with present trends
Energy intensity in industry
(3)
384TWh 344 TWh (CCS is deployed rapidly after 2025 in industries)
320.9 TWh 300.3 TWh (40% progress in energy efficiency/25% decrease in emissions intensity/66% of energy demands is for electricity)
Commercial Demand for heating and cooling
(3)
114.3 TWh 118.3 TWh 125.3 TWh 134.2 TWh (Space heating demand remains at the current level/ hot water demand increases by 25%,cooling stable)
Commercial heating electrification
(C) Technologies used:58% air source heat pump, 30% ground source heat pump, 1% Geothermal, 11% district heating from power source
Commercial heating that isn’t electric (C)
Commercial Lighting and (2) 77 TWh 80.8 TWh 85.3 TWh 90 TWh
Appliances (15% raise in energy demand for lighting and appliances and 5% decrease for cooking)
Electrification of commercial cooking
(B) Complete electrification
Table 8: ‘Kalinka’ supply side scenarios from 2020 to 2050
KALINKA SCENARIO
Supply Side Assumption
Trajectory Value/Technology
2020 2030 2040 2050
Nuclear Power Stations
(1.2)
0.24GW/yr new power stations 91 TWh
0.24GW/yr new power stations 91 TWh
0.24GW/yr new power stations 117 TWh
168 TWh
8
CCS Power Stations
(4)
2GW/yr new power stations
3GW/yr new power stations
3GW/yr new power stations
50-90 CCS Power Stations by 2050
9
CCS Power Station Fuel mix
(D)
~ 30% coal, 70% gas (natural, shale or biogas)
CCS power stations use 100% gas (natural, shale or biogas)
CCS power stations use 100% gas (natural, shale or biogas)
CCS power stations use 100% gas (natural, shale or biogas)
Offshore Wind
(2)
3GW/yr new power stations 80 TWh
3GW/yr new power stations 261 TWh
3GW/yr new power stations 379TWh
60 GW (new turbines have replaced older ones) 394TWh
Onshore Wind
(2)
1GW/yr new power stations 52 TWh
1GW/yr new power stations 168 TWh
1GW/yr new power stations 237 TWh
20 GW (new turbines have replaced older ones) 237TWh
Wave
(2)
0.1 GW 0.4 GW 3.6 GW 9.6GW 300km of Pelamis wave farms in the Atlantic-19TWh/yr
Tidal Stream (2)
0 GW 0.1 GW 0.7 GW 1.9 GW 6 TWh/yr from
8Influenced by policy instrument option from ‘ENP2050’ Workshop-Nuclear Industry 9Influenced by policy instrument option from ‘ENP2050’ Workshop-Gas Industry
electricity output
Tidal Range (2)
0.7 GW 1.7 GW 1.7GW 1.7 GW 3 TWh/yr
Biomass Power Stations
(2) 2.4 GW 4.2 GW 6.0 GW 7.8 GW
Solar panels for Electricity (2) 0.9 GW 5.8 GW 20.2 GW 70.4 GW
60 TWh/yr
Solar Panels for Hot Water
(2)
0.3 m2 per
household 0.5 m
2 per
household 0.8 m
2 per
household 1.0 m
2 per
household (30% of suitable UK buildings get 30% of their requirements for hot water from solar panels)
Geothermal Electricity (1.5)
50 MW 400 MW 500 MW 500MW 5.25 TWh/yr
Hydro Electric Power Stations
(1.5) 1.7 GW 1.75 GW 1.8 GW 1.85 GW
5.25 TWh/yr
Small Scale Wind
(2)
0.6 GW 0.6 GW 0.6 GW 0.6 GW (325.000 turbines or 1.3 TWh/yr)
Electricity Imports
(3)
6.0 TWh/yr 23 TWh/yr 47 TWh/yr 70 TWh/yr and 10% share of the international desert project
10
Land Dedicated to Bioenergy
(3)
10% of Land used for biocrops
cultivation
Livestock and their management
(2) Same as present (2010)
Volume of Waste and Recycling
(C)
45.8 TWh primary energy from waste
50 TWh primary energy from waste
54.3 TWh primary energy from waste
59 TWh primary energy from waste (81% increase in recycling rate)
Marine Algae
(2)
1.00 Km2
area of sea farmed
10 Km2 area
of sea farmed
100 Km2
area of sea farmed
562.5 Km2
area of sea farmed
4 TWh/yr
10
100 GW of concentrating solar power plants throughout Northern Africa proposed by the Desertec Foundation. This project will be interconnected with EU in order to meet European and global energy demand (Source: inhabitant.com)
Type of Fuels from Biomass
(B)
All biomass is converted in solid fuel in order to replace gradually coal
Bioenergy Imports (2) 24 TWh 39.3 TWh 55TWh 70 TWh
Geosequestration
(2)
- Carbon sequestration machines remove: 0.2 MtCO2/yr
0.6 MtCO2/yr
1 MtCO2/yr
Storage Demand Shifting & Interconnections
(2)
3.8 GW of Storage, 30 GWh of storage capacity and 6 GW of interconnection for electricity exports
3.8 GW of Storage, 30 GWh of storage capacity and 9 GW of interconnectors for electricity exports
3.8 GW of Storage, 10GWh of storage capacity and 10 GW of interconnectors for electricity exports
4 GW of Storage, 30 GWh of storage capacity and 10 GW of interconnection for electricity exports
Table 9: ‘Zorba’ supply side scenario from 2020 to 2050
ZORBA SCENARIO
Supply Side Assumption
Trajectory Value/Technology
2020 2030 2040 2050
Nuclear Power Stations (1.5) 111 TWh 189 TWh 291 TWh 420 TWh
CCS Power Stations (2)
0.5 GW/yr new power stations
1.5 GW/yr new power stations
1.5 GW/yr new power stations
25-40 CCS Power Stations
CCS Power Station Fuel mix
(D)
~ 30% coal, 70% gas (natural, shale or biogas)
CCS power stations use 100% gas (natural, shale or biogas)
CCS power stations use 100% gas (natural, shale or biogas)
CCS power stations use 100% gas (natural, shale or biogas)
Offshore Wind
(3)
4.2 GW/yr new power stations 80TWh
5 GW/yr new power stations 261 TWh
5 GW/yr new power stations 379TWh
100 GW 394TWh
Onshore Wind
(3)
1.6 GW/yr new power stations 51 TWh
1.6 GW/yr new power stations 84 TWh
1.6 GW/yr new power stations 84 TWh
29 GW (new turbines have replaced older ones) 84 TWh
Wave
(3)
0.1 GW 1.1 GW 7.0 GW 19.3 GW 600km of Pelamis wave farms in the Atlantic-38TWh/yr
Tidal Stream (3)
0.1 GW 0.5 GW 3.5 GW 9.5 GW 30TWh/yr
Tidal Range (3)
0.8 GW 4.3 GW 13 GW 13GW 26 TWh/yr
Biomass Power Stations
(3) 3.6 GW 6.6 GW 9.6 GW 12.6 GW
Solar panels for Electricity (3) 2.5 GW 16.1 GW 39.1 GW 94.7 GW 80
TWh/yr in 2050
11
Solar Panels for Hot Water
(3)
0.9 m2 per
household 1.6 m
2 per
household 2.3 m
2 per
household 3.0 m
2 per
household (All the suitable UK buildings get 30% of their requirements for hot water from solar panels)
Geothermal Electricity (2)
100 MW 800 MW 1 GW 1 GW 7 TWh/yr
Hydro Electric Power Stations
(2) 1.8 GW 1.9 GW 2.0 GW 2.1 GW
7TWh/yr
Small Scale Wind
(3)
1.7 GW 1.7 GW 1.7 GW 1.7 GW (825000 installed in every building generating 3.5 TWh/yr)
Electricity Imports (1) No electricity imports
Land Dedicated to Bioenergy (3) 10% of Land used for biocrops cultivation
Livestock and their management
(2) Same as present (2010)
Volume of Waste and Recycling
(C)
45.8 TWh primary energy from waste
50 TWh primary energy from waste
54.3 TWh primary energy from waste
59 TWh primary energy from waste (81% increase in recycling rate)
Marine Algae
(3)
1.00 Km2
area of sea farmed
50 Km2 area
of sea farmed
250 Km2
area of sea farmed
1.125 Km2
area of sea farmed 9 TWh/yr
Type of Fuels from Biomass (B) All biomass is converted in solid fuel in order to replace
gradually coal
Bioenergy Imports (3) 45 TWh 77 TWh 108.3 TWh 140 TWh/yr in
205012
Geosequestration (3)
- Carbon sequestration machines
20.6 MtCO2/yr
31MtCO2/yr
11Influenced by policy instrument option from ‘ENP2050’ Workshop-‘Other renewables’ industry 12Influenced by policy instrument option from ‘ENP2050’ Workshop-Oil industry (more biofuels used in aviation through this option)
remove 10.2 MtCO2/yr
Storage Demand Shifting & Interconnections
(4)
3.8 GW of Storage, 30GWh of storage capacity and 9 GW of interconnectors for electricity exports
10 GW of Storage, 150GWh of storage capacity and 25 GW of interconnectors for electricity exports
15 GW of Storage, 350GWh of storage capacity and 30 GW of interconnectors for electricity exports
20 GW of Storage, 400GWh of storage capacity and 30 GW of interconnectors for electricity
exports13
6.2 Scenarios Results
This section presents the results of the two scenarios as applied to the DECC Pathways Calculator,
including energy and electricity supply profiles and resulting GHG emissions, for each steps in each
scenario. The base year for the results is 2010, except for GHG emissions reduction, which is
calculated relative to 1990 levels.
6.2.1 Energy and Electricity Demand
Primary energy demand remains equal between ‘Kalinka’ and ‘Zorba’ as input energy demand
assumptions, as described above, did not vary. Results from 2020 to 2050 are presented in Figure
15, where it is illustrated that the energy proportions between the demand sectors remain relatively
constant over time. In 2050, the final projection year, energy demand is estimated to be
1359TWh/yr experiencing a reduction of 26% (between 2010 and 2050) - a sign of efficiency
improvements in the energy sector over the years. Clearly, the major consumer continues to be
buildings in the domestic and commercial sectors consuming 41% of the total primary energy in
2050. This proportion is comprised of 28% for heating and cooling and 13% for lighting and
appliances as presented in Figure 6. The second largest consumer is transportation, demanding 35%
of total primary energy, followed by industry with 24% in 2050.
13Influenced by policy instrument option from ‘ENP2050’ Workshop-Wind industry
Figure 15: Primary Energy Demand for ‘Kalinka’ and ‘Zorba’ scenarios for 2020-2050
Figure 16: Primary Energy Demand division in the Domestic and Commercial sectors for ‘Kalinka’ and Zorba’ scenarios for 2020-2050
0
100
200
300
400
500
600
700
The Black Pathway2020
The Grey Pathway2030
The Blue Pathway2040
The Green Pathway2050
TWh
Primary Energy Demand
Industry Transport Buildings
0
100
200
300
400
500
600
700
The Black Pathway2020
The Grey Pathway2030
The Blue Pathway2040
The Green Pathway2050
TWh
Primary Energy Demand in the Domestic and Commercial Buildings
Heating and Cooling Lighting & appliances
On the other hand, electricity demand is diversified between the two scenarios. The first difference
is observed in demand for heating and cooling as the increase in solar thermal for hot water in
‘Zorba’ reduces electricity requirements by 13TWh between 2010 and 2050. The second and more
important assumption is geosequestration, which constitutes a technology that is capable of
removing CO2 straight from the atmosphere by means of engineered air capture technologies and
stores it in soils, building materials etc. The difference from CCS is that it captures CO2 in the
atmosphere instead of at source (e.g. power stations) (DECC, 2010b, HM Government, 2010).
Geosequestration belongs to the supply side assumptions but affects electricity demand. In ‘Kalinka’,
sequestration is considered at ‘level 2’ (1MtCO2) in the Pathways Calculator. However, ‘level 3’
(31MtCO2) applied in ‘Zorba’, requires much higher levels of electricity to power geosequestration
technology. Consequently, there is a great impact in electricity demand between levels 2 and 3 equal
with 99 TWh.
According to Figure 17, electricity demand is projected to be 675 and 589 TWh/yr for Kalinka and
Zorba in 2050 respectively. Electricity for industry shares 35-45% (Kalinka and Zorba, respectively) of
this total demand. Buildings require almost 52% of the total (20.75% for heating & cooling and
31.25% for lighting & appliances) for ‘Kalinka’, and 43% (16% heating & cooling and 27% lighting &
appliances) for ‘Zorba’. It is observed that the electrification of transportation along with the
promotion of hydrogen fuel cells starts mainly in 2030 and increases until 2050 reaching 11-13%
(‘Kalinka’ - ‘Zorba’) of total electricity demand.
Figure 17: Total Electricity Demand for ‘Kalinka’ and ‘Zorba’ Scenarios for 2020-2050
0
100
200
300
400
500
600
700
800
Kalinka Zorba Kalinka Zorba Kalinka Zorba Kalinka Zorba
The Black Pathway2020
The Grey Pathway2030
The Blue Pathway2040
The Green Pathway2050
TWh
Electricity Demand
Industry Transport Buildings
Figure 18: Electricity Demand division in the Domestic and Commercial sectors for ‘Kalinka’ and Zorba’ scenarios for 2020-2050
6.2.2 Primary Energy Supply
UK energy supply is projected to increase by 11% and 4.5% between 2010 and 2050 for ‘Zorba’ and
‘Kalinka’, respectively.
Comparing the two scenarios, ‘Kalinka’ forecasts slightly lower levels of energy supply (2.534
TWh/yr) while the predominant source is fossil fuels. In contrast, the ‘Zorba’ scenario projects the
highest (2.688 TWh/yr) energy supply based on a wide range of resources. In this case, excess energy
products may be exported to other European countries.
As illustrated in Figure 19, the main difference between the scenarios is observed after 2030 (the
Grey Step), as in 2020 none of the major transformations has been completed or established.
‘Kalinka’ is based mainly on gas with CCS (32-37% from 2030-2050) whilst the use of coal will be
eliminated by 2030 (the black step) as the majority of coal fired plants is projected to retire by 2023-
2025 due to high levels of pollutant emissions. Nuclear has a back-up role and accounts for 6.7% in
2050 in order to facilitate energy security in case the weather conditions inhibit electricity
generation from wind installation. Bioenergy contributes considerably to the resource mix from
2020, (reaching 14-15% between 2030 and 2050) enhancing decarbonisation along with the carbon
capture and storage techniques. Besides biomass, wind energy shares high levels in the primary
energy supply from 2030 and by 2050 accounts for 11.5% of the total energy supply.
0
50
100
150
200
250
300
350
Kalinka Zorba Kalinka Zorba Kalinka Zorba Kalinka Zorba
The Black Pathway2020
The Grey Pathway2030
The Blue Pathway2040
The Green Pathway2050
TWh
Electricity Demand in the
Domestic and Commercial Buildings
Heating & Cooling Lighting & Appliances
‘Zorba’ scenario includes ’greener’ steps, that incorporate significant use of renewable energy.
However, nuclear power is projected to increase somewhat compared to ‘Kalinka’ producing 15.6%
of the total energy supply by 2050.Wind and bioenergy are the two main alternative sources
deployed in both scenarios although in ‘Zorba’ the investments in wind installations are higher (18%
of the energy share by 2050). Finally, the outputs of the calculator consider pumped heat as another
form of energy supply in both scenarios and its contribution is apparent mostly after 2040, reaching
approximately 7.5% in 2050.
Figure 19: Primary Energy Supply for Kalinka and Zorba Scenarios for 2020-2050
6.2.3 Electricity Supply
According to Figure 20, there is a gradual increase in electricity supply in both scenarios. This is due
to the high electrification of the industrial, domestic and commercial sectors along with some
modest progress in the transportation sector. Nonetheless, ‘Zorba’ projects the highest increase in
all years, particularly by 2050, (1,153TWh), at almost 3.5 times 2010 levels. ‘Kalinka’ has slightly
reduced electricity supply at 1,132TWh in 2050. Electricity supply between the scenarios follows
similar patterns of the broader energy supply development. Unreduced thermal generation that
derives from combined heat and power (CHP) is estimated to decline to very low levels by 2030 in
both scenarios. This is because of the limited heating from CHP as it is replaced by waste heat from
power stations (trajectory C in the DECC calculator).
0
500
1000
1500
2000
2500
3000
Zorba Kalinka Zorba Kalinka Zorba Kalinka Zorba Kalinka
The Black Step 2020 The Grey Step 2030 The Blue Step 2040 The Green Step 2050
TWh
Primary Energy Supply Scenarios & Steps Comparison
oil gas coal nuclear solar wind bioenergy pumped heat wave Tidal
Figure 20: Electricity Supply for Kalinka and Zorbas Scenarios for 2020-2050
The ‘Kalinka’ scenario produces a mostly gas-based electricity system (51% for 2050 – using natural
gas, shale gas or biogas), with the use of CCS. CCS is deployed mainly after 2030 (grey step-34%
share in 2030) and its full deployment is observed after 2040 (blue step-45% share in 2040). The rest
of the electricity is supplied by offshore wind reaching 168 TWh by 2030, 237 TWh in 2040, and
sustained until 2050. An additional, notable difference between ‘Kalinka’ and ‘Zorba’ is that the first
relies more on electricity imports (70TWh/yr) by 2050.
The ‘Zorba’ scenario on the other hand, includes less investment in fossil fuels with CCS and more in
renewables R&D. The electricity supply depends on a variety of resources including nuclear and gas
with CCS as illustrated in Figure 20. The highlight of this scenario is the increased use of wind
producing 41.5% of the total electricity. Furthermore, solar, wave and tidal energy contributes in
electricity generation especially after 2040 (the blue step), whilst in 2050 they share 15% of the total
electricity generation.
6.2.4 GHG Emissions
Results for GHG emissions from each scenario focus on 2020, 2030 and 2050, as the UK emission
targets and milestones are focused on these three milestones, and are illustrated in Figure 21.
Certainly ‘Zorba’ projects the most low-carbon pathway for the UK, although by 2020 the reduction
equals 38%, below the UK target for 42% reduction, according to the CCC (2011).This is due to the
0
200
400
600
800
1000
1200
1400
Zorba Kalinka Zorba Kalinka Zorba Kalinka Zorba Kalinka
The Black Step 2020 The Grey Step 2030 The Blue Step 2040 The Green Step 2050
TWh
Electricity Supply
Scenarios & Steps Comparison
Unabated Thermal Generation Onshore Wind
Offshore Wind nuclear
solar CCS
Electricity Imports wave & Tidal
fact that the most efficient low-carbon technologies are not yet established, with investments in
R&D not yet achieved in earnest. ‘Zorba’ attains to comply with the ‘Fourth Carbon Budget’ targets
for 60% reduction in 2030. Also in 2050 it achieves the 80% emissions reduction target (compared to
1990 levels) imposed by the ‘Climate Change Act’ (UK Government, 2008) by approximately by 2045.
The success of ‘Zorba’ to reach the lowest levels of decarbonisation by 2050 – an 83.6% decline from
1990-is attributed to the high deployment of geosequestration techniques (level 3) along with
effective use of land for biocrops production (level 3) that replace conventional fuels in
transportation and give ‘Bioenergy Credits’ to the UK through bioenergy exports.
The ‘Kalinka’ scenario also makes efforts towards the UK decarbonisation with extensive use of CCS
and average levels of geosequestration (level 2) and large scale of biocrops’ cultivation (level 3). It
succeeds reducing emissions by 65% in 2030 and by 77% in 2050, managing to achieve almost both
targets mentioned in the previous paragraph. However, the 2020 emission reduction target is not
achieved as only a 35% reduction in 2020 relative to 1990 is projected.
According to the ‘DECC 2050 Calculator’, the main emission source in both scenarios (all variations)
is direct fuel combustion in the domestic, industrial, commercial and transport sectors. After 2030
the emissions reduction is projected to be slower, reflecting the increase in energy supply and the
effort of CCS alongside bioenergy to generate ‘negative emissions’ in order to offset part of the
emissions produced by this.
Figure 21: Emissions for Zorba and Kalinka Scenarios for 2020-2050
0
100
200
300
400
500
600
The Black Step 2020 The Grey Step 2030 The Green Step 2050
MtC
O2
Year
Zorba Kalinka UK targets
6.2.5 Energy Security
One of the objectives of the ‘ENP2050’ Project is to investigate divergent scenarios that maintain a
continually secure energy system in the UK by 2050. Hence, the DECC model manages to imply a
stress test simulating the five coldest and windless days in the UK. Consistent with this analysis, both
of the scenarios succeed to balance energy supply and demand while matching energy supply with
increasing demand. In case of electricity surplus the excessive power may be exported to countries
such as Ireland and France. Energy sufficiency is achieved through energy production from a variety
of sources and increased energy storage (‘Zorba’ Scenario) or by a combination of investments in
fossil fuels in conjunction with CCS development and high levels of energy imports (‘Kalinka
Scenario’).
The import dependency among the scenarios shows that in ‘Kalinka’, resources imports are
increased. In ‘Kalinka’, 77% of oil and 91% of gas (along with all uranium for nuclear), is imported by
2050, producing high imports dependency and producing energy security issues. In total, 6% of
electricity supply and 67% of all primary energy is imported by 2050 in ‘Kalinka’.
In ‘Zorba’ scenario, 75% of oil and coal, 81% of gas, 25% of bionergy (along with all uranium) is
imported. However, these primary energy imports account for 54% of total supply, with no
electricity import requirements due to the prevalence of domestic renewable electricity
installations. It is evident that oil imports are high in both scenarios, as oil continues to be the
predominant power source for transportation, with domestic production decreasing over time,
continuing current trends.
6.2.6 Energy Flows in 2050
Figures 22 and 23 present the projected ‘energy flows’ for the two scenarios - the balance between
demand and supply in the UK energy system in 2050. As already discussed, gas (mainly shale and
biogas) is highly significant in ‘Kalinka’ and is generated by thermal generation stations. Thermal
generation is divided in: energy (680 TWh/yr), transmitted through the electricity grid towards
geosequestration exports, and other superfluous energy requirements, while a large amount of
energy (596 TWh/yr) is lost and 55 TWh/yr serve district heating. Oil as previously mentioned serves
the transportation sector. Renewable energy accounts for 19% of electricity generation in ‘Kalinka’
by 2050, and is distributed directly through the electricity network in order to provide power
primarily to the industry, domestic and commercial sectors. Nuclear power contributes 168 TWh in
the thermal generation transmitted through the power grid. Finally, bionergy along with waste fuels
are converted mainly into solid fuels (replacing coal) and the majority (195 TWh) is used for
domestic heating, while 78 TWh is exported. Pumped heat (199 TWh) serves heating and cooling in
houses and commercial buildings.
Figure 22: Energy Flows in the ‘Kalinka’ Scenario
The ‘Zorba’ scenario incorporates high proportions of renewables and nuclear in the energy system
by 2050. Electricity generation from nuclear power (420TWh), gas (339 TWh) and biogas (255 TWh),
are the primary components. Wind energy provides energy for heating, cooling, lighting, appliances
and industrial processes. Pumped heat equals 180 TWh in this scenario.
Figure 23: Energy Flows in the ‘Zorba’ Scenario
7 Comparison between ‘Kalinka’ and ‘Zorba’ with Existing Scenarios
Part of the ‘ENP2050 Project’ includes a literature review of 19 studies investigating future energy
scenarios in the UK. The range of the time periods explored in this project was between 2000 and
2050. This section attempts to compare some of the results of these studies with results of the
‘Kalinka’ and ‘Zorba’ Scenarios, as produced by the DECC 2050 Pathways Calculator. From the
reviewed studies, those with comparable results were chosen and projections years shown in Table
(all values are converted to TWh, where required). The majority of the studies were focused on the
electricity sector although many examined the whole energy sector in the UK. Figures 24 and 25
present electricity demand among the scenarios, and GHG emissions, respectively.
Table 10: Selected studies from the literature review to be compared with ‘ENP 2050 Project’ Scenarios
Name of Study Author & year Projection Years
Electricity Network Scenarios for 2050
Elders et al. 2006 2050
UK Energy and CO2 Emissions DTI, 2006 2010-2020
The balance of power. Reducing CO2 emissions from
the UK power sector
ILEX, 2006 2010, 2016, 2020, 2025
A bright future Friends of the Earth’s electricity sector model
for 2030
Friends of the Earth, 2006
2010-2030
LENS Project Ault, G. et al. 2008 2008
Tyndall Scenarios Mander, S.L. et al., Anderson, K.L. et al.
2008
2008
Closing the Energy Gap WWF, 2008 2020 & 2030
2050 Pathways Analysis HM Government, 2010 2010-2050
UK Future Energy Scenarios National Grid Scenarios, 2012
2013-2030
The UK Energy System in 2050: Comparing Low-Carbon,
Resilient Scenarios (UKERC Scenarios)
UKERC, 2013 2035 &2040
Figure 24 presents the scenarios electricity demands projections and assumptions for 2020, 2030
and 2050 (for 2040 there are no results obtained). For 2020 the WWF study projects the highest
(395 TWh) and lowest (290 TWh) projections for energy demand. By 2030, National Grid with
‘Accelerated Growth’ and WWF’s ‘high’ scenarios propose the highest projections coinciding in 380
TWh. For both 2020 and 2030 ‘Zorba’ and ‘Kalinka’ project moderate estimations for electricity
demand. However, in 2050, ‘Kalinka’ projects the highest energy demand at 688TWh, just above
‘Technological Restriction’ by Elders et al. (2006) whilst National Grid projects the lowest demand
estimating only 330 TWh with the ‘slow development’ scenario assuming generally low levels of
economic growth.
Figure 24: Electricity Demand Comparison among several studies identified in the literature review and ‘Kalinka’ – ‘Zorba’ scenarios
‘Zorba’ and ‘Kalinka’ are based on high electrification in all the sectors and mainly in industry,
domestic and commercial sectors. However, this is not achieved completely until 2050. According to
Figure 25, in 2020, 2030 and 2040, the HM Government study has developed the scenario ‘Zeta’ with
the highest projections: 590, 720 and 870 TWh respectively. On the other hand, FOE (2006) has the
lowest projections for 2020 and 2030 with just 359 TWh. Finally, as already mentioned, all the
transformations considered in the DECC calculator are completed by 2050. As such, apart from the
Tyndall decarbonisation scenarios with the ‘Purple‘ scenario that forecasts, high energy intensity
200
250
300
350
400
450
500
550
600
650
700
2020 2030 2040 2050
Year
Electricity Demand Comparison Between studies and Kalinka-Zorba Scenarios
ENP 2050 Project Zorba ENP 2050 Project Kalinka
Electricity Network Scenarios for 2050, 2006 Business as Usual Electricity Network Scenarios for 2050, 2006 Economic Downturn
Electricity Network Scenarios for 2050, 2006 Green Plus Electricity Network Scenarios for 2050, 2006 Technological Restriction
Electricity Network Scenarios for 2050, 2006 Central Direction WWF-Poyry analysis 2008 High
WWF-Poyry analysis 2008 Consultation WWF-Poyry analysis 2008 Medium
WWF-Poyry analysis 2008 Low National Grid, 2012 Slow Progression
National Grid, 2012 Gone Green National Grid, 2012 Accelerated Growth
improvement coupled with large economic growth causing energy demand to increase enormously,
‘Kalinka’ and ‘Zorba’ project higher levels of demand supply as they incorporate many renewables,
less thermal generation and improvement in transport electrification.
Figure 25: Electricity Supply Comparison among several studies identified in the literature review and ‘Kalinka’ – ‘Zorba’ scenarios
The majority of the reviewed studies include results for CO2 emissions rather than GHG emissions.
This inhibited the comparison of ‘Zorba’ and ‘Kalinka’, for which results were obtained for GHG only,
with many other studies. Nonetheless, the HM Government (2010) and the National Grid (2012)
studies both used the ‘DECC 2050 Pathways Calculator’ in order to estimate future reductions in
GHG emissions. According to Figure 26 none of the scenarios proposed in the ‘ENP 2050’ project
manages to achieve so high reductions of 42%, whilst in National Grid study two scenarios:
‘Accelerated Growth’ and ‘Slow Progression’ succeeded to surmount the national targets and
achieve 49% and 53% reductions respectively. These two cases include different assumptions, as the
first suggests rapid economic development, renewables and CCS investments while the second
250
450
650
850
1050
1250
1450
1650
1850
2020 2030 2040 2050
TWh
Year
Electricity Supply Comparison Between Studies and Kalinka-Zorba Scenarios
ENP 2050 Project Zorba ENP 2050 Project Kalinka
DTI, 2006 Central (1) DTI, 2006 Central (2)
ILEX, 2006 BAU: 456 ILEX, 2006 PS1: 406
ILEX, 2006 PS2: 386 FOE study, 2006 "Good Scenarios"
FOE study, 2006 "Slow Scenarios" HM Government report, 2010 Alpha
HM Government report, 2010 Beta HM Government report, 2010 Gamma
HM Government report, 2010 Delta HM Government report, 2010 Epsilon
HM Government report, 2010 Zeta LENS project, 2008 Big T&D
LENS project, 2008 ESCO LENS project, 2008 DSO
LENS project, 2008 MG LENS project, 2008 MN
The Tyndall Decarbonised Scenarios, 2008 Red The Tyndall Decarbonised Scenarios, 2008 Blue
The Tyndall Decarbonised Scenarios, 2008 Turquoise The Tyndall Decarbonised Scenarios, 2008 Purple
The Tyndall Decarbonised Scenarios, 2008 Pink UKERC Scenarios, 2013 REF
UKERC Scenarios, 2013 CFH UKERC Scenarios, 2013 CLC
UKERC Scenarios, 2013 CAM UKERC Scenarios, 2013 CSAM
projects a rather slow recovery and subsequent growth. However, both suggest two extreme
pathways which manage to reduce considerably their future emissions whilst Kalinka and Zorba
proposes improvement but with more mainstream assumptions overall (GDP, fuel prices etc). For
2030, ‘Kalinka’, ‘Zorba’ and ‘Accelerated growth’ from National Grid approximately coincide
managing to achieve a 60% reduction target. National grid did not include results for 2040 and 2050,
and ‘Zorba’ constitutes the only pathway for large-scale GHG emissions decline as presented in
Figure 26.
The rest of the scenarios that do not succeed to reach the emissions targets such as pathways
Epsilon and Zeta are based on assumptions which promote fossil fuels and restrain the use of
sustainable energy resources. Specifically, ‘Pathway Zeta’ is a scenario that projects minor changes
in human behaviour and energy efficiency progress compared to other scenarios which predict
significant change in human behaviour and energy efficiency improvements.
Figure 26: Emissions reductions comparison between the studies reviewed and ‘Kalinka’ – ‘Zorba’ scenarios
0
10
20
30
40
50
60
70
80
90
100
2020 2030 2040 2050
Emis
sio
ns
red
uct
ion
sfro
m 1
99
0 (
%)
Year
UK TARGETS ENP 2050 Project Zorba ENP 2050 Project Kalinka
National Grid, 2012 Slow Progression National Grid, 2012 Gone Green National Grid, 2012 Accelerated Growth
HM Government report, 2010 Alpha HM Government report, 2010 Beta HM Government report, 2010 Gamma
HM Government report, 2010 Delta HM Government report, 2010 Epsilon HM Government report, 2010 Zeta
8 Conclusions
The ’ENP2050 Project’ aims to present two feasible scenarios for the decarbonisation of the UK’s
energy system to 2050. Also, it examines the challenges presented by the required transformation to
a low-carbon energy system in the UK, but also the challenges presented in attempting such an
assessment. We begin by examining the inputs, outputs and assumptions made by previous studies
that attempt to project alternative visions of the future of the UK energy system, with an
intermediate assessment horizon of 2010. These values were then compared with each other, but
also actual data. Significant variation was noted in most metrics, including GDP growth, energy
demand, fossil fuel, nuclear and renewable energy production, and subsequent CO2 emissions.
Whilst some differences may be expected since many of these scenarios explicitly alter these
variables to investigate the impact of specific policy, technological or economic forces (but not
necessarily what the authors think is the most likely pathway), the short term horizon (2006, in
which the three studies concerned were published, to the 2010 intermediate assessment horizon),
would lead one to expect relatively little variation within this time frame, regardless of long-term
trajectories. This highlights the lack of certainty that must be acknowledged in producing future
scenarios that produce results over even the shortest time horizons. This conclusion is supported by
the comparisons with actual data, which in large part due to the financial crisis that began around
2008, meant assumptions such as GDP growth, which links strongly to energy demand assumptions,
quickly became irrelevant. Such ‘shocks’ are difficult, if not impossible to consider accurately in
energy system scenarios, and also serve to highlight that the use of scenarios and modelling are
useful in identifying challenges and likely impacts, but their results cannot be taken as ‘factual’
projections.
In light of this, the ENP2050 project developed two distinct, descriptive scenario pathways for the
development of a low-carbon energy system in the UK by 2050 ‘Zorba’ and ‘Kalinka’. ‘Zorba’ assumes
an immediate and long-term diversification to renewable energy, nuclear and energy storage
technologies. ‘Kalinka’ however retains a majority share in fossil fuels, with the development and
widespread use of CCS technologies. Whilst both achieve long-term decarbonisation and share
commonalities such as development in energy demand, they each result from different short-term
priorities of the ‘energy trilemma’ – energy security, energy affordability, and emission mitigation.
These scenarios aim to identify the benefits and challenges of these opposing decarbonisation
pathways, whilst acknowledging that a hybridised approach would in fact be the most probable, if
not the most desired.
Each scenarios was ‘segmented’ into descriptive decadal developments - steps (‘black’, ‘grey’, ‘blue’
and ‘green’ steps), quantified and modelled with the use of the ‘DECC 2050 Pathways Calculator’ to
produce key results such as sectoral energy demand, energy system development and subsequent
GHG emissions between 2010 and 2050. It is apparent that ‘Zorba’, apart from having the largest
reduction in emissions, projects a more secure energy system with reduced imports. Moreover, it
requires the development of efficient technologies such as the smart grid, and R&D related to grid
management, in order to facilitate a more effective and efficient power system. Evidently, ‘Zorba’
demands higher levels of capital investments while in the future offers a more reliable and low-
carbon energy system. In contrast, ‘Kalinka’ requires lower levels of investments in new technologies
(apart from CCS which is an essential tool to reduce emissions from fossil fuels). ‘Kalinka’ forecasts a
more conventional future with emphasis on the short-term reliability through utmost exploitation of
carbon capture along with some moderate use of renewables and low levels of nuclear as a back-up
resource.
The main divergence between the scenarios are observed after 2030, especially, moving towards the
‘blue’ and the ‘green’ steps (2040 &2050).
Comparing the two scenarios with other relevant studies we identified that the major deviations of
‘Zorba’ and ‘Kalinka’ are observed close to 2050. Until then, the scenarios match more or less with
many of the scenarios examined by other studies. All of the scenarios investigated in this study fit in
efforts to decline carbon dioxide emissions. However, two major differences among ‘ENP
2050’scenarios and the rest are identified, as they propose two doable scenarios with higher
reductions than most of the other scenarios developed by the DECC calculator while assimilating a
wide range of improved but still feasible assumptions. Additionally, these are related to the whole
energy UK system and not just electricity as the largest part of the literature review. It should be
noted that both scenarios were adjusted on the available assumptions of the DECC calculator and
embed several limitations related to the model constraints, which consist a prerequisite for further
improvement.
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ACKNOWLDGEMENT
The authors wish to thank for the funding support to BHP Billiton Sustainable Communities/UCL
Grand Challenges as part of the Sustainable Resources for Sustainable Cities Catalyst Grants 2013.
The analysis and views expressed remain those of the study team alone.
CONTACT:
Dr Catalina Spataru [email protected]
Energy Institute University College London (UCL) Central House 14 Upper Woburn Place London WC1H 0NN UK T: +44 (0)20 3108 5902 W: http://iris.ucl.ac.uk/iris/browse/profile?upi=CSPAT02