Renewables – introduction and barriers to
diffusion
Filip Černoch
cernoch@mail.muni.cz
What are RES?
•renewable energy is energy derived from natural
processes that is replenished at a higher rate than it is
consumed
•Solar, wind, geothermal, hydropower, bioenergy, ocean
power
•Variable (wind, solar) vs. dispatchable (hydro, biomass)
RES
Drivers for deployment
• Energy security – RES are spread globally, in contrast to the
conventional (fossil) fuels that are more geographically
concentrated
• Environmental concerns - low environmental impact (vary
according technology) – GHG emissions, local pollutants
• Strategic economic development (rural development,
agriculture sector, high-tech manufacturing)
• Energy access through distributed or off-grid sollutions → decentralized
energy system
• Diversification of energy sources
Conventional RES
Can be stored indefinitely in arbitrary
quantities (left in the ground)
Only few RES technologies readily allow
mass storage (hydro dams, biomass). Other
cannot be stored at all or only in small
quantities
Require extraction Freely available
Finite reserves Constantly replenished
Not strongly exposed to meteorological
factors
Subject to meteorological and climate
conditions
Key parts of the supply chain localised
(ports, pipelines, refineries, plants)
Large potential for decentralisation
Exploation requires large, dedicated
infrastructure at site of extraction
Exploation done at micro level (small PV
panels) up to large scale (large hydro)
Long-distance transport of primary
resource common
Long-distance transport of primary
resource impossible (with exception of
biomass)
Global trends
• As a result of governments´supportive policies „RES have been
the driver of much of the growth in the global clean energy sector since the
year 2000 … As global renewable elektricity generation expands in
absolute terms, it is expected to … become the second most important
global elektricity source, after coal (by 2016)“ (IEA).
• In 2013 RES accounted for almost 22% of total power
generation. Globally, renewable generation was on par with that
of natural gas.
2013 fuel shares in word total primary energy
supply
2013 fuel shares in word electricity
production
Annual growth rates of renewable supply
from 1990 to 2014 in OECD total
Global trends
• Global renewable elektricity generation projected to grow by
almost 45% (+5,4% per year) by 2020
• 2 global trends driving the development of RES power
capacity. 1) development should spread out geographically 2)
RES technologies are becoming competitive on a cost basis
with alternatives
• Annual growth in new capacity is expected to stabilise over
2013-2020, reflecting growing risks to deployment in some
markets and remaining development barriers
• Non-OECD countries are expected to account for around 70%
of new RES generation from 2013-2020. (Number of markets
have adopted long-term policy framework)
Global trends
• China remains the anchor of RES capacity deployment,
accounting for almost 40% of the global expansion and over
60% of non-OECD growth. RES should account for nearly
45% of incremental power generation over the medium term,
ahead of coal.
• In 2013 global new investment in RES capacity estimated over
USD 250 billion (plateued, slightly decreasing in last years).
• Reduction in investment costs have helped the LCOE. Closing
gap between competitiveness of traditional sources and RES.
Competitiveness depends heavily on market conditions and
political framework (onshore wind in Brazil, South Africa, PV
in Chile).
RES production by region
Costs of PV technology
Global trends
14
Techno-economic barriers
•Are present when the cost of a technology is above
the cost of competing alternatives. Mainly related to
• the level of technology maturity
• the extent to which external benefits and costs are
internalised
• „Real“ costs are difficult to assess
• Public subsidies – in 2011 renewables received roughly €30
billion in subsidies, nuclear power €35 billion and fossil
fuels took €26 billion. (EEA 2013).
• Limited responsibility of NPP – in CR up to €300 million,
estimated damages of Fukushima up to €170 billion.
• Coal industry social programmes.
Techno-economic barriers
• High initial capital costs – lower fuel and operating cost
make RES cost competitive on a life-cycle basis, but
higher initial capital costs results in less installed capacity
per initial euro invested. RES generally require higher
amounts of financing for the same capacity. Capital
markets may demand a premium in lending rates for
financing RES because more capital is being risked up
front than in conventional projects.
Techno-economic barriers
• Transaction costs – RES instalations typically smaller
than conventional energy projects. That makes
transaction costs (eg. resource assessment, sitting,
permitting, planning…) higher
• Unfavourable power pricing rules – RES may not receive
full credit for the value of their power. On one hand, they
are close to the consumer, on the other hand those
sources are intermitent
Techno-economic barriers
• Difficulty of fuel price risk assessment – risk associated
with fluctuations in future fossil fuel prices may not be
quantitatively considered in decisions about new power
generation capacity because these risks are inherently
difficult to access
• Price volatility – loss of 0,5% in GDP for 10% oil price
increase for the United States and the European Union.
Over the past year oil prices increased by app. 45%
resultin in a 2,25% loss in GDP (USD 774 bn). In
comparison with total support payment for all RES
globally in 2009 (57 bn)
• Price uncertainty
Legal and regulatory barriers
• Lack of legal framework for independent power
producers – in many countries power utilities still
control a monopoly on production and distribution
→ absence of a legal framework for independent
producers investing in RES facilites and selling their
electricity
• Restriction on siting and construction – based on
height, aesthetics, noise, safety. Permiting authorities
may not be familiar with the technologies
• Transmission access – utilities may not allow
favorable transmission access to RES or may charge
high prices for transmission access
Legal and regulatory barriers
• Utility interconnection requirements – individual
home or commercial systems connected to utility
grids can face inconsistent or unclear utility
interconnection requirements. Lack of uniform
requriements add to transaction costs
• Liability insurance requirement – problem for small
power generators that may face excessive
requirements for liability insurance
Market performance barriers
• Lack of access to credit – small investors may lack
access to credit to invest in RES (esp. when state
support policy is unstable)
• Percieved technology performance uncertainty
and risk – even proven and cost effective
technologies may be percieved as risky if there is
little experience with them in region. Wrong
perception (or missing experience) may increase
required rates of return, resultin in less capital
availability. „Lack of utility acceptance“
Market performance barriers
• Lack of technical or commercial skills and information –
markets function best when everyone has low-cost access to
information and skills. But in specific markets, skilled
personnel who can install, operate and maintain RES
technologies may not exist in sufficient numbers
Barriers to renewable energy
= Policy remains vital to the competitiveness of RES. Policy
uncertainty remains a key challenge to the RES deployment
= Non-economic barriers, integration challenges, grid
connection risks … can all increase financing costs and prevent
investments
= In markets based on short-term marginal cost pricing RES can
often require policy incentives
= in some areas RES are competitive without financial suppport
Sources
• IEA (2011): Renewable energy: Policy considerations for deploying
renewables
• IEA (2015): Renewable energy: Medium-term market report
• IEA (2016): Key renewable trends 2015