Given the scale of the issue, these investment decisions require
a robust and realistic view of a low CO2 competitive energy mix by
2050. With global population increasing by almost two billion in
the next 20 years, energy demand will balloon by 1.5 percent every
year. For most planners, managing and controlling demand represents
a top priority-best pursued through energy efficiency goals. Bain
& Company research shows that in Europe, a 10 percent reduction
in power consumption by 2050 will reduce CO2 emissions by 18
percent and a 20 percent reduction in power consumption will reduce
emissions by 48 percent. Yet measures to curb energy consumption
can only go so far. In parallel, countries also need to develop a
game plan to identify the right energy mix such that they minimize
their carbon footprint as well as meet the growing hunger for
energy.
The power sector offers the most scope for reducing CO2
emissions. In 2007, power generation accounted for 41 percent of
the world's CO2 emissions, well ahead of transportation (26
percent) and all other sectors combined (33 percent). For most
developed countries, achieving an 80 percent reduction in CO2
emissions by 2050 means "decarbonizing" the power sector by 90
percent-which clearly presents a major challenge. As other sectors
like transportation try to reduce their carbon footprints-for
example, through the use of electric cars-they will generate even
greater demand for power.
Yet the sooner countries shift their power generation to less
carbon-intensive capacities, the better their odds of getting to
the right competitive mix by 2050. Power generation represents 43
percent of all CO2 emissions in the United States and 37 percent in
Europe. By identifying the right mix of power technologies that
make their economies more competitive, the US and Europe can reduce
emissions by 80 percent by 2050-if they make the right choices
now.
When we analyzed the installed capacity in the US in 2008, we
found that the existing capacities still operating in 2050 will
account for only about 5 percent of the demand at that time. The US
will need to invest in new assets or renew existing ones to meet 95
percent of the demand in 2050. In the case of Europe, Bain
estimates the EU-27 will need to invest to meet nearly 90 percent
of the total demand in 2050. The scope might appear daunting at
first, but currently available technologies offer plenty of options
to invest in power infrastructure that can help meet demand at low
CO2 levels by 2050. The power cost will clearly be higher-roughly
?30 per ton of CO2 avoided in Europe and $20 per ton in the US-but
affordable as long as the target for reducing CO2 emissions remains
below 90 percent. Eliminating the remaining 10 percent emissions
will imply financial burdens that could jeopardize the
competitiveness of the economy. Most governments and key decision
makers can therefore start the process of meeting the 90 percent
reduction right away. Their challenge: identifying the right
affordable power mix for 2050.
In our experience, when defining an energy policy, most
governments make trade-offs between as many as five criteria.
- Cost of the electricity
- Amount of CO2 emissions
- Security of supply
- Ability to capture the value created by power assets
locally
- Public acceptance of the available technology
With no optimal mix, each country or region must define its own
"potentially appropriate" combination based on the relative
importance of each criterion for that country or region.
Despite the growing pressure to reduce carbon emissions, for
many countries criteria such as security and public acceptance
gained greater importance in the last decade. In many US states and
in some European countries, citizen groups campaign to block new
nuclear plants. Today, nuclear energy provides only 18 percent of
US energy needs-equivalent to 0.32 kilowatt (KW) per inhabitant. In
contrast, in France, nuclear energy provides almost 75 percent of
all electricity generated (equivalent to 1 KW per inhabitant), but
wind energy struggles to gain wide acceptance. To be eligible for
tariffs, wind farms can be built only in restricted Wind Power
Development Zones. Meanwhile, in Germany, which is often at the
cutting edge of experimenting with new low CO2 technologies, the
pilot test for carbon capture and sequestering (CCS) faced public
opposition. Vattenfall's Schwarze Pumpe project in Spremberg,
Northern Germany, which was meant to be a global demonstration for
the three key stages of trapping, transporting and burying
greenhouse gases, was forced to release CO2 directly into the
atmosphere when Germans protested "not under my backyard."
Four levers to shift to lower CO2 emissions
When we applied the framework of the five issues to the US and
the EU-27, the Bain model for optimizing the energy mix showed that
countries can choose between many different paths to get to a
low-emissions competitive mix by 2050. We found that the energy mix
decisions became simpler if countries focus on four main
levers:
"Decarbonization" of the base load: The demand
for base load power generation accounts for 85 percent of current
CO2 emissions from power generation in Europe and up to 92 percent
in the US. Decarbonizing the base load production of electricity
attacks the problem at scale, but raises the next challenge of
finding the right technology.
Currently, there are at least seven low CO2 technologies. Five
of these are already operational: run of river hydraulic;
geothermal; biomass; nuclear; and alternative energy sources like
wind and solar. Two technologies are still maturing: concentrating
solar power (CSP) with storage, and coal and gas with carbon
capture and storage (CCS). Each source of power comes with its own
constraints. Rivers, geothermal and biomass technologies will
quickly reach the limits of available natural resources;
technologies like CSP with storage and coal or gas with CCS are
still to develop commercially to full potential.
Given the existing installed capacity and technology
constraints, the US and the EU-27 can take several paths to a low
CO2 future by 2050, depending on the trade-offs they make. For
example, countries can depend on low-cost renewable sources such as
run of river, biomass and geothermal for their competitiveness and
low CO2 emissions, but these natural resources have finite
potential. Or, countries can bet on CCS, which shows promise as a
low CO2 technology, but still needs to evolve as a viable financial
model for business. Another option: Countries can use nuclear power
to reduce the cost of electricity as well as CO2 emissions, but
nuclear technology comes with a considerable time lag.
Options such as nuclear power and CCS become even more complex
due to the time and cost involved in these projects. Bain estimates
show that if Europe and the US completely ignore nuclear power in
the mix, it would increase electricity costs by 30 percent in
Europe and 28 percent in the US compared with a balanced mix that
includes nuclear supply. However, given the issues around
licensing, feasibility and construction, a nuclear project can mean
a lead time of almost 10 years. Similarly, not including CCS
development in the mix could increase electricity costs by 13
percent in Europe and 26 percent in the US compared with a balanced
mix. However, the jury is still out on how long CCS technology will
take to mature.
Shifting high CO2-emitting power capacities to serve
semi-base and peak load demand: When renewing semi-base
and peak load capacities and reinvesting in new low CO2
infrastructure, countries can switch supply. They can use existing
high CO2 emission base load power plants, fired by coal or gas, to
service demand only at less frequent load levels. Displacing high
CO2-emitting plants to meet less frequent demand has several
benefits.
Our model shows that under certain conditions, displacement
could reduce the EU-27's cumulative carbon emissions by 15 percent
over the next 40 years. In the US, an additional benefit is a
potential drop in the cost of electricity: Redeploying older assets
to meet demand at less frequent load levels and investing in
cleaner base load production technologies could reduce the price of
electricity from $69 per megawatthour (MWh) to $66 per MWh.
However, to get the best from displacement, utilities will have to
speed up substantial investments. For example, the US would need to
invest $1,533 billion by 2020 versus $1,332 billion without
displacement.
Relying on wind and solar in the near term:
Even with displacement, most of the power a country needs will
still come from high carbon-emitting plants. In the US and in
Europe, wind and solar power can play a critical role in
immediately reducing dependence on high CO2-emitting
power-generation technologies. Most countries will need a
short-term plan based on these technologies to dovetail into the
long-term goal of reducing carbon emissions by 2050.
However, renewable energy sources have limitations, too. They
can be volatile, as they depend on intermittent sources of energy:
the wind and sun. Many countries worry that wind and solar energy
are still not dependable enough to cover base load demand. Another
deterrent: The cost of electricity storage seems likely to remain
prohibitive for quite some time.
Wind and solar also represent a high initial capital investment,
with marginal operating costs once the infrastructure is up and
running. If too widely deployed, they will reduce the ability to
get the full benefit from low CO2 competitive base load
infrastructure based on nuclear energy or coal with CCS. The Bain
model estimates that in Europe, a competitive power mix where 240
gigawatts (GW) of power is generated by wind and solar capacities
by 2050 will require ?1,408 billion in total investments over the
period. Depending further on wind- and solar-generated power-say to
meet 600 GW demand-will require additional investments of roughly
?250 billion and increase the total cost of electricity by nearly
10 percent.
Managing demand: An effective way for a country
to reach its 2050 goal is by tackling the demand profile for power.
By looking for innovative ways to transfer semi-base and peak
demand to base load-which is cheaper to decarbonize-a country can
dramatically reduce carbon emissions at a lower cost. In one
projection, the EU 27 can reduce the required power capacity from
773 GW to 670 GW by shifting 13 percent of peak demand to a more
average level of demand.
However, managing demand comes with its own issues. A critical
constraint in balancing energy demand across regions-and for that
matter, across different sources of energy-is the state of the
transmission and distribution networks. Such networks become even
more complex when they cross national boundaries. It took almost 20
years, for example, to build the interconnection capacities between
France and Spain.
Moreover, the aggressive push to reduce CO2 emissions comes at a
cost: To renew and develop these capacities, utilities in the US
would need to invest 30 percent more and in Europe 25 percent more
than "business as usual" between now and 2050. But the payoff would
be higher, too. In Europe, for example, countries can choose the
right low CO2 technology for themselves by prioritizing options
that stimulate economic growth and create more jobs locally.
The road ahead
As countries choose their optimal energy mix, they must consider
two factors that can stall- or accelerate-activity. The first is
the role of capital. Most options for a competitive low CO2 mix in
2050 require higher capital investments today for lower operating
costs tomorrow. That puts tremendous pressure on utilities to come
up with the requisite cash in the short term. The private sector
can play a crucial role in bridging the need for capital, but that
raises the second issue: a stable, predictable environment for
energy investments. The more the profit pool in energy depends on
unclear and changing rules and regulations made by governments, the
less likelihood of private capital shifting to the energy
sector.
Bold approaches require strong leadership and therefore, getting
to the right energy mix by 2050 will test both the public and the
private sectors. Government can play a key role in launching
initiatives that steer the mix in the right direction, providing
access to financing and creating an environment of stability and
transparency that attracts investments. Private leadership will
feature in an equally significant role. Investors will need to
assess and allocate risks. Technology developers will need to speed
up the rollout and development of new low CO2 technologies.
Meanwhile, power generation companies will need to ramp up plans
to renew old assets or build new low-carbon facilities. They can
also play a role in educating both the public and private sectors
on stimulating R&D and pushing for the development of common
and competitive standards on these technologies: Smooth license
processes and collaboration on standards could substantially reduce
the cost of investments. Most of all, despite the flux in the
regulatory environment, utilities can choose to embark swiftly on
their journey to 2050, by taking the first steps needed to develop
a clear vision of the future.
Arnaud Leroi and Stephane Charveriat are partners with Bain
& Company and work in the Utilities practice in Paris. Joseph
Scalise is a Bain partner in San Francisco and leads the US
Utilities practice.
Key contacts in Bain & Company's Global Utilities
practice:
Europe:
Stephane Charveriat in Paris
Julian Critchlow in London
Frederic Debruyne in Brussels
Berthold Hannes in Düsseldorf
Arnaud Leroi in Paris
Roberto Prioreschi in Rome
Nacho Rios Calvo in Madrid
Philip Skold in Stockholm
Kalervo Turtola in Helsinki
Americas:
Neil Cherry in San Francisco
Stuart Levy in Atlanta
Alfredo Pinto in São Paulo
Joseph Scalise in San Francisco
Andy Steinhubl in Houston
Asia:
Sharad Apte in Southeast Asia
Amit Sinha in New Delhi
