Combating Energy Poverty in Mountainous Areas
Through Energy-saving Interventions
Insights From Metsovo, Greece

Nikolas Katsoulakos

katsoulakos@metal.ntua.gr

Metsovion Interdisciplinary Research Center, National Technical University of Athens, 9 Heroon Polytechneiou, 15773 Zografos Athens, Greece

Open access article: please credit the authors and the full source.

An increasing number of

people find it difficult or

even impossible to

ensure adequate

coverage of their energy

needs. This situation,

defined as energy poverty,

is one of the results of the

global energy crisis.

Mountainous areas are

especially vulnerable to energy poverty because their thermal

energy needs are especially high and their economic

environment is not a particularly prosperous one. We studied

ways of reducing conventional fuel use and thus restricting the

risk of energy poverty in Metsovo, a Greek mountain town.

Given the special characteristics of energy consumption in the

area and its energy potential, several alternative scenarios for

saving energy in the town of Metsovo were constructed. The

economic performance of the alternatives and their

contribution to combating energy poverty were assessed. It

was shown that utilizing locally produced biomass and

applying energy-saving measures can bring households below

the ‘‘energy poverty limit.’’ Moreover, dependence on diesel

oil and electricity for heating purposes can be reduced to a

very low level by applying financially viable energy practices.

The case of Metsovo shows that the establishment of an

appropriate framework of sustainable energy policy in

mountainous areas can bring about significant environmental,

social, and financial benefits. The general objectives of the

energy strategy of the European Union, as well as its efforts to

combat energy poverty, can be significantly supported by the

rich renewable energy potential of its mountainous areas,

which is well illustrated by the example of Metsovo.

Keywords: Energy poverty; biomass; energy saving; energy
efficiency; renewable energy potential; Greece.

Peer-reviewed: August 2011 Accepted: September 2011

Introduction

Energy production at the global level is based mainly on
nonrenewable sources. As their name implies, these
sources are finite and exhaustible. Economically viable
deposits of fossil fuels are becoming rare at the same time
that global energy demand is increasing. It is estimated
that global energy consumption in 2025 will be almost
30% greater than in 2007, and 80% of it will be based on
fossil fuels (EIA 2010). The impacts of this situation are
multidimensional: Environmental, economic, social, and
political problems emanate from continuously increasing
use of fossil fuels.
Energy poverty is one of the most important issues

related to the global energy crisis. There are many
approaches to energy poverty. A comprehensive
description is contained in an opinion of the European
Economic and Social Committee (EESC), published in
2011 (p. C44/54):

Energy poverty occurs where a household finds it difficult
or impossible to ensure adequate heating in the dwelling
at an affordable price … and having access to other

energy-related services, such as lighting, transport or
electricity for use of the Internet or other devices at a
reasonable price.

There is no standard quantitative definition of
energy poverty. However, an approach that is often
used is the following: If a household spends more
than 10% of its annual income for energy, it is
considered as energy poor (Walker 2008). This ‘‘energy
poverty limit’’ was first introduced in the United
Kingdom.
The impacts of energy poverty can be particularly

negative. Premature deaths from indoor air pollutiondue
to wood or coal use in poor households are the sixth
largest health risk factor in developing countries (Sagar
2005). According to the United Nations, by 2030 deaths
caused by energy poverty will be more than premature
deaths owing to malaria or HIV if no action is taken
(Lavelle 2010). Hence, several national and international
organizations have become concerned about this
problem. In 2010 the EESC proposed that combating
energy poverty should be a new social priority within the
European Union.

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Increase in fuel prices is one of the main factors that
intensify energy poverty, although this is virtually
inevitable as the result of scarcity of fossil deposits,
unstable tax policies, and inefficiencies in the function of
the liberalized energy market (Bahce and Taymaz 2008;
EESC 2011). Thus if no action is taken the problem will
intensify as a result of the global energy crisis. Improving
energy efficiency and promoting renewable sources of
energy are the basic steps in combating energy poverty.
Mountainous areas have common characteristics that

make them highly vulnerable to energy poverty. Many
mountain economies are not particularly robust (Funnell
and Parish 2001), mountain settlements are usually far
away frommajor energy production centers, and thermal
energy needs in mountain areas are significantly greater
due to cold climatic conditions.
Especially in Greece, mountain communities are

threatened by both the global energy crisis and the
economic crisis. Between December 2010 and February
2011, incidents of illegal logging were recorded in
mountainous areas of Greece (Peklaris 2010), as many
people were unable to afford the cost of diesel oil and
desperately sought for ways to cover their thermal energy
needs. Such occurrences, following energy poverty, are
common in developing countries (Foerster et al 2011),
and it is quite worrying that they are also beginning to
appear in the European Union.
There is a considerable lack of studies on energy-

saving potential inmountainous settlements inGreece, as
well as on the issue of energy poverty in mountainous
Greece. The present study is one of the first attempts to
compensate for this lack. Itsmain objective is to highlight
the positive effects of energy saving in cutting the risk of
energypoverty inmountainousGreece.Themountainous
town of Metsovo (39u469130N; 21u119020E) was used as a
case study (Figure 1). Metsovo is situated in the northern
Pindos mountain range and lies at an altitude of 1100 m.
It has about 3000 inhabitants, living in 750 households.
Although it has a rich renewable energy potential,
Metsovo is vulnerable to energy poverty.
Mountainous regions, according toEUROMONTANA,

‘‘are an ideal area for reducing energy consumptionwhile
maintaining a high standard of living’’ (2010: 4). Bearing
this in mind, we have attempted to show that reducing
fuel consumption should be a basic part of mountain
energy policy. The current economic crisis threatens the
standard of living in Greece, and in Metsovo expenses to
meet energy needs are an especially high demand on
people’s income. Therefore, exploring energy-saving
possibilities is necessary in order to preserve positive
development perspectives in the area.

Methodology

The improvement of a building’s energy performance is
basedonanalysis of its energy consumptionanda techno-

economic assessment of available energy-saving solutions.
In order to explore the possibilities for reducing energy
consumption in Metsovo and thus reducing the risk of
energy poverty in the town, the methodology used for a
single building was generalized.
More specifically, the methodology included 5 steps:

1. Collection and analysis of statistical data. Thedata analyzed
included the thermal and electrical energy consump-
tion of the households, according to theGreek Energy
Information System, and the characteristics of the
buildings, according to the Hellenic Statistical Au-
thority.

2. Field survey related to the energy consumption of the
households. The survey aimed to define detailed
characteristics of energy consumption in the residen-
tial sector (energy systems used, required fuel quanti-
ties, technical and geometrical characteristics of the
residencies, etc) and was conducted on the basis of
personal interviews in 2010. The sample included 200
households. At a confidence level of 95%, the margin
of error of the survey is 5.81%, taking into account
that the population (number of households) is 750.

3. Thermal imaging of 90 houses. The survey aimed to define
weaknesses in the shell ofbuildings that lead to thermal
losses. It was conducted between February andApril
2011. The sample included houses in 4 age categories
(before 1970, 1971–1985, 1986–1995, after 1996). The
houses in the same age category present similar
technical characteristics and energy performance.

4. Formation of alternative scenarios for reducing energy
consumption. Five scenarios of different economic and
technological intensity were constructed. The alter-
natives include energy-saving interventions, biomass,
and solar energy utilization. In order to estimate the
impacts of the alternatives on energy consumption, a
‘‘model house’’ was created for each age category, to
which the energy improvement interventions were
applied. Following the data analyzed in the first step,
the model house was considered to have area and
volumeequal to the corresponding average sizes of the
buildings belonging to the same age category. The
technical characteristics of the ‘‘model house’’ were
estimatedaccording toboth the statistical data and the
field surveys.

5. Technical and economical assessment of the alternatives. In
order to assess the financial performance of the
alternatives, a feasibility study was conducted. The
feasibility study was based on cash-flow tables, which
include the financial benefits, the required investment
costs, and the operation and maintenance costs for
each alternative. Moreover, the contribution of the
alternatives toward combating energy poverty was
estimated, as well as environmental performance.

The central idea behind this study is to apply a
methodology followed at a small-scale level (single

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buildings) to a large-scale level (entire town). It was
applied for the first time in mountainous Greece. The
main advantage of this procedure is that it can provide
quick and reliable estimates of the effectiveness of several
‘‘green’’ energy practices. Moreover, the accuracy of the
results is far greater than the estimates currently available
at country level. This allows for priorities for regional
energy strategies to be set. Therefore, this methodology
can be a useful tool for policy makers in mountain
settlements to identify pathways to combating energy
poverty.

Metsovo energy profile

The cold climate in the area around Metsovo results in
high thermal energy demand, which is significantly
greater than in areas at almost the same latitude but at
lower altitudes. The mean annual temperature is 10uC,
and the average annual rainfall is as high as 1473 mm.
Heating degree-days are summations of the

differences between the average daily temperature and a
base temperature, usually considered to be 18.3uC. They
are derived from temperature measurements. The
thermal needs of a building structure at a given location
are directly proportional to the number of the heating
degree-days at this location. In Figure 2, the heating
degree-days for Metsovo and 3 other towns—calculated
by the available meteorological data—are presented.

Energy needs

In Table 1 the data for energy consumption in Metsovo
and its environmental and financial impacts are
summarized. Fuel prices used were: 1.13 US$/L for diesel,
142 US$/tonne for firewood, and 0.17 US$/kWh for
electrical energy. The diesel and firewood prices refer to
the average prices of those fuels in Greece between
October 2010 and April 2011. The heating source
referred to as ‘‘other’’ is assumed to be a combination of
diesel oil heaters, open fireplaces, and electrical heaters,
following the results of the field survey. In order to
calculate the particulate matter emissions for the heating
systems currently used, several estimates were combined
(Johansson et al 2004; Greenpeace 2007; EEA 2009; NAEI
2009). The CO2 emissions were obtained by the Greek
Public Power Corporation.
According to Table 1, and bearing in mind that the

number of households in Metsovo is 750, the average
annual thermal energy consumption per household was
23,408 kWh, of which 93% is needed for space heating
and 7% for water heating. The cost of this amount of
thermal energy is US$ 2293 per year. The thermal energy
costs corresponded to 7.1%of the average annual income
of the households, which was US$ 32,135.
Electrical energy consumption—excluding electrical

energy consumption forheatingpurposes—was estimated
at 6833 kWh/household, on an annual basis, following the
results of the field survey. This corresponds to US$ 1161

FIGURE 1 View of the town of Metsovo. (Photo by Nikolas Katsoulakos)

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per year. Electricity consumption in Metsovo is
significantly lower than the corresponding average
consumption in Greece.

Energy efficiency of buildings

The available statistical data show that 89% of the total
thermal energy demand of the households in Metsovo
comes from buildings constructed before 1985. The
majority of these houses are stone-built, and their
insulation standards are very poor.
After taking thermal images of the residencies in

Metsovo and analyzing the statistical data, some useful
conclusions were reached (Figure 3):

N Houses built before 1970 and between 1971 and 1985
had particularly low energy performance. About 75%
of themwere not insulated, and almost all of themhad
obsolescent window frames. These houses need to be
insulated, and theirwindow frames shouldbe replaced.

N Houses built between 1986 and 1995 had better energy
efficiency, mainly due to the fact that their walls were
insulated. Their thermal losses were mainly attributed
to window frames that should be replaced.

N The thermal energy demand of houses built after 1996
represents only 2% of the total demand. Their energy
performance was generally good. So no action for
those buildings is proposed.

Metsovo and energy poverty

Overall, 10.7% of the households’ annual income was
required for energy expenses, taking into account both
heating and the electrical energy costs. This percentage
was slightly higher than the ‘‘energy poverty limit,’’
which means that Metsovo is vulnerable to energy
poverty. After a more thorough look at the distribution
of household income, it was apparent that a significant
number of people already faced great difficulties in
covering their energy needs. More specifically, 114
households had annual incomes of less than US$ 14,125.
For these people energy expenses represented more
than 24% of their income, meaning that they are
obviously not capable of covering their energy needs
sufficiently.
The Greek government has announced that fuel taxes

will be dramatically increased in October 2011. Diesel oil

TABLE 1 Thermal energy consumption and its environmental and financial impacts in Metsovo.

Thermal energy system

Energy

consumption

(kWh)

Annual CO2
emissions

(tons)

Annual

PM
a)

emissions

(kg)

Annual cost

(US$)

Ratio of

heating costs

to households’

income (%)

Space heating 16,323,113 3509 3599 1,591,010 6.6

Diesel oil–fired heaters 11,679,969 2995 196 1,314,890

Wood-fired heaters 1,137,660 0 102 42,045

Wood stoves 1,034,236 0 931 38,081

Other 2,471,248 514 2370 195,994

Water heating 1,232,755 395 39 129,014 0.5

Boiler heated by diesel oil 741,554 190 13 83,482

Boiler heated by wood 285,214 0 26 10,540

Electrical boiler 205,987 205 0 34,992

Total 17,555,868 3904 3638 1,720,024 7.1

a)PM: Particles with a median diameter of less than 10 mm. The amount present in the atmosphere is used as an indicator of the level of pollution.

FIGURE 2 Heating degree-days of 4 Greek towns.

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will rise fromUS$ 1.13/L to aboutUS$ 1.69/L, an increase
of 50%.Thismeans that the averageportionofhousehold
income needed for energy expenses will rise to 12.2% in
Metsovo, not to mention that Greek gross domestic
product is expected to decrease in 2012. Therefore, the
problem of energy poverty will be further intensified
(especially for low-income households) under the effects
of the current economic crisis, so there is a definite need
to take action.

Possibilities of exploiting renewable energy potential and

applying energy-saving measures

Metsovo is surrounded by large forests. Between 1988
and 2008, the average firewood production was
5000 tonne/y, according to the local forestry authorities.
This quantity is sufficient to cover the thermal energy
needs of about half of the households. So far, only 13%
of the households cover their energy needs with wood-
fired systems. Therefore, there is an important local
biomass potential that can be utilized. It should be
noted that the forests are publicly owned and are
exploited on a cooperative basis.
The annual portion of solar irradiation in the area

of Metsovo is 1660 kWh/m2 on a horizontal plane
(PVGIS, 2008). This important solar energy potential is
practically unutilized in Metsovo. Solar systems are not
used in the town, because of legal restrictions that aim
to protecting the vernacular architecture of the town.
So incorporating renewable technologies in traditional
buildings—with consequent revision of current
legislation—is a prerequisite for taking advantage of
solar energy.
As far as energy saving is concerned, interventions in

the buildings’ shell are necessary to lower thermal loads.
According to the Technical Chamber of Greece (2010),
improving the shell of a building can have the following
results:

N Thermal insulation of walls: 20–25% energy savings;
N Replacement of window frames: 25–30% energy
savings.

Alternative scenarios for lowering

energy consumption

In order to devise a strategy formore rational energy use
thatwill help to confront energypoverty, it is necessary to
create alternative scenarios of varying economic and
technological intensity. In accordance with the special
characteristics of Metsovo, 5 alternatives have been
created (see Box 1).

The investment costs for each alternative, the
economic benefits, the external benefits (monetary value
of the environmental benefits), and the contribution to
reducing conventional fuel use are given in Table 2.
Calculation of external benefits was based on Butti et al
(2008) and the results of the ExternE research project.
The investment costs were estimated after a thorough
search of the energy products market in Greece and by
taking into account themodel house in eachage category.
Taking the age category ‘‘before 1970’’ as an example, the
model house has the following characteristics:

N Area: 72.36 m2; volume: 217.08 m3; area of openings:
23.75 m2; number of floors: 1;

N Shell construction materials: stone; construction ma-
terials for openings: wood; insulation: none.

FIGURE 3 Distribution of thermal energy demand in Metsovo versus buildings’
age (according to the Greek Energy Information System).

BOX 1: Alternative scenarios for reducing
conventional fuel use in Metsovo

Alternative 1: Installation of solar collectors for hot
water heating. This option includes the installation of
solar systems in 575 households using diesel oil–fired
and electrical boilers.
Alternative 2: Installation of domestic biomass–fired
heaters. This scenario includes the replacement of
diesel oil–fired heaters with biomass heaters. Locally
produced biomass can cover the needs of 375
households.
Alternative 3: Thermal insulation of walls and
replacement of window frames. This option promotes
energy-saving interventions in the building shell.
Thermal insulation would be added to residences built
before 1985, and replacement of window frames would
be applied to houses built prior to 1995.
Alternative 4: Building shell improvement and use of
domestic biomass–fired heaters. This is a combination
of alternatives 2 and 3.
Alternative 5: Building shell improvement, use of
domestic biomass–fired heaters and installation of
solar collectors. This is the most complex scenario
that combines alternatives 1 and 4.

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Assessment of the alternatives

A feasibility study was conducted for financial evaluation
of the alternatives. The lifetime of the investments was
taken tobe15 years, and thediscount ratewas considered
to be 5% (Christodoulou 2010). The criteria of the Net
Present Value (NPV), the Internal Rate of Return (IRR),
and the Payback Period (PP) have been used. The
feasibility study was supplemented with estimates of the
contribution of the alternatives toward combating energy
poverty. The ratio of the annual energy expenses to the
average household’s income is calculated following each
energy intervention (Table 3).
All the investments hadpositiveNPV, IRRhigher than

the discount rate, and PP less than 15 years, which is
considered to be their lifetime. The increased thermal
energy needs of mountain settlements in combination
with high diesel oil prices were the main reasons for the
good financial performance of the energy-saving
interventions.
The replacement of diesel oil–fired heaters with

biomass heaters had remarkably good financial
performance and seemed to be the most efficient
intervention for reducing fuel costs in Metsovo. Apart
from the direct economic and environmental benefits,
forest biomass exploitationhas broaderpositive results in
mountainous areas. More specifically, the existence of
forest production can contribute to forest revitalization
and creation of workplaces.

The assumptions about the lifetimeof the investments
and the discount rate were in accordance with the
corresponding assumptions commonly made for energy-
saving projects in Greece. However, a sensitivity analysis
was carried out in order to assess the influence of the
discount rate on the performance of the alternatives. As
depicted in Table 4, a variation of 620% in the discount
rate did not seem to have a very significant influence on
the investments’ performance. All of the alternatives
remain viable, and3of thempresent a 1 year’s increase in
the PP if the discount rate grows by 20%.
The prices of the fuels proved to be more important

for theviabilityof the investments. Inparticular, theprice
of diesel oil had a more intense influence on the
performance of the alternatives. For example, in the case
of applying thermal insulation to the shell and replacing
the window frames, if the diesel oil price decreases 15%,
then the PP increases from 9 to 13 years, and the NPV
shrinks to 33% of the initial value. Figure 4 shows the
impacts of the variation of the diesel oil price, the
firewood price, and the discount rate on the PP of the
second alternative (use of domestic biomass heaters).
Nevertheless, the contribution of the alternatives to

combating energy poverty cannot be based solely on
economic performance. The use of biomass heaters
reduces the percentage of energy expenses to 9.4% of
annual income. Combining biomass heaters with energy-
saving interventions brings about further reduction, and
the ratio percentage drops to 6.8%.Adding solar systems

TABLE 2 Financial costs and benefits, external benefits, and reduction in conventional fuel use for each alternative.

Alternatives

Investment cost

(US$)

Annual economic

benefit (US$)

Annual external

benefit (US$)

Reduction in

conventional fuel

use (%)

1 581,125 94,778 47,473 5.5

2 1,486,433 327,228 489,807 59.5

3 4,903,672 761,110 468,468 44.5

4 6,351,883 951,813 723,905 77.7

5 6,566,708 990,941 733,753 79.6

TABLE 3 Economic performance of the alternatives and ratio of thermal energy expenses to the households’ income.a)

Alternatives NPV (US$) IRR (%)

Payback period

(y)

Thermal energy expenses to

household income ratio (%)

1 310,908 12 9 6.7

2 1,910,004 21 6 5.8

3 2,214,666 11 10 4.0

4 2,639,656 11 10 3.2

5 2,830,973 11 10 3.0

a)NPV: net present value; IRR: internal rate of return.

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for hot water production reduces the percentage to the
minimumpossible value of 6.6%. It should be noted that
the fifth alternative was of significant help for the
financially weakest part of the town ofMetsovo. People
obliged to spend24%of their income forenergywouldbe
greatly relieved after applying this alternative, since they
wouldneed to spendabout15%of their income.However,
this amount is still higher than the energy poverty limit,
and under current conditions, people with low incomes
need support to cover their energy needs sufficiently.
As far asenvironmentalperformance is concerned, it is

obvious that themost complex alternative has themost
positiveenvironmental impact.Thefifthalternativeresults
invery lowdependenceonconventional fuel,at the levelof
20%.Thealternativewith thebest economicperformance
also showedgoodenvironmentalperformance, resulting in
about a 60%reduction in conventional fuel use andCO2
emissions.Widening the use of biomassmay also have
negative environmental consequences related to the
increase in particulatematter emissions, even if the new
biomassheaters follow strict standards suchas theEN303-
5.However, due to meteorological conditions inMetsovo,
which includeNandNWwindswithvelocitiesover5m/sec
ona regularbasis, this slight increase inparticulatematter
emissions is not expected to affect the environmental
quality of the air.

Conclusions

It is clear that increased fuel use in mountainous areas
make them particularly vulnerable to energy poverty,
owing to the harsh weather conditions. As illustrated in
the case of Metsovo, by applying the proposed
methodology, pathways leading to combating energy
poverty can be found. Mountainous areas should
overcome the risk of becoming ‘‘energy poor,’’ asmany of
them are situated in locations that are ‘‘energy rich.’’
In Metsovo, expanding the use of domestic, biomass-

fired heaters resulted in high financial performance and
helped to reduce conventional fuel use. This constitutes a
solution with reasonable investment costs and direct
positive effects on reducing energy expenses. A more

integrated solution, with greater effects on energy
poverty, would be a combination of biomass use with
energy-saving interventions. This strategy can have more
positive consequences on a long-termbasis. However, the
required investment costs are particularly high (Figure 5).
It seems that a policy providing financial incentives to

apply energy improvement interventions is necessary to
improve the Metsovo energy profile. The Greek
government has designed a program, called ‘‘save at
home,’’ that promotes energy saving by providing
subsidies to specific categories of households. More
specifically, the houses eligible for energy improvement
are those built before 1989 in areas with relatively low
land prices. State support is of significant help to
householdswith annual incomes less thanUS$ 42,577 and
includes a 35% subsidy and a 65% interest-free loan.
A disadvantage of the ‘‘save at home’’ program is the

fact that it does not include a criterion related to the
intensity of energy demand. It is reasonable that areas
with increased energydemand shouldhaveprioritywhere
energy improvement is concerned, but this is not part of
the current energy-saving policy. Therefore, Greek
mountainous settlements are not receiving significant
assistance in changing their energy profile. Since

TABLE 4 Variation in the payback period of the alternatives with respect to changes in the rate of return.

Alternatives

Payback period (y)

Rate of return

4% 4.5% 5% 5.5% 6%

1 8 8 9 9 9

2 6 6 6 6 6

3 10 10 10 10 11

4 10 10 10 11 11

5 10 10 10 10 11

FIGURE 4 Sensitivity analysis related to alternative 2 (use of domestic
biomass heaters).

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mountainous areas are more vulnerable to energy
poverty, it is clear that a special energy policy framework
should be created for them.
The economic and environmental benefits of applying

sustainable energymeasures inmountainous areas arenot
only of local importance. It should be noted that
reduction of conventional fuel use could reach almost
80% in Metsovo. This has far more positive effects than
the ‘‘20–20–20’’ objective.
The economic effects are not only important for local

society, but also for theGreek economy in general. Diesel
oil demand in Greece—and in the majority of European
countries—is basically covered by imports, with
consequent macroeconomic impacts. Therefore, every
action that reduces dependence on diesel oil has a
generally positive result in economic terms.
In conclusion, taking into account the analysis done

for Metsovo, several key factors of interest to mountain
areas in general can be highlighted:

N Energy poverty is a serious social issue and combating
it should become one of the main priorities of
mountain policy, since mountain settlements are
particularly vulnerable to it.

N Utilization of locally available biomass is a key to
lowering fossil fuel consumption for heating purposes
inmountainous areas, provided that the productionof
firewood follows the principles of sustainable forestry.

However, the whole procedure of biomass production,
even under the principles of sustainability, can have
multiple impacts on the forest ecosystem. Hence,
further research is needed in this field in order to
minimize the side effects of biomass use.

N Special financial incentives should be given to moun-
tain populations to apply energy-saving measures. The
economic and environmental effects of such a policy
can be highly positive, at the local level and beyond.

N Mountain communities such as Metsovo could be
assisted in implementing a sustainable energy policy
through knowledge exchange with communities that
have applied successful energy strategies, like Trento
in Italy. Creating communication networks between
mountainous areas is a prerequisite for effective
knowledge transfer. EU-funded programs, such as
COST, can be utilized to this end.

The case of Metsovo shows that the economic crisis
should not be an excuse for inaction. On the contrary,
mountain communities can overcome the impacts of the
problem of covering energy needs by promoting 2 of the
basic elements of the energy strategy proposed by
EUROMONTANA for mountain areas:

N Energy efficiency to the greatest extent possible;
N Energy production at local level from diverse re-
sources.

ACKNOWLEDGMENTS

The author thanks Mrs Aggeliki Theodorou, postgraduate student in the MSc
‘‘Environment and Development of Mountainous Areas’’ of the National

Technical University of Athens, for providing the thermal images and her
valuable help in analyzing statistical data.

FIGURE 5 Investment costs and contribution of each of the 5 alternatives toward mitigating
energy poverty.

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