.


International Journal of Energy Economics and Policy | Vol 9 • Issue 2 • 2019 31

International Journal of Energy Economics and 
Policy

ISSN: 2146-4553

available at http: www.econjournals.com

International Journal of Energy Economics and Policy, 2019, 9(2), 31-39.

Evaluation of Renewable Energy Alternatives for Turkey via 
Modified Fuzzy AHP
Esra Karakaş*, Ozan Veli Yildiran

Adana Science and Technology University, Faculty of Business, Department of Business Administration, Adana, Turkey. 

*Email: ekoyuncu@adanabtu.edu.tr

Received: 08/11/2018 Accepted: 02/02/2019 DOI: https://doi.org/10.32479/ijeep.7349

ABSTRACT

The importance of renewable energy is increasing both with the inadequacy of traditional energy resources and environmental awareness. Turkey has a 
large potential for renewable energy sources, and utilizing the potential is an inevitable choice for increasing its self-sufficiency with an environmentally 
friendly way. Therefore, evaluation of renewable energy alternatives for the country and determination of the most suitable renewable energy alternative 
are important issues to make reasonable energy investment plan. In this study, we evaluate the renewable energy alternatives of Turkey using Modified 
Fuzzy Analytic Hierarchy Process. Renewable energy alternatives considered in the study are hydro, wind, solar, biomass and geothermal energy. 
Four main criteria and eight sub criteria are used to evaluate five renewable energy alternatives. The obtained results indicate that solar energy is the 
best alternative, and wind energy is the second best alternative for Turkey. The conclusion reached by this study is also support successful realization 
of the Vision 2023 energy targets.

Keywords: Fuzzy Analytic Hierarchy Process, Renewable Energy, Energy Strategy 
JEL Classifications: D81, Q20, Q38

1. INTRODUCTION

Turkey has the highest rate of growing energy demand among 
OECD countries over the last 15 years. Due to the lack of 
domestic gas sources, the country has become an energy importing 
country (http://www.mfa.gov.tr/turkeys-energy-strategy.en.mfa, 
02.07.2018). This dependence on energy imports combined with 
increasing energy cost and the serious negative environmental 
impact of high energy consumption has increased the importance 
of renewable energy resource.

More countries are focusing on renewable energy beyond 
traditional energy sources. Renewable energy is an inevitable 
choice for sustainable economic growth, for the harmonious 
coexistence of human and environment as well as for the 
sustainable development. Renewable energy is usually regarded as 
energy that does not pollute environment and could be recycled in 

nature (Ertay et al., 2013. p. 39). Renewable energy technologies 
are known to be less competitive than traditional electric energy 
conversion systems, mainly because of their intermittency and 
the relatively high maintenance cost. However, renewable energy 
sources (RES) have several advantages, such as the reduction in 
dependence on fossil fuel resources and the reduction in carbon 
emissions to the atmosphere (Banos et al., 2011. p. 1754).

Turkey’s geographic location has several advantages for extensive 
use of most of the RES. Turkey has various types of alternative-
energy resources such as hydro, solar, wind, biomass, and 
geothermal energy available in abundance. However, Turkey is 
an energy importing country with more than half of the energy 
requirement being supplied by imports, and air pollution is 
becoming a great environmental concern in the country. In this 
regard, renewable energy resources appear to be one of the 
most efficient and effective solutions for sustainable energy 

This Journal is licensed under a Creative Commons Attribution 4.0 International License



Karakaş and Yildiran: Evaluation of Renewable Energy Alternatives for Turkey via Modified Fuzzy AHP

International Journal of Energy Economics and Policy | Vol 9 • Issue 2 • 201932

development and environmental pollution prevention in Turkey 
(Kaygusuz and Sarı, 2003. p. 459). Taking these conditions into 
account, Turkey government aims to produce 30% of Turkey’s 
electricity demand in 2023 from RES. So, the important decision 
for Turkey is whether or not to establish renewable energy systems, 
to decide which RES or combination of sources is the best choice. 
Also, because of the important investment costs of constructing a 
renewable energy structure, selecting the best alternative among 
the different renewable energy resources is a vital from the point 
of view of long-term planning.

Renewable energy decision-making can be viewed as a multiple 
criteria decision-making (MCDM) problem with correlating 
criteria and alternatives. The decision making procedure has 
to take into account several conflicting aspects because of the 
increasing importance of the social, technological, environmental, 
and economic factors. Traditional single-criterion decision-making 
cannot cope with the complexity of this problem (San Cristobal, 
2011. p. 498). A traditional single criteria decision making approach 
which is aimed at identifying the most efficient supply options at 
low cost was popular during the 1970s. Growing environmental 
awareness in the 1980s has modified the decision framework by 
incorporating environmental and social considerations in energy 
planning. Thus, the selection among energy alternatives has 
become a multi-criteria problem with many conflicting criteria 
such as economic, technical, environmental, political, social 
(Pohekar and Ramachandran, 2004). Therefore, a multi-criteria 
approach to decision making appears to be the most appropriate 
tool to evaluate some alternatives by taking into account their 
advantages and disadvantages based on selection criteria.

In this study, MCDM model based on the revised fuzzy AHP 
approach is applied to Turkey’s renewable energy optimization 
problem. The objective of this research is to evaluate the most 
appropriate renewable energy alternatives to determine ratings of 
each renewable energy alternatives. For this purpose the revised 
Fuzzy analytic hierarchy process (AHP) technique (Aydın and 
Kahraman, 2011; Aydın and Kahraman, 2018) is utilized to get 
rating of alternatives. The revised fuzzy AHP is an effective and 
newly published technique. This technique was firstly proposed 
by Aydın and Kahraman (2011), and later triangular fuzzy scale 
was revised slightly in their later study published in 2018 (Aydın 
and Kahraman, 2018).

This article is organized in four main sections. First, a review of 
the literature on renewable energy selection problem is presented. 
Especially, extensive literatures concerning the evaluation of RES 
in Turkey are given. Second, description of the selection criteria 
and alternatives are given and the Fuzzy AHP methodology is 
presented. Third, results are presented together with the discussion 
in relation to the literature. Finally, conclusions are given.

2. LITERATURE REVIEW

Decision-making is the process of finding the best option from all 
of the feasible alternatives. Decision-making problems considering 
several criteria are called MCDM problems. There are various 
decision-making methodologies developed by researches in the 

literature. Most frequently used methods for renewable energy 
selection are analytical hierarchical process (AHP), analytical 
network process (ANP), and Technique for Order of Preference 
by Similarity to Ideal Solution (TOPSIS), elimination and choice 
expressing reality (ELECTRE), preference ranking organization 
method for enrichment of evaluations. In addition, during the 
recent years, some researchers take renewable energy selection 
problem as Fuzzy MCDM problem (FMCDM). Therefore, MCDM 
techniques are applied to solve energy decision making problems 
in different countries such as Iran, Greece, India, Spain and 
China. Due to importance of energy for sustainable development, 
countries desire to utilize analytical methods to determine energy 
policy.

Beccali et al. (2003) assessed renewable energy technologies by 
using ELECTRE-III method under fuzzy environment for the 
island of Sardinia. Sadeghi et al. (2012) suggested a FMCDM 
approach to assess four renewable energy alternatives in Yazd 
province in Iran. They used fuzzy AHP (FAHP) method to 
determine weights of criteria and ranked alternatives with fuzzy 
TOPSIS method. They concluded solar energy as the most 
appropriate alternative for the selected area. Tasri and Susilawati 
(2014), focused on determining the most appropriate renewable 
energy alternative for electricity production in Indonesia using 
fuzzy AHP. Al Garni et al. (2016) used a MCDM methodology 
based on AHP to rank renewable power generation alternatives 
taking into account economic, environmental, socio-political 
and technical criteria. And then, they applied their proposed 
methodology to rank renewable sources for Saudi Arabia. Algarin 
et al. (2017) used the AHP to prioritize criteria, subcriteria and 
alternatives for renewable energy supply in rural areas of the 
Caribbean region of Colombia. They concluded that solar energy 
was the best renewable energy alternatives for the region (Algarin 
et al., 2017).

There are many studies about MCDM application of renewable 
energy modeling in the literature. More studies can be found in 
review articles about MCDM application in renewable energy 
selection. Pohekar and Ramachandran (2004) discussed renewable 
energy applications with MCDM. Taha and Daim (2013) presented 
a literature review in which MCDM applications in renewable 
energy are divided into four main categories: Renewable energy 
planning and policy, renewable energy evaluation and assessment, 
technology and project selection, and environmental aspects.

In this section, available MCDM studies in renewable energy 
selection for Turkey are given in detail. Ulutaş (2005) aimed 
to determine the appropriate energy sources for Turkey using 
ANP. Both RES and the other sources were considered as energy 
alternatives. The results of the study indicated that biogass is the 
most attractive source for the country. Kahraman et al. (2009) 
proposed two FMCDM methods to select the most appropriate 
renewable energy in Turkey. The first method was Fuzzy 
AHP, while the other was Fuzzy axiomatic design (AD). They 
considered biomass, hydropower, geothermal, wind and solar 
renewable energy as alternatives. Wind energy was selected as 
the best renewable energy alternative in both methods. Kahraman 
et al. (2010) determined the best energy alternative of Turkey 



Karakaş and Yildiran: Evaluation of Renewable Energy Alternatives for Turkey via Modified Fuzzy AHP

International Journal of Energy Economics and Policy | Vol 9 • Issue 2 • 2019 33

by considering interactions among criteria via Choquet integral 
methodology. They concluded that the wind energy is the best 
alternative for Turkey. Kaya and Kahraman (2010) proposed a 
methodology based on an integrated fuzzy AHP-VIKOR method 
to determine the best renewable energy alternative for Istanbul. 
They also used the proposed methodology for selection among 
alternative energy production sites in Istanbul. The following year, 
Kaya and Kahraman (2011) focused on the energy technology 
selection problem for Turkey considering modified fuzzy TOPSIS. 
They determined frequently used criteria in the literature and 
used these criteria while selecting best energy alternatives. They 
suggested wind energy as the best energy alternatives for Turkey. 
Boran et al. (2012) evaluated renewable energy technology for 
Turkey using intuitionistic fuzzy TOPSIS. They considered hydro, 
wind, photovoltaic, and geothermal as the renewable energy 
technologies in Turkey. The results indicated that hydro is the best 
alternative and wind power ranked as the second best alternative 
for Turkey. Erol and Kılkış (2012) developed an AHP method to 
facilitate energy resource planning for Aydın distinct in Turkey. 
They considered geothermal power, lignite, natural gas, wind, 
hydroelectric, and hydrokinetic powers as energy alternatives. 
Solar energy was found as best energy sources. Barış and Küçükali 
(2012), developed a multi-criteria analysis tool to evaluate the 
performance of different RES technologies under technical, 
economic, environmental and social aspects. They suggested 
biaogass as the best possible RES option for Turkey. Demirtaş 
(2013) considered technical, economic, environmental and social 
criteria and applied AHP to determine best renewable energy 
alternatives for Turkey. The results of the study suggested that wind 
energy was the best renewable energy alternative and the ranking 
of the other alternatives in descending order was determined as 
biomass, geothermal, solar and hydropower. Ertay et al. (2013) 
evaluated the renewable energy alternatives; wind, solar, biomass, 
geothermal, and hydropower by using two MCDM methods. The 
ranking order of alternatives obtained by MACBETH is wind, 
solar, biomass, geothermal, hydropower. When they applied 
fuzzy AHP, they concluded the same ranking result. Kabak and 
Dağdeviren (2014) proposed a hybrid model based on analytic 
network process (ANP) and benefits, opportunities, costs and risks 
to determine the energy state of Turkey and to prioritize alternative 
RES. They evaluated five alternatives in terms of nineteen criteria 
and determined hydro power as the best alternative for Turkey. 
Büyüközkan and Güleryüz (2014) aimed to build up a model to 
help investors by prioritizing renewable energy alternatives. They 
suggested a new group decision making approach based on FAHP 
with linguistic interval fuzzy preference and fuzzy TOPSIS. They 
obtained weights of evaluation criteria using FAHP and ranking of 
the alternatives is determined using fuzzy TOPSIS. Şengül et al. 
(2015) presented a multi-criteria decision support framework for 
ranking renewable energy supply systems in Turkey. They used 
Shannon’s entropy methodology to determine criteria weights and 
fuzzy TOPSIS method to prioritize alternatives. They concluded 
that the amount energy produced is the most important criterion 
and hydro power was the most important supply system followed 
by geothermal power, regulator and wind power. Balin and Baraçli 
(2015) offered a MCDM model based on interval type-2 fuzzy 
TOPSIS and interval type-2 fuzzy AHP. They calculated the criteria 
weights by using interval type-2 fuzzy AHP method, and then 

they calculated ranking of alternatives according to the ranking 
vector determined by interval type-2 fuzzy TOPSIS method. 
Kuleli et al. (2015) modeled energy selection problem integrating 
ANP and TOPSIS methods. They considered social, economic, 
and environmental factors and concluded that Hydro energy is 
the most appropriate RES for Turkey. Also, they performed a 
sensitivity analysis to monitor the influence of criteria weights 
on the model results. Erdogan and Kaya (2015) clarified ranking 
of energy alternatives for Turkey by developing an integrated 
FMCDM methodology. They used type-2 fuzzy AHP to weight 
the criteria and then used type-2 fuzzy TOPSIS to rank energy 
alternatives. The results showed that wind energy is the most 
appropriate energy alternatives. Büyüközkan and Güleryüz (2016) 
developed an integrated MCDM model combining the Decision 
Making Trial and Evaluation Laboratory (DEMATEL) and ANP 
methods in order to determine the most suitable renewable energy 
resource for Turkey in Turkey from an investor perpective. Wind 
energy is selected as best renewable energy alternatives for Turkey. 
Çelikbilek and Tuysuz (2016) presented a grey based MCDM 
methodology which integrates DEMATEL, ANP and VIKOR 
methods. Grey DEMATEL is used to determine relations among 
evaluation criteria, grey ANP is used determine the weights of the 
evaluation criteria, and also grey VIKOR is used finally to rank 
renewable energy alternatives. They demonstrated the effectiveness 
of the improved model with the application for RE in Turkey. They 
concluded that solar energy is best alternative followed by wind, 
hydroelectric, biomass, geothermal. Büyüközkan and Güleryüz 
(2017) integrated DEMATEL-ANP-TOPSIS methodologies 
with linguistic interval fuzzy preference relations. The results 
revealed that the best renewable energy technology for Turkey 
was geothermal sources, followed by biogas. Çolak and Kaya 
(2017) proposed a hybrid MCDM method based on AHP with 
interval type-2 fuzzy sets and TOPSIS with hesitant fuzzy sets. 
The ranking of energy alternative is determined as wind, solar, 
hydraulic, biomass, geothermal, wave and hydrogen energy.

3. METHOD

In this paper, an analysis is performed to determine the ranking of 
RES in Turkey. Turkey has significant renewable energy potential, 
whose realizable renewable energy potential is equal to 13% 
of EU-27’s total potential. Turkey’s total electricity generation 
potential from RES is 240,165 GWh/yr for 138,000 MW economic 
potential. Potential for various RES types have important role 
to find a solution to the current economical and environmental 
problems of Turkey (Özcan, 2018. p. 2630).

3.1. Renewable Energy Alternatives and Selection 
Criteria
Turkey has different type of RES potantial. According to 
Turkey’s Ministry of Energy and Natural Resources data, Turkey 
has 144,000 GWh/yr hydro (for 36,000 MW), 14,665 GWh/yr 
geothermal (for 2000 MW), 60,000 GWh/yr wind (for 48,000 
MW), 14,000 GWh/yr biomass (for 2000 MW), and 7500 GWh/yr 
solar (for 50,000 MW) renewable energy potential (Sirin and Ege, 
2012. p. 4922). By considering RES potential in Turkey, RES 
alternatives are determined as hydro energy, wind, solar, biomass 
and geothermal. Hydro energy exploits the potential energy 



Karakaş and Yildiran: Evaluation of Renewable Energy Alternatives for Turkey via Modified Fuzzy AHP

International Journal of Energy Economics and Policy | Vol 9 • Issue 2 • 201934

that is contained in flowing waters like rivers and reservoirs in 
mountainous regions (Büyüközkan and Güleryüz, 2017. p. 151). 
The potential of hydropower resource relies on the amount of 
available water and suitable land. Hydropower potential for Turkey 
is not yet to be exploited fully. The goal of the Turkish government 
is to utilize all technically and economically available hydropower 
by 2023 (Melikoğlu, 2013. p. 504).

Solar energy is obtained by collecting sunlight through solar or 
photovoltaic cells, and then focused with mirror to create a high-
intensity heat source which runs a generator to produce electricity. 
Solar energy can be utilized for cooling, lighting, heating and other 
energy demands (Kabak and Dağdeviren, 2014. p. 26). Turkey 
has high solar energy potential due to its geographical location. 
According to the solar energy map of Turkey prepared by the 
Renewable Energy General Directorate, it has been determined that 
the total annual insolation time is 2741 h (a total of 7.5 h per day), 
and the total solar energy derived per year is 1527 kWh/m2 per 
year (total 4.18 kWh/m2 per day). As of the end of 2017, there 
were 3616 solar power plants with a total installed capacity of 
3421 MW. This is the equivalent of 4% of the total potential. In 
2017, electricity production based on solar energy have realized 
2684 GWh and 0.91% of our electricity production was obtained 
from solar energy (http://www.enerji.gov.tr/en-US/Pages/Solar, 
02.07.2018).

Wind energy is derived from air masses encountering different 
temperature ranges and is converted to electricity by means 
of wind turbines. By the end of 2017, installed wind power in 
Turkey reached 6516 MW. This is the equivalent of 7.6% of the 
total potential. In 2017, electricity production from wind energy 
have realized 17,909 GWh and 6.06% of electricity production 
was obtained from wind energy (http://www.enerji.gov.tr/en-US/
Pages/Wind, 02.07.2018).

Biomass can be defined as the total mass of living organisms that 
belong to a society consists of species or consist of several species. 
Biomass is also defined as an organic carbon. Biomass potential in 
Turkey is estimated about 8.6 million tonnes of equivalent petrol 
(MTEP), and biogas quantities that can be produced from biomass 
is 1.5–2 MTEP. As of the end of 2017, there were 122 renewable 
waste power plants with a total installed capacity of 634.2 MW. 
This is the equivalent of 0.7% of the total potential (http://www.
enerji.gov.tr/en-US/Pages/Bio-Fuels, 02.07.2018).

Geothermal power is the energy generated by heat stored beneath 
the Earth’s surface or the collection of absorbed heat derived from 
underground in the atmosphere and oceans (Kahraman and Kaya, 
2010. p. 6271). Turkey has important geothermal potential for its 
direct use and for electricity generation. With the end of the year 
2017, there were 40 geothermal power plants with a total installed 
capacity of 1,064 MW (http://www.enerji.gov.tr/en-US/Pages/
Geothermal, 02.07.2018).

In the evaluation phase, these RES alternatives are assessed in 
light of four main criteria and eight sub criteria. The criteria are 
determined with respect to relevant literature. Kaya and Kahraman 
(2011) introduced the most frequently used criteria by considering 

the criteria used in the literature. We also used these main and 
subcriteria, and the descriptions of the criteria are given as follows.

Efficiency (C11): Efficiency refers to how much useful energy can 
be extracted from an energy source and is measured generally using 
efficiency ratio. Efficiency ratio is defined as the ratio of output 
energy to input energy (Kaya and Kahraman, 2011; Mourmouris 
and Potolias, 2013). Exergy efficiency (C12): Exergy efficiency 
or rational efficiency investigates the efficiency of a renewable 
energy technology regarding to the second law of thermodynamics. 
It means there is always an exergy loss when a process involves 
a temperature change. Exergy is the net energy that is left to be 
used (Kaya and Kahraman, 2011. p. 6582).

Investment cost (C21): Investment cost includes all type of cost 
occurred for establishing the energy technology such as engineering 
services, road construction or other construction work, purchase of 
mechanic equipment, legislative authorization (Büyüközkan and 
Güleryüz, 2017; Mourmous and Potolias, 2013). Operation and 
maintenance cost (C22): Operation and maintenance cost includes 
all production costs that are associated with running a power plant. 
The components of operations costs are salaries, energy expenses, 
expenditure on products and services. Also, maintenance costs are 
the funds spent to ensure reliable plant operations and to avoid 
failure and damage (Büyüközkan and Güleryüz, 2017; Kaya and 
Kahraman, 2011).

Particles emmision (C31): Particle emission criterion consists of gas 
release to atmosphere, such as CO2, N2O and CH4, which are the 
results of combustion process, liquid wastes related to secondary 
products by fumes treatment or with process water, and solid wastes. 
The evaluation of the criteria includes type and quantity of emissions, 
and costs associated with wastes treatments. Also the electro-magnetic 
interferences, bad smells, and microclimatic changes for energy 
investment are taken into account while evaluating this criterion 
(Kahraman and Kaya, 2010; Kahraman et al., 2009). Land Use (C32): 
Energy systems need some land to be built, however different energy 
systems may occupy different land while the products are same. The 
environment and landscape are affected directly by the land occupied 
by energy systems (Wang et al., 2009). A strong demand for land can 
also determine the economic losses (Kahraman et al., 2009).

Social acceptability (C41): Social acceptability is defined as the 
overview of opinions related to the energy systems by the local 
population. The overall opinion of local populations and of pressure 
groups can heavily influence the progress with investment decisions. 
Social acceptance could not be expressed by quantitative way but 
qualitative. To transforming qualitative decisions into quantitative, 
survey method could be used (Büyüközkan and Güleryüz, 2017; 
Wang et. al., 2009). Job creation (C42): Job creation includes direct 
and indirect employment, as well as creation of new professional 
areas indirectly. Energy systems employ many people during their 
life cycle, from construction and operation till decommissioning. 
Job opportunities for local societies improve the living quality of 
local people. However each energy source creates different job 
opportunities and decision makers should select energy source 
and plant type by considering local community (Büyüközkan and 
Güleryüz, 2017; Wang et. al., 2009).



Karakaş and Yildiran: Evaluation of Renewable Energy Alternatives for Turkey via Modified Fuzzy AHP

International Journal of Energy Economics and Policy | Vol 9 • Issue 2 • 2019 35

By considering the RES potential in Turkey, energy alternatives are 
evaluated from environmental, socio-political, economic, technical 
and technological aspects by experts. Figure 1 shows hierarchical 
structure of energy decision making problem. Three experts are 
utilized to evaluate the considered criteria and alternatives with 
respect to Figure 1. One of them is an academic in Energy Systems 
Engineering Department and the others have work experience on 
energy policy and planning. Equal weight was given to each expert.

3.2. The Fuzzy AHP Method
In this study the Fuzzy AHP method proposed by Aydın and 
Kahraman (2011) is utilized. The researchers slightly revised their 
triangular fuzzy scale in their later studies (Aydın and Kahraman, 
2018). We use this fuzzy scale as given in Table 1.

The procedure of the Fuzzy AHP method can be explained as 
follows (Aydın and Kahraman, 2011; Aydın and Kahraman, 2018).

The weights (e) are allocated to experts on the basis of their 
knowledge, experience, etc. Suppose that m experts exist in the 
group and the kth expert is Ek is assigned an expert weight ek,

Where ek ϵ[0,1], e1+e2+...+em = 1 (1)

To obtain a group preference from individual preferences, the 
aggregation of TFNs scores is performed as following equation:

1 1 2 2ˆ ˆ ˆ ˆij ij ij ijm me e ea a a a⊕ ⊕…= ⊗ ⊗ ⊗ (2)

Where aij  is the aggregated fuzzy score from all comparisions. 
aij1 , aij2 … aijm  are corresponding TFN scales assigned by experts 

E1, E2,…Em, respectively. ⊗ and ⊕ symbols refer fuzzy 
multiplication and fuzzy addition operators, respectively.

As known, the scores in the classical AHP method are also based 
an exponantial importance. So, to convert negative fuzzy TFNs 

to positive TFNs, corresponding exponantial values of negative 
scores are calculated. The conversion is obtained by following 
equation.

ˆ
( )* 4

ija

ija e= (3)

Where a l m uij ij ij ij= ( , , )

Triangular fuzzy comparision matrix is demonstrated by,

( ) ( ) ( )
( ) ( ) ( )

( ) ( ) ( )

12 12 12 1 1 1

21 21 121 2 2 2

1 1 1 1 1

1,1,1 , , , ,
, , 1,1,1 , ,

, , , , 1,1,1

n n n

n n n
ij

n n ij n n n

l m u l m u
l m u l m u

A a

l m l l m u

 …
 

… 
= =  

 
 … 

   





(4)

Where a l m uij ij ij ij= ( ), ,  and a u m lij ij ij ij
− =1

1 1 1
( , , )  for i,j=1,…,n 

and i≠j. A normalized matrix N  is calculated,



N nij ij m n=
  ×

(5)

N
l

u

m

u

u

u
ij

ij

j

ij

j

ij

j
=










* * *
, , (6)

u uj
i

ij
*

max= (7)

The importance weights of the factors are calculated ussing 
following equation:

1'

1 1

         1, 2,

n
ijj

i n n
kjk j

n
W k n

n

=

= =

= = …
∑

∑ ∑


(8)

GOAL: Selecting the best 

renewable energy resource 
for Turkey 

C1: Technical C2: Economic C3:Environmenta C4: Social 

C11: Efficiency 
C12 : Exergy 

efficiency 

C21: Investment Cost
C 2 2 :Operation and 

Maintenance Cost 

C31: Particle Emmision
C 3 2 : Land Use 

C41: Social 

Acceptability 
C42: Job Creation 

Hydro 

Energy

Wind 

Energy

Solar 

Energy

Biomass 

Energy

Geothermal 
Energy

Figure 1: A Hierarchy for Selection of the most appropriate renewable energy resources for Turkey



Karakaş and Yildiran: Evaluation of Renewable Energy Alternatives for Turkey via Modified Fuzzy AHP

International Journal of Energy Economics and Policy | Vol 9 • Issue 2 • 201936

The rating of each alternative is multiplied by the weights of the 
sub-criteria and aggregated to get local ratings with respect to each 
criterion. The local ratings are then multiplied by the weights of 
the criteria and aggregated to obtain global ratings.

In the last step, we rank the obtained fuzzy numbers. In order 
to rank the fuzzy numbers, we use the signed distance value 
developed by Yao and Wu (2000).

4. RESULTS AND DISCUSSION

As referred, mainly five RESs (hydro energy, wind, solar, biomass 
and geothermal) alternatives have exploting possibilities on 
Turkey. As known, first step of any multicriteria approach is 
defination of alternatives and criteria. The definition of alternatives 
and the evaluation criteria are previously described. The second 
step is the weighting of each criterion to express their relative 
importance. Comparison matrix of main citeria is given in Table 2. 
To analyze the consistency of the fuzzy pair-wise comparison 
matrices, we converted the fuzzy numbers into crisp numbers 
using a defuzzification technique. Many techniques are used for 
defuzzification in the literature. The most used approaches are 
Mean-of-Maximum, Center-of-Area, and Alpha-cut Method (Zhao 
and Govind, 1991). In this study, we utilized the Center-of-Area 
method because of its calculation easiness (Yalcın et al., 2012).

After obtaining the aggregation of TFNs scores using Eq. 2, we 
converted negative fuzzy numbers in Table 2 to positive fuzzy 
numbers via Eq. 3. As a result, the comparision matrix is revised 
as Table 3.

Then, normalized matrix given in Table 4 is obtained using Eqs. 5-7.

Finally, we obtained importance weights of main criteria by using 
Eq. 8.

( ) ( )
( ) ( )

' '
1 2

' '
3 4

0.170, 0.284, 0.535 ,  0.060, 0.096, 0.179 ,

 0.279, 0.505, 0.816 ,  0.061, 0.113, 0.216
C C

C C

W W

W W

= =

= =

We found that experts considered the criterion of ‘environmental’ 
more important than others. Also, the second important criterion 
was determined as “technical.” This result means the experts were 
more interested in environment and technical factors. The same 
procedures are repeated for the sub-criteria and the weights of 
the sub-criteria are calculated as in the following Tables 5 and 6.

All the importance weights of the hierarchy have been calculated 
as following the same steps, and finally importance weights of the 
alternatives are obtained and given in Table 7.

According to Table 7, the ranking of the alternatives from the best 
to the worst is solar, wind, geothermal, hydropower and biomass. 
So, the best renewable alternative in Turkey is solar energy. This 
result is also parallel with the finding of Erol and Kılkış (2012) and 
Celikbilek and Tuysuz (2016). Solar energy has many advantages. 
It causes no emissions like carbon dioxide, nitrogen oxide or 
sulphur oxide. Although, the initial cost of a solar system is high, 
maintenance cost of solar system is very low. Also, technology 

of solar energy is continuously developing regarding innovations 
in nanotechnology. Technological development probably would 
increase the effectiveness of solar system and and decrease in 
investment cost in near future. Among the alternative RES in 
Turkey, the most important one is solar energy. Turkey has more 
chance than the other countries in terms of solar energy potential 
due to its geographic situation (Balat, 2005). Result of the study 
also confirms that solar energy is the most suitable alternative 
to meet growing energy demand. In addition, the second best 
alternative is wind energy. The main advantages of wind energy is 
that it does not harm the environment, the production of electricity 
with wind energy does not cause to the CO2 emissions, acid rain 
and atmospheric warming (Erdogan and Kaya, 2015). Also, wind 
energy may play a critical role in both strengthening energy 
security of Turkey and thus decreasing energy dependency. Some 
RER selection publications for Turkey (Kahraman et al., 2009; 
Kahraman et al., 2010; Kaya and Kahraman, 2011; Ertay et al., 
2013; Çolak and Kaya, 2017) concluded that the second best 
alternative is solar energy after wind energy. Both solar and wind 
energy are very important to realize Turkey’s RER energy targets.

Taking economic potential of renewable resource into account, 
the utilization rate of wind power and solar power is very low. As 
mentioned before, there were 3616 solar power plants with a total 
installed capacity of 3421 MW, which is the equivalent of 4% of 
the total potential. Also, by the end of 2017, installed wind power 
in Turkey reached 6516 MW. This is the equivalent of 7.6% of the 
total potential. Therefore, it can be seen that utilization rate of both 
solar and wind energy alternatives are very low when compared 
to their potential. Also, Turkey has also attained 21.41% of its 

Table 1: Triangular fuzzy coversion scale
Linguistic scale Triangular 

fuzzy scale
Triangular fuzzy 
reciprocal scale

Just equal (0,0,0) (0,0,0)
Weakly important (0,1,3) (−3,−1,0)
important (1,3,5) (−5,−3,−1)
Strongly more important (3,5,7) (−7,−5,−3)
Very strongly more important (5,7,9) (−9,−7,−5)
Absolutely more important (7,9,9) (−9,−9,−7)
Source: Aydın and Kahraman, 2018

Table 2: Comparison matrix of main criteria
Expert Weight C1 C2 C3 C4
C1

1 0.3333 (0,0,0) (1,3,5) (0,1,3) (0,1,3)
2 0.3333 (0,0,0) (7,9,9) (0,1,3) (1,3,5)
3 0.3333 (0,0,0) (1,3,5) (−9,−9,−7) (3,5,7)

C2
1 0.3333 (−5,−3,−1) (0,0,0) (−5,−3,−1) (0,0,0)
2 0.3333 (−9,−9,−7) (0,0,0) (−9,−9,−7) (−3,−1,0)
3 0.3333 (−5,−3,−1) (0,0,0) (−9,−9,−7) (1,3,5)

C3
1 0.3333 (−3,−1,0) (1,3,5) (0,0,0) (3,5,7)
2 0.3333 (−3,−1,0) (7,9,9) (0,0,0) (5,7,9)
3 0.3333 (7,9,9) (7,9,9) (0,0,0) (3,5,7)

C4
1 0.3333 (−3,−1,0) (0,0,0) (−7,−5,−3) (0,0,0)
2 0.3333 (−5,−3,−1) (0,1,3) (−9,−7,−5) (0,0,0)
3 0.3333 (−7,−5,−3) (−5,−3,−1) (−7,−5,−3) (0,0,0)



Karakaş and Yildiran: Evaluation of Renewable Energy Alternatives for Turkey via Modified Fuzzy AHP

International Journal of Energy Economics and Policy | Vol 9 • Issue 2 • 2019 37

2023 target in wind energy and 4.52% of its 2023 target in solar 
energy (Özcan, 2018. p. 2635). So, increasing the utilization rates 
of wind and solar energy would make an important contribution 
to realize Turkey’s 2023 renewable energy targets.

According to the result, geothermal energy is the third best energy 
alternatives and its score is very close to wind energy. Economic 
potential of geothermal energy is estimated to be 2000 W, with an 
annual average generation potential of 14,665 GWh/yr (Özcan, 
2018. p. 2635) and as of the end of 2017, there are 40 geothermal 
power plants with a total installed capacity of 1,064 MW. This is 
the equivalent of 1.2% of the total potential (http://www.enerji.
gov.tr/en-US/Pages/Geothermal, 02.07.2018). The government 
aims to achieve 1000 MW installed power by the year 2023 
(Özcan, 2018. p. 2635). In this case, it seems that the government 
has already achieved its 2023 target for geothermal energy. 
However, the utilization rate of geothermal energy is still low 
when taken into account of the total potential. For this reason, it 

may be an option to update targets related to geothermal energy 
in the future.

5. CONCLUSIONS

Awareness of renewable energy importance on both environment 
and energy security has been increasing in Turkey. In parallel, 
Turkey government aims to produce 30% of Turkey’s electricity 
demand in 2023 from RES. Therefore, the determination of the 
most suitable renewable energy alternative is an important issue to 
plan energy investment. In this study, the evaluation of renewable 
energy resources in Turkey accomplished via modified fuzzy 
AHP method proposed by Aydın and Kahraman (2011; 2018). 
There are two mains reasons for the use of the revised fuzzy AHP 
method. Firstly, this method use both positive fuzzy numbers 
and negative fuzzy numbers in fuzzy scale and thus it presents 
more understandable scales for comparing alternatives. Secondly, 
this method is very easy to apply because it is based on simple 
arithmetic operations of fuzzy numbers. Also, this study also 
demonstrates the effectiveness and applicability of revised fuzzy 
AHP method, which has been newly published and less known.

The energy alternatives considered in the study are hydro, wind, 
solar, biomass and geothermal, which are mentioned in Turkey’s 
2023 energy targets. Renewable energy alternatives were evaluated 
by considering four main criteria and eight sub criteria. The criteria 
are determined with respect to relevant literature. The results 
suggested that experts consider the criterion of “environmental” 
more important than others. Also, the second important criterion 
was determined as “technical.” This result means that the experts 
were more interested in environmental and technical factors. After, 
weights of the criteria are calculated, the ranking of alternatives are 
determined as solar, wind, geothermal, hydropower and biomass 
in descending order. The results are also parallel with some similar 
studies in the literature. Although their order changes, wind energy 
and solar energy have been found to be the most suitable renewable 
energy alternatives in most of the studies for Turkey. Because 
the utilization rates of these resources are low, increasing the 
utilization rates of wind and solar energy would make an important 
contribution to realize Turkey’s 2023 renewable energy targets.

In the future research, we are planning to carry out a mathematical 
model in order to determine optimal investment amount for each 

Table 3: Aggregated fuzzy comparision matrix for main criteria
C1 C2 C3 C4

C1 (1,1,1) (2.117,3.490,4.871) (0.472,0.558,0.920) (1.395,2.117,3.490)
C2 (0.205,0.287,0.472) (1,1,1) (0.147,0.174,0.287) (0.846,1.181,1.516)
C3 (1.086,1.792, 2.117) (3.490,5.754,6.798) (1,1,1) (2.500,4.123,6.798)
C4 (0.287, 0.472,0.716) (0.659,0.846,1.181) (0.147,0.242,0.399) (1,1,1)

Table 4: Normalized fuzzy comparision matrix for main criteria
C1 C2 C3 C4

C1 (0.472,0.472,0.472) (0.311,0.513,0.716) (0.472,0.558,0.920) (0.205,0.311,0.513)
C2 (0.096,0.135,0.223) (0.147,0.147,0.147) (0.147,0.174,0.287) (0.124,0.174,0.223)
C3 (0.513,0.846, 1) (0.513,0.846,1) (1,1,1) (0.368, 0.607,1)
C4 (0.135, 0.223,0.338) (0.096,0.124,0.173) (0.147,0.242,0.399) (0.147,0.147,0.174)

Table 5: Fuzzy weights of main criteria
Main criteria Fuzzy weights Signed distance value
C1 (0.170,0.284,0.535) 0.318
C2 (0.060,0.096,0.179) 0.108
C3 (0.279,0.505,0.816) 0.526
C4 (0.061,0.113,0.216) 0.126

Table 6: Fuzzy weights of sub‑criterisa
Sub-criteria Fuzzy weights
C11 (0.313,0.417,0.582)
C12 (0.437,0.582,0.747)
C21 (0.611,0.871,1.215)
C22 (0.089,0.128,0.211)
C31 (0.460,0.679,0.947)
C32 (0.217,0.320,0.529)
C41 (0.595,0.851,1.187)
C42 (0.103,0.148,0.244)

Table 7: Importance weights of alternatives
Alternatives Fuzzy weights Signed distance value
Hydro (0.0433,0.174,0.768) 0.289
Wind (0.054,0.236,0.994) 0.380
Solar (0.062,0.275,1.139) 0.439
Biomass (0.028,0.122,0.587) 0.150
Jeothermal (0.047,0.193,0.839) 0.318



Karakaş and Yildiran: Evaluation of Renewable Energy Alternatives for Turkey via Modified Fuzzy AHP

International Journal of Energy Economics and Policy | Vol 9 • Issue 2 • 201938

renewable alternatives taking into account weights of alternatives 
obtained in the study.

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