Energy Storage for Energy Security and Reliability through Renewable Energy Technologies: A New Paradigm for Energy Policies in Turkey and Pakistan


sustainability

Article

Energy Storage for Energy Security and Reliability through
Renewable Energy Technologies: A New Paradigm for Energy
Policies in Turkey and Pakistan

Riaz Uddin 1,*, Hashim Raza Khan 2, Asad Arfeen 3 , Muhammad Ayaz Shirazi 1, Athar Rashid 4

and Umar Shahbaz Khan 5

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Citation: Uddin, R.; Raza Khan, H.;

Arfeen, A.; Shirazi, M.A.; Rashid, A.;

Shahbaz Khan, U. Energy Storage for

Energy Security and Reliability

through Renewable Energy

Technologies: A New Paradigm for

Energy Policies in Turkey and

Pakistan. Sustainability 2021, 13, 2823.

https://doi.org/10.3390/su13052823

Academic Editor: Vincenzo Bianco

Received: 13 January 2021

Accepted: 20 February 2021

Published: 5 March 2021

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Attribution (CC BY) license (https://

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4.0/).

1 Haptics, Human-Robotics and Condition Monitoring Lab (National Center of Robotics and Automation),
Department of Electrical Engineering, NED University of Engineering & Technology, Karachi 75270, Pakistan;
mshirazi@ee.knu.ac.kr

2 Neurocomputation Lab (National Centre of Artificial Intelligence-NCAI), Department of Electronic
Engineering, NED University of Engineering & Technology, Karachi 75270, Pakistan; hashim@neduet.edu.pk

3 Department of Computer and Information Systems Engineering, NED University of Engineering &
Technology, Karachi 75270, Pakistan; arfeen@neduet.edu.pk

4 Department of Governance and Public Policy, National University of Modern Languages,
Islamabad 44000, Pakistan; atharrashid@numl.edu.pk

5 Department of Mechatronics Engineering, College of E&ME, National University of Sciences and Technology,
Islamabad 46000, Pakistan; u.shahbaz@ceme.nust.edu.pk

* Correspondence: riazuddin@neduet.edu.pk

Abstract: Forecasting the microeconomics of electricity will turn into a challenging process when
electricity is produced through renewable energy technologies (RET). These technologies are mainly
sunlight-based photovoltaic (PV), wind power, and tidal resources, which vigorously rely upon
ecological conditions. For a reliable and livable energy supply to the electricity grid from renewable
means, electrical energy storage technologies can play an important role while considering the
weather effects in order to provide immaculate, safe, and continuous energy throughout the genera-
tion period. Energy storage technologies (ESTs) charge themselves during the low power demand
period and discharge when the demand of electricity increases in such a way that they act as a catalyst
to provide energy boost to the power grid. In this paper, we presented and discussed the renewable
ESTs for each type with respect to their operational mechanism. In this regard, the renewable energy
scenarios of Pakistan and Turkey are first discussed in detail by analyzing the actual potential of each
renewable energy resource in both the countries. Then, policy for the EST utilization for both the
countries is recommended in order to secure sustainable and reliable energy provision.

Keywords: renewable energy technologies; electricity storage system; sustainable energy; reliable
energy; energy policy

1. Introduction

For secure, reliable, and sustainable energy production, electricity storage technologies
(ESTs) play a vital role in the implementation of renewable energy technologies [1]. ESTs
provide several benefits, services, and smooth reliable operation to off-grid systems [2].
Through the services provided by the ESTs, smooth operations will certainly improve
the power quality, reliability, strength, and competitiveness of the deployed renewable
energy technologies (RET) [2–4]. Various ESTs [5] provide an overview and the detailed
explanation of each energy storage technology by comparing the battery storage system
in-terms of technical and economical features. In this regard, the work [6] compares
the lead acid battery with lithium ion battery in terms of capacity fading and partial
charging of batteries. It describes the procedure of battery testing in off-grid renewable
energy applications.

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Several approaches were also proposed in the modeling of the battery. The work [7]
developed twelve models of lithium ion batteries. The datasets of each models were
collected under three different temperatures of two lithium ion cell by utilizing swarm
optimization algorithm. The algorithm derived the optimal model parameters of the
two types of lithium ion cell. In research [8], the techniques to determine the internal
resistance of electro-chemical batteries are defined, such as lead acid, lithium ion, nickel
metal-hydride, and electrochemical double layer capacitors-based batteries. The study
also compares the ohmic resistance and dynamic internal resistance of the electrochemical
batteries. Similarly, the work [9] developed the battery model/energy storage system
and derived the parameters through a manufacturer’s data sheet by simulating it via
the SimPowerSystems (SPS) simulation software tool. The tool integrated the model of
battery and performed complete analysis through simulation of hybrid electric vehicles
power train. Study [10] reviewed the battery modeling of electric vehicles by changing
its dimension from lithium ion battery to lithium sulphur batteries. It also discussed in
detail the challenges for the deployment of lithium sulphur batteries on electric vehicle
application. Work [11] carried out the modeling and simulation of the battery storage
technologies, while deriving the size result of battery energy storage (BES) for residential
areas of electricity peak shaving. In addition, the study [12] used the particle swarm
optimization algorithm to find the parameter of the lithium-ion battery in order to define
the battery model in healthy or degraded state.

Study [13] described each energy storage technology and compared the energy storage
technologies in terms of efficiency, energy capacity, energy density, capital cost, response
time, self-discharge, and life cycles in order to improve the energy security. Analysis [14]
briefly clarifies the storage scheme using batteries and through recreation of the photo-
voltaic framework and HOMER (a computer model developed by National Renewable
Energy Lab (NREL)), the real price of solar panel, lead acid, nickel-cadmium, NiMH, and
Li-ion batteries were inferred. Research [5] explained the battery storage technologies in
detail and investigated their application in power systems. Research [15] compared the bat-
tery, ultra-capacitors, and fuel cell technologies for hybrid and plug-in hybrid vehicles by
composing the hybrid electricity storage system through the utilization of ultra-capacitor,
battery, and fuel cell technologies. Another study [16] compared and discussed the en-
ergy storage technologies and briefly explained the applications of the energy storage
technologies by highlighting its maturity level and potential level to connect the storage
technologies, whereas the work [17] did the cost-benefit analysis of electrical storage system
by focusing on the capital cost, operation, maintenance, and replacement cost. Similarly,
work [18] presents a review on several electricity storage technologies suitable for wind
power application.

In the research [19], the literature talks about the life cycle assessment and metrics for
calculation of input energy requirement and emission of greenhouse gas. It was developed
for energy storage systems and applied to energy storage technologies, such as pump
hydro storage (PHS), compressed air energy storage (CAES), and battery storage systems
with vanadium and sodium poly sulphide type as electrolytes. The study also revealed
that greenhouse gas emission by these storage systems will be lower when coupled with
nuclear or renewable resources as compared to fossil fuel resources. Further, PHS gives
lower greenhouse gas emission when integrated to nuclear or renewable energy resources,
whereas CAES emits lower greenhouse gas emissions when integrated with fossil fuel
resources as compared to PHS and battery energy storage (BES).

The world desperately needs to de-carbonize the global energy sector in order to limit
the effects of climate change by shifting towards renewable energy resources from fossil
fuel [20]. As the contribution of renewable energy technologies in the global power genera-
tion increases rapidly, there is a dire need for energy storage systems. For improvement
of power quality, proper provision to maintain the voltage level and constant frequency
in energy storage technologies is required for the deployment of sustainable renewable
energy technologies [1,21]. After reviewing the above-mentioned ESTs, it is necessary to



Sustainability 2021, 13, 2823 3 of 17

identify the optimum electricity storage technology to render the cost effective services
and benefits to the power grid. Based on this scenario, the energy storage for energy
security and reliability through RETs is studied for the case of Turkey and Pakistan. In this
connection, we have the following objectives of this research:

• The detailed study and comparison of renewable ESTs for each type with respect to
their operational mechanism.

• Discussion of the renewable energy scenarios of Pakistan and Turkey to analyze the
actual potential of each renewable energy resource.

• Proposal and recommendation of the policy for the ESTs application suggested for
both nations to secure feasible and trusted power supply arrangement.

The remaining part of the paper is organized as: Section 2 describes various ESTs and
their deployment in the power sector along with discussion and comparison of different
ESTs. Section 3 comprises renewable energy scenarios of Pakistan and Turkey. Section 4
states energy targets and storage policy along with energy storage policy recommendation
for both the countries. Section 5 draws conclusions of the conducted study with the focus
on policy recommendations.

2. Energy Storage Technologies (EST)

A power repository system is broadly considered and installed in progressive nations
of Europe, Asia, and Australia for the arrangement of smooth, reasonable, and low-cost
power supply to the particular local distribution frameworks [21]. Power storage technolo-
gies are essentially divided into six categories depending on its development and utilization.
Therefore, Figure 1 portrays the number of ESTs accessible around the world, which can be
utilized for diverse applications of power distribution to the end user depending upon the
benefits and draw backs of each technology.

Figure 1. Electricity storage technologies (ESTs) [17].

Considering the latest updates, most the developed nations, which are equipped with
energy storage technology, have made the best use of a battery storage scheme, a pumped
hydro storage scheme, and a thermal storage scheme in their agenda to supply low cost,
maintainable, reasonable, and smooth power supply to end users. Figure 2 shows the cost
summary of electrical energy storage technologies as TCC (total capital cost), while the



Sustainability 2021, 13, 2823 4 of 17

global capacity share of each storage technology utilized by different countries (i.e., specific
storage/total) in terms of capacity and deployment ratio is depicted in Figure 3 [22]. As
shown in Figure 2, the lowest cost is recorded for the case of super-capacitors-based energy
storage systems. Figure 3 concludes that molten salt thermal storage covers the highest
capacity and the deployment ratio, i.e., 2.5 GW and 75%, respectively.

Figure 2. Cost summary of electrical energy storage technologies [17].

Figure 3. Global operational electricity storage power capacity by technology [22].

2.1. Different ESTs with Implementation in Power Sector

Electricity storage system plays an important role by deploying electricity storage
technologies in different locations of power systems in order to provide safe, reliable, and
affordable electricity [2]. Charging/discharging of storage technologies plays a significant
part in short and long interval of time for energy storage capacity. It also depends on
high/low output power to the power grid. ESTs mainly depend upon its charge and
discharge time, which takes seconds to hours to charge and discharge completely [23].
Moreover, each EST is best suited for particular application of KW level to GW power of
the system requirement. For bulk energy storage, PHS and CAES are most suitable for
this application due to its discharge time for tens of hours economically [14,17]. On the



Sustainability 2021, 13, 2823 5 of 17

other hand, flywheel energy storage technology discharges (10 KW–900 KW), high power
super-capacitor storage discharges (10 KW–1 MW), and superconducting magnetic energy
storage discharge (1 MW–10 MW) in a very short period of time, i.e., few seconds, but
with rapid high power rating, which makes it suitable for UPS (uninterruptible power
supply) application or improves the quality of power [14,17]. Similarly, flow batteries
like zinc-chlorine flow battery, zinc air flow battery, zinc bromine flow battery, vanadium
redox flow battery, and polysulfide bromine flow battery charges and discharges the power
rating from 10 KW–10 MW. It also takes hours to discharge at rated power [5,11,14]. In
addition, high temperature battery sodium sulphur (NaS) takes hours to discharge at
rated power from 1 MW to 15 MW. On the other hand, lithium-ion battery discharges at
(1 KW–1 MW), lead acid batteries (1 KW–12 MW), high energy super-capacitors storage
(1 KW–10 KW), advanced lead acid battery (100 KW–10 MW), nickel cadmium battery
(1 KW–100 KW), sodium nickel chloride battery (100 KW–5 MW), and nickel-metal hydride
battery (1 KW–1MW) mainly take minutes to discharge at rated power in order to provide
the services to the grid [5,11,14].

Electricity storage systems can be used in three main segments of the electricity sector
named as grid services, behind the meter application, and off-grid applications. Below, we
briefly describe different ESTs regarding the suitability of electricity storage technology for
different applications in these three main segments of electricity sector:

• Pumped hydro storage technology is suitable for frequency restoration reserve, energy
shifting/load leveling and island grid applications [17].

• Compressed air energy storage technology is best suited for frequency restoration
reserve, energy shifting/load leveling and island grid application [17].

• Fly wheel storage technology suits for the application to enhance frequency re-
sponse, frequency containment reserve, increased power quality, peak shaving, and
island grid.

• Flooded lead acid storage batteries and valve-regulated lead acid batteries are suitable
to enhance frequency response, frequency containment reserve, self-consumption for
small residential (community) storage, increased power quality, peak shaving, time of
use, nano-off grid, village electrification, and island grid.

• Lithium-ion storage batteries stand ideal for enhancement of frequency response,
frequency containment reserve, self-consumption for small residential (community)
storage, increased power quality, peak shaving, time of use, nano-off grid, village
electrification, and island grid applications [6].

• Sodium nickel chloride storage battery is best suited for enhancing frequency response,
frequency containment reserve, community storage, increased power quality, peak
shaving, time of use, village electrification, and island grid applications [5,17,24].

• Vanadium redox flow battery is ideal application for frequency restoration reserve,
energy shifting/load leveling, self-consumption for small residential (community)
storage, peak shaving, time of use, village electrification, and island grid applica-
tion [17].

• Zinc bromine flow battery is ideal for applications such as self-consumption for small
residential areas, community storage, time of use, village electrification, and island
grid [6,11].

2.2. Discussion and Comparison on Different ESTs

Pumped hydro storage (PHS) technology is usually used in peak demand of electricity
to reduce the power generation cost. Presently, PHS plays an important role in storing the
energy worldwide, which constitutes 96% share of world’s generation (169 GW capacity).
An additional benefit of PHS technology is the low discharging rates at idle scenario and it
can also store energy for a longer period of time as compared to electro-mechanical flywheel
energy storage technology. The drawback of the flywheel energy storage technology is its
high discharge rates at idle scenario. On the other hand, it also provides high power ratings
in terms of voltage regulations and frequency within the electricity system [25]. Hydrogen



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ammonia storage technology has gained attention in terms of reliable and efficient means
available, irrespective of the region, policies, and conditions. This storage technology can
be utilized to gain the maximum output for energy storage as well as to store the energy
for a longer period of time. In case of bulk power generation, we can store energy by using
the hydrogen ammonia technology and utilize it according to demand for a longer period
of time. In order to compare ESTs in different common specifications, Table 1 provides a
useful analysis of all technical indicators, which details the five different energy storage
systems separately according to their features, capacities, and issues [17].

Table 1. Comparison of technical indicators of ESTs [17].

Storage Systems

S.No
Technical
Indicators

Pumped
Hydro Storage

(PHS)

Compressed Air
Energy Storage

(CAES)

Flywheel
Energy Storage

Electrochemical
Battery Energy
Storage (BES)

Hydrogen
Based Storage

1
Commercially

proven
Yes Yes

R & D
proven

Initial stage
Ready to

implement

2 Power Capacity 100–2000 MW
About 3–15MW (with
2–4 h discharge time)

200 KW
flywheel EES
and store 5

kWh for a few
seconds

Capacity of 10
MW with 4 h as
the discharging

time

Ready to
implement

3
Operational

Cost
4.6 €/kW-year

No significant
reduction of cost

5.2 €/kW-year
Between 3.2

and 13
€/kW-year

Initial stages

4
Construction

and Installation
costs

Average costs
1406 €/kW

Average costs 893
€/kW

Average costs
867 €/kW

Average costs
2512 €/kW

(Li-ion
batteries)

The capital
costs of

electrolysis
itself varies in

different
applications.

5 Efficiency 0.70–0.82 0.70–0.90 0.93–0.95
0.85–0.95
(Li-ion

Batteries)

Net electrolysis
efficiency up to

83%

Until now, 42 countries have fully utilized the pumped hydro storage technology in en-
ergy transition for secure, affordable, and reliable energy provision to their consumers [22,26].
In this regard, China stands as a leading case with a large capacity of PHS technology
(32 GW) followed by Japan (28 GW capacity). The data for other countries includes USA
(23 GW), Spain (8 GW), Italy (7 GW), and the lowest capacity of energy storage through
PHS among 42 countries is reported for Denmark, whereas, non-PHS storage stands at
162 GWh (2017). Thermal storage capacity (TSC) is 3.3 GW (1.9%) in the recent scenario,
electro-chemical battery capacity is 1.9 GW (1.1%), and electro-mechanical storage battery
capacity is 1.6 GW (0.9%) [26]. The shared capacity of ESTs with respect to top coun-
tries are as follows: China (electro-chemical capacity 0.1 GW, TSC 0.1 GW, PHS capacity
32 GW), followed by Japan (electro-chemical capacity 0.3 GW, PHS capacity 28.3 GW), USA
(electro-mechanical 0.2 GW, electro-chemical capacity 0.7 GW, TSC 0.8 GW, PHS capacity
22.6 GW), Spain (TSC 1.1 GW, PHS capacity 8.0 GW), Germany (electro-mechanical 0.9 GW,
Electro-chemical capacity 0.1 GW, PHS capacity 6.5 GW), Italy (electro-chemical capacity
0.1 GW, PHS capacity 7.1 GW), India (TSC 0.2 GW, PHS capacity 6.8 GW), Switzerland
(PHS capacity 6.4 GW), France (PHS capacity 5.8 GW), Republic of Korea (electro-chemical
capacity 0.4 GW, PHS capacity 4.7 GW).

It is estimated that the electricity storage demand for stationary [27] and mobile
applications will increase rapidly from 4.67 TWh (2017) to 11.89–15.72 TWh (2030) [22] if
the contribution of the deployment of renewable energy technologies doubles as compared



Sustainability 2021, 13, 2823 7 of 17

to the present scenario. Non-PHS storage is estimated to rise up to 5821–8426 GWh by 2030
depending on the falling cost of the battery. Hydrogen ammonia storage technology is
estimated to rise to 1560–2340 GWh of energy storage by 2030. It is estimated that battery
deployment capacity in stationary application will increase from 11 GWh to 100–167 GWh
by 2030 [17]. In addition, the utility sector utilized the battery energy storage (BES) system
of 10 GWh (2017), which will rise to an estimate of 45 GWh to 74 GWh by 2030 [22]. In
the renewable energy map analysis [22], it is concluded that by 2030, electricity energy
storage will reach 1000 GW, when the installed capacity of solar and wind plant capacity
will soar to 5000 GW. The share of storage capacity in 2030, will be 1100 GW, which will
constitute 600 GW capacity from electric vehicle storage, 325 GW from PHS, and 175 GW
from stationary battery storage [22].

3. Renewable Energy Scenario of Pakistan and Turkey
3.1. Pakistan Scenario

The entire land of Pakistan is 881,913 km2 with 211.17 million people [28]. Up until
2019, electricity generation in Pakistan was 87.3 TWh [28]. Pakistan is facing severe energy
crises and the facts [29] reveal as follows: (1) the role of fossil fuel remains the highest
in form of oil and gas, i.e., 62.1% resource consumption in order to produce electricity in
2019 in Pakistan; (2) the share of power production through hydro power plants is 25.8%,
nuclear power plants stand at 8.2%, and renewable energy 3.9%. It is a dire need to make a
strategy to overcome the prevailing crisis and formulate a clear goal keeping in view the
decreasing levels of fossil fuel in the world simultaneously reducing massive expenditures
incurred on its import [30]. Pakistan is spending 60% of its reserves on importing the
fossil fuel, which is a great burden on its crumbling economy [31]. From energy security,
sustainable energy resource, climate change, and economic considerations, alternative
energy resources can prove to be the best option in hand in the present scenario [32].
Pakistan’s Ministry of Energy and other responsible departments, such as Pakistan Water
and Power Development Authority (WAPDA), Karachi Electric Supply Company (KESC),
and Independent Power Plant (IPPS), are planning and executing several renewable energy
projects by establishing plants for wind energy, solar power, hydel power, and biogas
across the country [31].

In order to provide low-priced electricity, transformation of the existing resources of
energy from thermal plant (fossil fuel) to renewable energy resources is taking place for
clean energy production. With this shift of renewable energy technologies, there will be less
or no reliance on fossil fuels as the main source for energy. Moreover, there will be positive
effects on the environment in both the countries. According to study [33], the demand
increases up to 5% annually. The difference between demand and supply was 5000 MW in
2013, but it increased to 6000 MW in 2018 [34]. According to the study [35], Pakistan faced
an energy deficit of 5201 MW in 2015 and on a daily basis, there was load-shedding of
14–18 h across the country continuing from 2011. According to the Pakistani government,
the prediction was that the energy crisis in Pakistan would completely vanish in 2019 and
the country would produce surplus energy of 2732 MW [35]. Pakistan is still facing the
energy crisis with a shortfall of 3000 MW due to transmission losses [36]. According to
this report, Pakistan was generating 553.3 MW of electricity through modern renewable
energy technologies in 2015–2016, which was added to the national grid [35]. Still, the
Pakistani energy scenario heavily relied on oil to produce electricity, but in 2013–2014,
a shift from oil to gas could be witnessed in the power sector to generate electricity for
industrial, household, commercial, and transport sector consumption. As compared to
2008, the fossil fuel cost increased in 2009 resulting in 0.6% decrease in the total energy
supplies [31], which badly affected the economy of the country. The contribution of fossil
fuels remains the highest in the form of oil and gas, i.e., 64% to generate electricity. Despite
all these efforts, Pakistan is unable to fulfill the demands of energy requirement. This
situation mainly affected the industrial sector resulting in the export minimization and
causing adverse effects on the economic growth of the country. The total installed capacity



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in terms of fossil fuel, hydro power, and nuclear power plant to generate electricity in
Pakistan up to July 2017 was reported to be 25,100 MW with the generation of 108,408
GWh [31].

Pakistan deployed several wind power plants, solar photovoltaic plants, and biomass
plants in order to cope with the energy crisis. The summary of power capacity installed
and electricity generation through the renewable energy technologies is shown in Figures 4–
7 [22]. The share of the hydro power renewable energy technology is far high as compared
to other modern renewable energy technologies. The installation capacity and energy
production of each renewable energy technologies are summarized in Figures 4 and 5.
Similarly, the detailed usage of solar-, wind-, and biomass-based capacity and power
generation are shown in Figures 6 and 7, respectively.

Figure 4. Total installed capacity of renewable energy in Pakistan up until 2018 [22].

Figure 5. Total electricity generation through renewable energy technologies of Pakistan up until 2016 [22].



Sustainability 2021, 13, 2823 9 of 17

Figure 6. Total capacity of modern renewable energy technologies of Pakistan up until 2018 [22].

Figure 7. Total electricity generation through modern renewable energy technologies of Pakistan [22].

3.2. Turkey Scenario

Turkey has 783,562 km2 territorial area [37] with a population of 83.1 million [38].
Total electricity generation for Turkey was recorded to be 261,783 GWh up until 2015.
According to the observation, Turkey depends mainly on coal (37%), natural gas (19%),
hydropower (29%), and renewable energy (15%) [38] to generate electricity. Turkey imports
72% of these total primary energy supplies (oil, natural gas, coal), which is certainly an
enormous load on the Turkish economy [32,39]. In this regard, the research [40] analyzes
the operational performance and investment performance of natural gas-, oil-, and coal-
based thermal power plant operated by public and private sectors of Turkey. It also derived
some useful efficiency scores based relationships between the thermal power plants in
terms of operational and investment cost [41]. With the 8% increase of energy demands
in Turkey annually [39], there is a lurking need to increase energy production. According
to the observation, the major share in the rise of demand is due to the industrial sector.
The industrial sector energy demand was expected to reach 97 to 148 TWh due to the
exports of industrial goods and agricultural processed products to the European open
market (without custom duty) till 2020 [42]. In order to fulfill the requirement of energy
demand and supply, and with a vision [43] to utilize the 30% renewable energy technology
resources to generate (160,000 GWh) electricity till 2023, Turkey will be less dependent on
fossil fuel and can also get rid of the carbon tax [39].



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Turkey lies in a perfect region where it can utilize the maximum resources of modern
renewable energy technologies to cope with the upcoming energy demand in the country.
By utilizing the renewable energy resources, such as wind power technology, solar power
technology, biomass technology, and geothermal energy technology, Turkey has the poten-
tial to produce 160 TWh of energy, which is double the energy generation compared to
electricity generated in 1996 [44].

Moreover, this renewable energy technology does not emit CO2 as compared to the
utilization of the traditional fossil fuel used for electricity generation, which is not only
harmful for the environment, but lays heavy costs on the national economy of Turkey in
terms of conventional fuel (coal, gas, oil) import costs. Energy security and sustainable
energy supply is paramount for the Turkish state as only dependence on fossil fuels would
make the state dependent on the stakeholders causing risk to the national security of the
Turkish state. According to the collected facts in the years 2008–2009, 80% of electricity
generated in Turkey was thermal-based (gas, coal, oil), where renewable-based electricity
generation was only 19.3% (18.5% hydropower, 0.8% others) [45]. Turkey has a great
potential of wind power plant as shown in Figures 8–11 and as of now, 158 companies have
installed wind power plants across the country.

Figure 8. Total capacity of renewable energy technologies of Turkey up until 2018.

Figure 9. Total generation through renewable energy technology up until 2016.



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Figure 10. Total capacity of modern renewable energy technologies of Turkey up until 2018.

Figure 11. Total generation capacity of modern renewable energy technologies up until 2016.

4. Energy Targets and Storage Policy

Policy targets regarding energy are broadly classified into five different sectors, i.e., pri-
mary energy supply, final energy consumption, electricity, transport, and heating/cooling
system. In Pakistan’s case, an energy crisis-based scenario sets a target and recommends a
strategic policy to overcome the confronting energy challenge through the deployment of
modern renewable energy technologies. Several projects of renewable energy technologies
are under development to meet the current energy demands and fulfill the requirement
by utilizing the available natural resources of energy in power and transport sectors. It is
believed that by the middle of June 2021, Pakistan will be in a position to produce surplus
energy, which will definitely impact its socio-economic growth. Pakistan should adopt
the electricity storage policy in order to produce affordable, safe, secure, and sustainable
energy, whereas, in Turkey’s case, the nation aims to fulfill the national energy demands
focusing on primary energy supply as well as generating electricity to export it to the
other European countries. In this regard, 400 kV Akhaltsikhe-Borcka of transmission line



Sustainability 2021, 13, 2823 12 of 17

is under construction with a DC (Direct Current) back to back station at Georgian side.
Moreover, Turkey-Romania 400 kV HVDC (High Voltage Direct Current) submarine cable
under the Black Sea carrying 600 MW is proposed and feasibility studies are in progress. In
addition, Turkey-Iraq 400 kV Cizre-Musul transmission line is in the planning stage and
Turkey-Iran transmission line of 400 kV Khoy-Baskale-Van is under construction with DC
back to back interconnection.

4.1. Discussion on Energy Storage Policy

Energy storage policy has become a significant issue for both developing and de-
veloped countries in terms of reliability, security, sustainability, and affordability. Many
countries have a national energy policy entailing the integration of the various renewable
energy technologies with effective energy storage systems in order to make the power
sector reliable and sustainable. Moreover, this policy will play a significant part in reducing
the effect of CO2 emissions. There is an active global movement going on for the adoption
of 100% employment of renewable energy technology in power sectors. Energy storage is
directly proportional to deployment of modern renewable energy technologies. On a global
scale, every country shows interest in investing money in the power sector for energy stor-
age systems for the implementation of renewable energy technologies. USA, Australia, and
China are pioneers in this field, which uses electro-chemical storage, electro-mechanical
storage, and thermal storage in its energy infrastructure for reliable operation of the power
sector. Hydro pumped storage, which is a mature field, has made its place in the power
sector and many countries adopted it in their national policy to store the energy. On the
other hand, the prices of battery storage system have fallen down and are expected to
move down with the passage of time. The lower the price of the battery storage system,
the higher the expectation of the deployment of renewable energy technologies.

For the active implementation of the energy storage technologies along with the
renewable energy technologies in the power sector, the support of the public sector stands
as paramount. The second step in this regard is a clear framework of promoting the
implementation of renewable energy technologies in the current infrastructure to fulfill
the demand of energy and phasing out all subsidies on fossil fuel import and nuclear
energy production.

In order to achieve the smooth, fast, and cost effective transition to energy storage
technologies, government needs to adopt a national legislative act, which ensures to
provide the opportunity to private entities to invest money in the deployment of renewable
energy technologies as well as energy storage technologies. In this regard, the following
are the key recommendations in terms of the deployment of energy storage technology for
policy makers for the utilization of the maximum potential of renewable energy resources
by integrating it with the latest storage technologies.

4.2. Energy Storage Policy Recommendation
4.2.1. New Channels and Mechanisms to Attract Investors

The German renewable power sources act (EEG) is a good and ideal model of policy
guideline in which they establish the permanent feed-in-duty for the deployment of re-
newable energy systems. This policy guideline gives reduced upfront cost in wind- and
solar-based technologies. This policy framework allows preferential award for investment
in the renewable energy projects. The German scheme has certain merits and demerits [46],
such as the feed-in tariff mechanism posing higher risks on large installations of solar PV
with longer project durations as there are higher uncertainties about remuneration levels
at project completion time. Feed-in tariffs involve lower costs of equity and cost of debt
than tenders.

It has been observed from the data and statistics of different countries that by applying
the tenders instead of a feed-in-tariff, this strategy will reduce the investment cost to deploy
more renewable energy technologies in the power sector as tender becomes costly for
consumers. Tenders are only applicable for capacities above 40 MW and feed-in-tariff



Sustainability 2021, 13, 2823 13 of 17

process should be adopted for capacity below 40 MW to promote the renewable energy
technologies as well as integration of storage technologies.

Since there are some trade-offs using feed-in tariffs and tenders to remunerate different
scales of renewable energy projects [46], hybrid support mechanisms [47] are becoming
popular gradually and a new political mechanism also needs to be implemented in order to
invest in renewable energy, storage technology, and their integration to achieve the reliable
and affordable electricity. Hybrid renewable power plant remuneration (hybrid support
mechanism) [47] was introduced and termed as a reformed version of feed-in-tariff and
tenders in energy sector.

4.2.2. Phasing out Subsidies on Non-Renewable Resources

It is advised that the governments promote and encourage renewable energy tech-
nology by giving subsidies in taxes for the pioneer investors in this sector. It is also
recommended to increase taxes on import of fossil fuels discouraging this trend and saving
foreign reserves in parallel. This scheme would increase spending of public funding on
infrastructure projects and education by the government. The study [48] concludes that
the nuclear energy contributes to environmental pollution in Pakistan. This study further
suggests certain actions and measures to make nuclear energy a clean source of energy
in Pakistan:

• Improvement in the infrastructure for nuclear generation.
• Establishment of independent regulatory body to achieve the threshold level of nuclear

share and enhancing nuclear waste management facilities.
• The checks are required for operational performance, efficiency, and monitoring to

avoid serious irreversible consequences to humanity and the environment.

4.2.3. Power Storage Sector as Tax-Free Zone

This sector can be categorized as exempted from tax on acquisition of property, pro-
curement of necessary equipment, commercialization, financing, and trading. This will
ease the making of relevant business plans by entrepreneurs and they will quickly achieve
the break-even point in their financial books. This will minimize the risk of loss and
maximize the return on investment in the future. It will also build the trust of businessmen
community on the government.

4.2.4. Introducing Carbon and Radioactive Tax

By introducing the carbon and radioactive tax, the trend of power generation from
fossil fuel will be declined and most of the countries will switch slowly and gradually to
renewable energy and storage technologies. This fact cannot be ignored that fossil fuel
reserves will be depleted in the future, so the cost of fossil fuels and imposed taxes will be
increased gradually, which will push the world to shift to alternate approaches.

4.2.5. Research and Development for Renewable Energy

Research and development is the key factor for success in a particular field. It is rec-
ommended to create awareness in the younger generation of the deployment of renewable
energy projects and reducing reliance on fossil fuels by taking the Ministry of Education
on board. Universities can play a better role by connecting undergraduates, MS students,
PhD scholars, and young entrepreneurs to do research work in this sector. Business and
technology incubation centers should encourage business ideas in renewable energy and
energy storage sector. Similarly, it is necessary to force local research institutes to apply for
collaborative research with international researchers and funding agencies.

4.2.6. Pilot Projects and Their Enhancement

The government should adopt a clear policy to take an initiative after feasible study to
deploy the most suitable energy storage technology with the renewable energy technologies
and introduce it as a pilot project. The pilot projects can be improved using a learning-by-



Sustainability 2021, 13, 2823 14 of 17

doing approach, so that energy storage technologies can be utilized to their maximum in
the power sector in order to reduce the emissions of CO2 and dependence on fossil fuel
imports that lay a heavy cost on the national economy.

4.2.7. Safe and Secure Platform to the Competitor

A subsidy and tax reduction policy should be implemented on renewable energy
technology deployment along with energy storage technologies. More competitors will
show their interest in energy storage systems and ultimately storage technology will be
employed for every renewable energy technology installation.

4.2.8. Learning from Positive Case Studies

It is impossible for the user to learn and deploy most suitable storage technologies.
User should consider the best-case result in which battery storage or thermal storage
technology has played a vital role and replicate the idea if the condition and environment
suits the needs and demands.

Table 2 provides a brief summary of the policy recommendations. The right mark
indicates the suitability and applicability of the policy recommendation in the respective
countries. N/A is the abbreviation of “not applicable”. Table 2 shows the recommendations
for the renewable energy and energy storage development of Pakistan and Turkey. These
recommendations include the adoption of the mechanisms to attract investments, phas-
ing out subsidies and incentives on non-renewable energy projects, tax exemption from
renewable energy projects, creating more competitors for providing relief to consumers
and learning from other countries through positive case studies. Table 2 also highlights the
other recommendations applicable for Pakistan, such as pilot project initiative, R&D in zero
emission, and introduction of radioactive tax to promote renewable energy development.
In case of Turkey, the introduction of a carbon tax may prove to be beneficial for renewable
energy development.

Table 2. Summary of above policy recommendations.

S.No Recommended Policies Pakistan Turkey

1 Enable the direct investment in renewable energy 4 4

2 Phasing out subsidies 4 4

3 Tax exemption from RET 4 4

4 Introducing carbon tax N/A 4

5 Introducing radioactive tax 4 N/A

6 Research and development in zero emission and RET 4 N/A

7 Pilot projects initiative 4 N/A

8 Develop more competition to provide relief to consumers 4 4

9 Learn from others through positive case studies 4 4

5. Conclusions

In this paper, we have performed comparative analysis of different energy storage
technologies with the emphasis on energy security and reliability based on the renewable
energy scenario of Pakistan and Turkey. We have compared different energy storage
technologies in terms of some technical indicators and suitability of applications useful for
the deployment of renewable energy projects. We have also reported the statistics of the
deployment of energy storage technologies in the globe and its expected increase until 2030
based on renewable energy scenario. The presented data and analysis prove that Pakistan
and Turkey have not fully exploited the renewable energy potential in the respective
countries. As Pakistan and Turkey are dependent on the imports of fossil fuels, they may
set an example for other developing countries willing to transform their energy sector



Sustainability 2021, 13, 2823 15 of 17

towards renewable energy resources by utilizing the maximum potential of renewable
energy and its cost effective integration with the energy storage technologies. This change is
inevitable due to global environmental and ecological effects pushing the global community
to impose certain taxes on the localities releasing CO2 in the environment.

The mentioned facts and standpoints encourage both the countries to develop, design,
and formulate a very strong storage policy, which is easy to implement and should be bene-
ficial in the long run. The policy recommendations include the adoption of the mechanisms
to attract direct investments, phasing out subsidies on non-renewable energy resources, tax
exemption from renewable energy projects, creating more competitors for providing relief
to consumers, imposing carbon tax, and learning from other countries through positive case
studies. The policy also suggests cost effective integration of electricity storage technology
with the renewable energy technology as the prices of the electricity storage technologies
continue to reduce with the passage of time according to IRENA database.

Author Contributions: Conceptualization, R.U.; methodology, R.U.; validation, H.R.K., A.A., M.A.S.
and A.R.; formal analysis, H.R.K. and A.A.; investigation, R.U. and H.R.K.; resources, H.R.K., A.A.,
A.R. and U.S.K.; data curation, M.A.S.; writing—original draft preparation, R.U.; writing—review
and editing, M.A.S.; visualization, M.A.S.; supervision, R.U.; project administration, A.R.; funding
acquisition, U.S.K. All authors have read and agreed to the published version of the manuscript.

Funding: This work was supported by the Higher Education Commission of Pakistan under grants
titled “Establishment of National Centre of Robotic and Automation (DF-1009-31)”.

Institutional Review Board Statement: Not applicable.

Informed Consent Statement: Not applicable.

Data Availability Statement: Not applicable.

Conflicts of Interest: The authors declare no conflict of interest.

References
1. Chauhan, A.; Saini, R. A review on Integrated Renewable Energy System based power generation for stand-alone applications:

Configurations, storage options, sizing methodologies and control. Renew. Sustain. Energy Rev. 2014, 38, 99–120. [CrossRef]
2. Koohi-Kamali, S.; Tyagi, V.; Rahim, N.; Panwar, N.; Mokhlis, H. Emergence of energy storage technologies as the solution for

reliable operation of smart power systems: A review. Renew. Sustain. Energy Rev. 2013, 25, 135–165. [CrossRef]
3. Hall, P.J.; Bain, E.J. Energy-storage technologies and electricity generation. Energy Policy 2008, 36, 4352–4355. [CrossRef]
4. Shahid, M.; Ullah, K.; Imran, K.; Mahmood, I.; Mahmood, A. Electricity supply pathways based on renewable resources: A

sustainable energy future for Pakistan. J. Clean. Prod. 2020, 263, 121511. [CrossRef]
5. Divya, K.; Østergaard, J. Battery energy storage technology for power systems—An overview. Electr. Power Syst. Res. 2009, 79,

511–520. [CrossRef]
6. Krieger, E.M.; Cannarella, J.; Arnold, C.B. A comparison of lead-acid and lithium-based battery behavior and capacity fade in

off-grid renewable charging applications. Energy 2013, 60, 492–500. [CrossRef]
7. Hu, X.; Li, S.; Peng, H. A comparative study of equivalent circuit models for Li-ion batteries. J. Power Sources 2012, 198, 359–367.

[CrossRef]
8. Piłatowicz, G.; Marongiu, A.; Drillkens, J.; Sinhuber, P.; Sauer, D.U. A critical overview of definitions and determination techniques

of the internal resistance using lithium-ion, lead-acid, nickel metal-hydride batteries and electrochemical double-layer capacitors
as examples. J. Power Sources 2015, 296, 365–376. [CrossRef]

9. Tremblay, O.; Dessaint, L.-A.; Dekkiche, A.-I. A generic battery model for the dynamic simulation of hybrid electric vehicles. In
Proceedings of the 2007 IEEE Vehicle Power and Propulsion Conference, Arlington, TX, USA, 9–12 September 2007; pp. 284–289.

10. Battke, B.; Schmidt, T.S.; Grosspietsch, D.; Hoffmann, V.H. A review and probabilistic model of lifecycle costs of stationary
batteries in multiple applications. Renew. Sustain. Energy Rev. 2013, 25, 240–250. [CrossRef]

11. Leadbetter, J.; Swan, L. Battery storage system for residential electricity peak demand shaving. Energy Build. 2012, 55, 685–692.
[CrossRef]

12. Rahman, M.A.; Anwar, S.; Izadian, A. Electrochemical model parameter identification of a lithium-ion battery using particle
swarm optimization method. J. Power Sources 2016, 307, 86–97. [CrossRef]

13. Evans, A.; Strezov, V.; Evans, T.J. Assessment of utility energy storage options for increased renewable energy penetration. Renew.
Sustain. Energy Rev. 2012, 16, 4141–4147. [CrossRef]

14. Nair, N.-K.C.; Garimella, N. Battery energy storage systems: Assessment for small-scale renewable energy integration. Energy
Build. 2010, 42, 2124–2130. [CrossRef]

http://doi.org/10.1016/j.rser.2014.05.079
http://doi.org/10.1016/j.rser.2013.03.056
http://doi.org/10.1016/j.enpol.2008.09.037
http://doi.org/10.1016/j.jclepro.2020.121511
http://doi.org/10.1016/j.epsr.2008.09.017
http://doi.org/10.1016/j.energy.2013.08.029
http://doi.org/10.1016/j.jpowsour.2011.10.013
http://doi.org/10.1016/j.jpowsour.2015.07.073
http://doi.org/10.1016/j.rser.2013.04.023
http://doi.org/10.1016/j.enbuild.2012.09.035
http://doi.org/10.1016/j.jpowsour.2015.12.083
http://doi.org/10.1016/j.rser.2012.03.048
http://doi.org/10.1016/j.enbuild.2010.07.002


Sustainability 2021, 13, 2823 16 of 17

15. Khaligh, A.; Li, Z. Battery, ultracapacitor, fuel cell, and hybrid energy storage systems for electric, hybrid electric, fuel cell, and
plug-in hybrid electric vehicles: State of the art. IEEE Trans. Veh. Technol. 2010, 59, 2806–2814. [CrossRef]

16. Ferreira, H.L.; Garde, R.; Fulli, G.; Kling, W.; Lopes, J.P. Characterisation of electrical energy storage technologies. Energy 2013, 53,
288–298. [CrossRef]

17. Zakeri, B.; Syri, S. Electrical energy storage systems: A comparative life cycle cost analysis. Renew. Sustain. Energy Rev. 2015, 42,
569–596. [CrossRef]

18. Díaz-González, F.; Sumper, A.; Gomis-Bellmunt, O.; Villafáfila-Robles, R. A review of energy storage technologies for wind power
applications. Renew. Sustain. Energy Rev. 2012, 16, 2154–2171. [CrossRef]

19. Denholm, P.; Kulcinski, G.L. Life cycle energy requirements and greenhouse gas emissions from large scale energy storage
systems. Energy Convers. Manag. 2004, 45, 2153–2172. [CrossRef]

20. Papadis, E.; Tsatsaronis, G. Challenges in the decarbonization of the energy sector. Energy 2020, 118025. [CrossRef]
21. Wang, Y.; Xu, L.; Solangi, Y.A. Strategic renewable energy resources selection for Pakistan: Based on SWOT-Fuzzy AHP approach.

Sustain. Cities Soc. 2020, 52, 101861. [CrossRef]
22. IRENA. Electricity Storage and Renewables: Costs and Markets to 2030; International Renewable Energy Agency: Abu Dhabi, United

Arab Emirates, 2017.
23. Spanos, C.; Turney, D.E.; Fthenakis, V. Life-cycle analysis of flow-assisted nickel zinc-, manganese dioxide-, and valve-regulated

lead-acid batteries designed for demand-charge reduction. Renew. Sustain. Energy Rev. 2015, 43, 478–494. [CrossRef]
24. Kousksou, T.; Bruel, P.; Jamil, A.; El Rhafiki, T.; Zeraouli, Y. Energy storage: Applications and challenges. Sol. Energy Mater. Sol.

Cells 2014, 120, 59–80. [CrossRef]
25. Rehman, S.; Al-Hadhrami, L.M.; Alam, M.M. Pumped hydro energy storage system: A technological review. Renew. Sustain.

Energy Rev. 2015, 44, 586–598. [CrossRef]
26. US DOE. DOE Global Energy Storage Database. 2017. Available online: http://www.energystorageexchange.org/projects

(accessed on 4 August 2017).
27. Malhotra, A.; Battke, B.; Beuse, M.; Stephan, A.; Schmidt, T. Use cases for stationary battery technologies: A review of the

literature and existing projects. Renew. Sustain. Energy Rev. 2016, 56, 705–721. [CrossRef]
28. Pakistan Economic Survey 2019–20; Finance Division, Government of Pakistan: Islamabad, Pakistan, 2020. Available online:

http://www.finance.gov.pk/survey_1920.html (accessed on 10 November 2020).
29. Pakistan Economic Survey 2018–19; Finance Division, Government of Pakistan: Islamabad, Pakistan, 2019. Available online:

http://www.finance.gov.pk/survey_1819.html (accessed on 10 November 2020).
30. Sheikh, M.A. Energy and renewable energy scenario of Pakistan. Renew. Sustain. Energy Rev. 2010, 14, 354–363. [CrossRef]
31. Pakistan Energy Year Book (PEYB). 2009. Available online: https://www.hdip.com.pk/contents.php?cid=31 (accessed on 12

April 2020).
32. Rasheed, R.; Rizwan, A.; Javed, H.; Yasar, A.; Tabinda, A.B.; Bhatti, S.G.; Su, Y. An analytical study to predict the future of

Pakistan’s energy sustainability versus rest of South Asia. Sustain. Energy Technol. Assess. 2020, 39, 100707. [CrossRef]
33. Asif, M. Sustainable energy options for Pakistan. Renew. Sustain. Energy Rev. 2009, 13, 903–909. [CrossRef]
34. International Energy Outlook. DOE/EIA-0484(2009), Energy Information Administration (EIA); US Department of Energy: Washing-

ton, DC, USA, 2009.
35. Kamran, M. Current status and future success of renewable energy in Pakistan. Renew. Sustain. Energy Rev. 2018, 82, 609–617.

[CrossRef]
36. Energy Crisis: Myth or Reality. Available online: https://nation.com.pk/06-Aug-2020/energy-crisis-myth-or-reality#:~{}:

text=Another%20part%20of%20the%20Pakistan,MW%3D%20%2D%203%2C000MW (accessed on 8 February 2021).
37. Turkey’s Statistical Yearbook 2009; Turkish Statistical Institute: Ankara, Turkey, 2009. Available online: http://www.tuik.gov.tr/

yillik/yillik.pdf (accessed on 6 December 2020).
38. Turkish Statistical Institute. Main Statistics. Population & Demography. Environment & Energy. Available online: http:

//www.turkstat.gov.tr/UstMenu.do?metod=temelist (accessed on 3 January 2020).
39. Tükenmez, M.; Demireli, E. Renewable energy policy in Turkey with the new legal regulations. Renew. Energy 2012, 39, 1–9.

[CrossRef]
40. Sarıca, K.; Or, I. Efficiency assessment of Turkish power plants using data envelopment analysis. Energy 2007, 32, 1484–1499.

[CrossRef]
41. Cetin, A.; Kadioglu, Y.K.; Paksoy, H. Underground thermal heat storage and ground source heat pump activities in Turkey. Sol.

Energy 2019, 200, 22–28. [CrossRef]
42. Dilaver, Z.; Hunt, L.C. Industrial electricity demand for Turkey: A structural time series analysis. Energy Econ. 2011, 33, 426–436.

[CrossRef]
43. Melikoglu, M. Vision 2023: Feasibility analysis of Turkey’s renewable energy projection. Renew. Energy 2013, 50, 570–575.

[CrossRef]
44. Wind Energy in Turkey. 2002. Available online: www.bsrec.bg (accessed on 5 March 2020).
45. EUAS 2008 and 2009 Electricity Generation Sector Report. Available online: https://www.euas.gov.tr/tr-TR/yillik-raporlar

(accessed on 10 January 2020).

http://doi.org/10.1109/TVT.2010.2047877
http://doi.org/10.1016/j.energy.2013.02.037
http://doi.org/10.1016/j.rser.2014.10.011
http://doi.org/10.1016/j.rser.2012.01.029
http://doi.org/10.1016/j.enconman.2003.10.014
http://doi.org/10.1016/j.energy.2020.118025
http://doi.org/10.1016/j.scs.2019.101861
http://doi.org/10.1016/j.rser.2014.10.072
http://doi.org/10.1016/j.solmat.2013.08.015
http://doi.org/10.1016/j.rser.2014.12.040
http://www.energystorageexchange.org/projects
http://doi.org/10.1016/j.rser.2015.11.085
http://www.finance.gov.pk/survey_1920.html
http://www.finance.gov.pk/survey_1819.html
http://doi.org/10.1016/j.rser.2009.07.037
https://www.hdip.com.pk/contents.php?cid=31
http://doi.org/10.1016/j.seta.2020.100707
http://doi.org/10.1016/j.rser.2008.04.001
http://doi.org/10.1016/j.rser.2017.09.049
https://nation.com.pk/06-Aug-2020/energy-crisis-myth-or-reality#:~{}:text=Another%20part%20of%20the%20Pakistan,MW%3D%20%2D%203%2C000MW
https://nation.com.pk/06-Aug-2020/energy-crisis-myth-or-reality#:~{}:text=Another%20part%20of%20the%20Pakistan,MW%3D%20%2D%203%2C000MW
http://www.tuik.gov.tr/yillik/yillik.pdf
http://www.tuik.gov.tr/yillik/yillik.pdf
http://www.turkstat.gov.tr/UstMenu.do?metod=temelist
http://www.turkstat.gov.tr/UstMenu.do?metod=temelist
http://doi.org/10.1016/j.renene.2011.07.047
http://doi.org/10.1016/j.energy.2006.10.016
http://doi.org/10.1016/j.solener.2018.12.055
http://doi.org/10.1016/j.eneco.2010.10.001
http://doi.org/10.1016/j.renene.2012.07.032
www.bsrec.bg
https://www.euas.gov.tr/tr-TR/yillik-raporlar


Sustainability 2021, 13, 2823 17 of 17

46. Grau, T. Comparison of Feed-In Tariffs and Tenders to Remunerate Solar Power Generation; DIW Berlin: Berlin, Germany, 2014; Available
online: https://papers.ssrn.com/sol3/papers.cfm?abstract_id=2403873 (accessed on 10 December 2020).

47. Renewable Energy Support Mechanisms: Feed-In Tariffs and Auctions. Available online: https://energypedia.info/wiki/
Renewable_Energy_Support_Mechanisms:_Feed-In_Tariffs_and_Auctions (accessed on 8 February 2021).

48. Mahmood, N.; Wang, Z.; Zhang, B. The role of nuclear energy in the correction of environmental pollution: Evidence from
Pakistan. Nucl. Eng. Technol. 2020, 52, 1327–1333. [CrossRef]

https://papers.ssrn.com/sol3/papers.cfm?abstract_id=2403873
https://energypedia.info/wiki/Renewable_Energy_Support_Mechanisms:_Feed-In_Tariffs_and_Auctions
https://energypedia.info/wiki/Renewable_Energy_Support_Mechanisms:_Feed-In_Tariffs_and_Auctions
http://doi.org/10.1016/j.net.2019.11.027

	Introduction 
	Energy Storage Technologies (EST) 
	Different ESTs with Implementation in Power Sector 
	Discussion and Comparison on Different ESTs 

	Renewable Energy Scenario of Pakistan and Turkey 
	Pakistan Scenario 
	Turkey Scenario 

	Energy Targets and Storage Policy 
	Discussion on Energy Storage Policy 
	Energy Storage Policy Recommendation 
	New Channels and Mechanisms to Attract Investors 
	Phasing out Subsidies on Non-Renewable Resources 
	Power Storage Sector as Tax-Free Zone 
	Introducing Carbon and Radioactive Tax 
	Research and Development for Renewable Energy 
	Pilot Projects and Their Enhancement 
	Safe and Secure Platform to the Competitor 
	Learning from Positive Case Studies 


	Conclusions 
	References