sustainability

Article

Foreign Direct Investment in the Power and Energy
Sector, Energy Consumption, and Economic Growth:
Empirical Evidence from Pakistan

Rashid Latief * and Lin Lefen *

College of Finance, Nanjing Agricultural University, Nanjing 210095, China
* Correspondence: 2016218005@njau.edu.cn (R.L.); lefenlinna@njau.edu.cn (L.L.)

Received: 8 November 2018; Accepted: 17 December 2018; Published: 2 January 2019
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Abstract: Pakistan significantly contributes to the overall economy of South Asia, but, for many
years, it has been facing a severe energy crisis. Despite the robust economic growth and a sharp
increase in energy demand, no deliberate efforts have been made to meet the energy demand of the
country. Similar to other developing countries, foreign direct investment (FDI) plays a key role in the
economic development of this country. Pakistan receives FDI from many countries in various sectors
of the economy. This paper aims to highlight the present situation of the power and energy sector of
Pakistan (PESP), and empirically analyze the causality among the FDI in the power and energy sector,
the energy consumption, and the economic growth of Pakistan for the period 1990–2017. The Johansen
co-integration and Granger causality tests were employed to find the causal relationships among
the variables of interest in the short-run and the long-run. The sector-wise flow of FDI reveals that
the power and energy sector of Pakistan (PESP) has comparatively received a higher amount of FDI
than other sectors of the economy in recent years. Furthermore, trends of energy production and
energy usage reveal a substantial gap in previous years. The results confirm a positive bi-directional
short-run causal relationship between economic growth and energy consumption. The results also
reveal the presence of long-run causality in the equation of energy consumption. Considering the
current situation of PESP, policy-makers should formulate policies to attain the minimum debt level
and discourage loan-based investment. Such policies would be helpful to control the severe energy
crisis and increase economic growth.

Keywords: FDI; energy consumption; economic growth; power and energy sector

1. Introduction

At present, investment appears to be a significant factor in the economic development of any
country. Specifically, foreign direct investment (FDI) constitutes the main source of economic growth in
developing countries. Over the past few decades, globalization has helped to promote strong economic
integration between countries. The developing countries have changed their economic policies by
pulling down hurdles in the way of foreign trade and investment. Consequently, severe competition
exists among developing countries to attract FDI.

FDI is helpful for developing countries, such as Pakistan, in many ways. First, it offers capital to
generate positive externalities, such as employment generation, the transfer of technology, managerial
skills, productivity gains, research and development, and new ways of production, in the country.
Second, it encourages domestic investors to invest in the country [1]. Currently, Pakistan lies on the
radar of foreign investors globally despite different political and economic challenges. Indeed, Pakistan
has adopted investment-oriented policies to create opportunities for foreign investors.

Sustainability 2019, 11, 192; doi:10.3390/su11010192 www.mdpi.com/journal/sustainability

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Sustainability 2019, 11, 192 2 of 21

Pakistan receives FDI from different countries around the world, such as China, the United States,
Japan, Norway, the United Kingdom, Hong Kong, Saudi Arabia, and Switzerland. The target sectors
for FDI include the power and energy sector, financial business, trade, construction, transport, textiles,
and trade. The power and energy sector of Pakistan (PESP) is one of the major sectors that receives
a higher amount of FDI. Recently, the Government of Pakistan (GOP) has announced a new power
policy and offered different incentives for encouraging domestic and foreign investors to invest in the
power and energy sector [2].

Energy is an essential input to economic productivity. Moreover, production growth helps to
increase the energy demand as a result of an increase in energy consumption [3]. The level of energy
consumption is directly linked to the overall progress of a country. Therefore, per capita energy
consumption is used as a proxy to measure the socioeconomic development of a country [4]. Similar
to other developing countries, the energy demand and consumption of Pakistan have consistently
increased with the increase in its population. Pakistan is facing a severe energy crisis due to its
intense reliance on oil and gas, de-rated capacity, circular debt, energy security and threats, and bad
governance. To control the energy crisis, policies should be formulated to attain the minimum debt
level and discourage loan-based investment.

To take an impartial view of FDI in the power and energy sector, it is necessary to analyze the
government’s policies to bring a sufficient amount of FDI into the sector and its contribution to the
overall economy of the country. To the best of our knowledge, no empirical study has been conducted
in the context of Pakistan to examine the flow of FDI specifically in the power and energy sector and
its impact on economic growth. The aim of this paper is to analyze the causality among the FDI in the
power and energy sector, the energy consumption, and the economic growth in the context of Pakistan.
This paper also highlights the overall structure of the power and energy sector of Pakistan (PESP), and
major constraints in the progress of this sector. Finally, this paper suggests policy implications for the
progress of this sector.

The rest of the paper is organized as follows. Section 2 provides an overview of the power and
energy sector of Pakistan (PESP), major constraints on this sector, and the contribution of FDI to
the development of this sector. Section 3 reviews the research work completed by other researchers
on the relationship between FDI, energy consumption, and economic growth. Section 4 details the
data collection, empirical models, and the empirical approaches adopted. Section 5 demonstrates the
empirical results of this paper. Section 6 concludes the study and sketches the policy implications.

2. Overview of Pakistan’s Power and Energy Sector

2.1. The Structure of Pakistan’s Power and Energy Sector

The overall structure of Pakistan’s power and energy sector consists of different players from the
production stage to the final usage as depicted in Figure 1. The following are the major players that are
involved in the sector.

2.1.1. Suppliers of Primary Energy

The major suppliers of primary energy in Pakistan, such as Oil and Gas Development Company
Limited (OGDL), Pakistan Petroleum Limited (PPL), and Pakistan Oilfields Limited (POL), supply
crude oil to the refineries. The refineries refine the crude oil and supply it to the end consumers through
oil distributors. Pakistan is heavily dependent upon oil and gas resources to meet its energy demand.
Domestic oil resources are not enough to fulfill the country’s energy requirement. Therefore, Pakistan
imports crude oil, which satisfies about one-third of its total oil demand, from different countries, such
as Saudi Arabia and Middle Eastern countries, to fulfill its energy demand [5].



Sustainability 2019, 11, 192 3 of 21

2.1.2. Power Generators and Power Distributors

There are three major power generators operating in Pakistan: Generation Companies (GENCOS),
Karachi Electric Supply Corporation (KESC), and Independent Power Producers (IPPs). The power
is transmitted from these power generators and other projects (hydel and nuclear) to the power
distributors. The power distributors supply power to the end consumers.

2.1.3. End Consumers

The end consumers, which consume the energy to fulfill their demand, comprise individual
households, different industries, government institutes, and transporters. End consumers pay tariffs
that are often subsidized by the government in the form of power and fuel subsidies. These tariffs are
utilized to make payments at different phases of the energy supply chain [6].

Sustainability 2018, 10, x FOR PEER REVIEW  3 of 21 

 

End Consumers 

The end consumers, which consume the energy to fulfill their demand, comprise individual 

households, different industries, government institutes, and transporters. End consumers pay tariffs 

that are often subsidized by the government in the form of power and fuel subsidies. These tariffs are 

utilized to make payments at different phases of the energy supply chain [6]. 

Figure 1. The structure of Pakistan’s Power and Energy Sector [7]. 

2.2. Major Constraints on Pakistan’s Power and Energy Sector 

Pakistan has been facing a severe energy crisis for a long time. Despite the robust economic 

growth and a sharp increase in energy demand, no solemn efforts have been made to satisfy the 

energy demand in the past few decades. The following are the major constraints behind the energy 

crisis in the country. 

Intense Reliance on Oil/Gas 

Pakistan is highly dependent upon the import of fossil fuel from foreign countries. Fuel import 

is connected with the volatile price structure of oil in the international oil market. In highly volatile 

circumstances, Pakistan pays a higher cost for importing fossil fuel to meet its domestic requirement 

for producing energy. Pakistan spends about 60% of its foreign exchange reserves on importing fossil 

fuel from the international oil market. For instance, the oil prices were increased recently in the 

international market. The higher oil prices and the shortage of funds adversely affected the quantity 

demand of Pakistan for importing oil. As a result, the gap between energy demand and supply was 

increased [5]. 

Pakistan has different choices for improving the current situation of the power and energy 

sector. It can change its power policy by focusing on alternative energy sources, such as hydro 

projects, wind projects, and solar projects. Pakistan requires new dams to fulfill the energy 

requirement of the country. Although Pakistan already has a few dams, namely the Tarbela Dam, the 

Mangla Dam, the Mirani Dam, the Warsak Dam, and the Sabakzai Dam, these dams do not produce 

enough energy to fulfill the energy requirement of the country. 

 

 

 

Figure 1. The structure of Pakistan’s Power and Energy Sector [7].

2.2. Major Constraints on Pakistan’s Power and Energy Sector

Pakistan has been facing a severe energy crisis for a long time. Despite the robust economic
growth and a sharp increase in energy demand, no solemn efforts have been made to satisfy the energy
demand in the past few decades. The following are the major constraints behind the energy crisis in
the country.

2.2.1. Intense Reliance on Oil/Gas

Pakistan is highly dependent upon the import of fossil fuel from foreign countries. Fuel import
is connected with the volatile price structure of oil in the international oil market. In highly volatile
circumstances, Pakistan pays a higher cost for importing fossil fuel to meet its domestic requirement
for producing energy. Pakistan spends about 60% of its foreign exchange reserves on importing fossil
fuel from the international oil market. For instance, the oil prices were increased recently in the
international market. The higher oil prices and the shortage of funds adversely affected the quantity
demand of Pakistan for importing oil. As a result, the gap between energy demand and supply was
increased [5].

Pakistan has different choices for improving the current situation of the power and energy sector.
It can change its power policy by focusing on alternative energy sources, such as hydro projects, wind



Sustainability 2019, 11, 192 4 of 21

projects, and solar projects. Pakistan requires new dams to fulfill the energy requirement of the country.
Although Pakistan already has a few dams, namely the Tarbela Dam, the Mangla Dam, the Mirani
Dam, the Warsak Dam, and the Sabakzai Dam, these dams do not produce enough energy to fulfill the
energy requirement of the country.

2.2.2. De-Rated Capacity

Many energy production units are installed at different places in Pakistan, but their energy
producing capacity has been de-rated with the passage of time. There are different factors behind this
situation, such as mismanagement, a shortage of funds, the availability of oil, and a lack of proper
maintenance. For instance, the total installed capacity of PESP was 24,953 MW for generating electricity
until June 2014. Although the power producers were capable of producing more electricity, as a result,
Pakistan suffered severe load shedding in the subsequent years [8].

2.2.3. Circular Debt

Circular debt is one of the major constraints that Pakistan’s power and energy sector has faced for
many years. The problem of circular debt arises as the operating energy units face the issue of cash
flows with their creditors and suppliers. SS Ali and S Badar [6] highlighted different reasons for the
circular debt:

(1) The failure of distribution companies to collect due payments from their receivables (mainly
government-owned organizations);

(2) The default of distribution companies on making payments to energy producers;
(3) The default of energy producers on making payments to oil companies for purchasing fuel; and
(4) Late payments of oil companies to oil refineries.

For instance, the figure of Pakistan’s circular debt approached 977 billion rupees at the beginning
of 2018, and it is the highest figure of circular debt that the PESP has yet faced. Out of the total figure
of circular debt, 542.9 billion rupees were payables, while 434 billion rupees were pending in the form
of loans borrowed by Power Holding Private Limited (PHPL). Looking at the receivables, billions
of rupees are pending to be received by the Central Power Purchase Agency (CPPA) from different
government and private organizations. This overall situation of circular debt has made the power and
energy sector of Pakistan more stagnant [9].

2.2.4. Energy Security and Threats

Pakistan’s domestic oil and gas resources are very limited. The domestic oil reserves could be
depleted within the next 13 years, while the gas reserves are available for the next 16 years. Therefore,
Pakistan imports oil from different countries to fulfill its domestic oil demand. This situation creates
grave concerns about energy security. The main threat to energy security is from foreign routes
for importing oil, because these might be disrupted at any time due to global conflicts. Moreover,
the seaports might also be dysfunctional in the case of war between countries. As a result, Pakistan’s
entire thermal electricity production system could be adversely affected [4].

The main gas resources of Pakistan exist in the provinces of Baluchistan and Sindh. The political
and security situation of these provinces could significantly affect the energy sector. In 2013, Pakistan
formally inaugurated the Iran–Pakistan gas pipeline project to import gas from Iran. However,
this project has not yet been completed, although it was expected to be complete in December 2017.
The main reason behind it was the economic sanctions imposed by the United States on Iran. Moreover,
the Government of Pakistan (GOP) has recently negotiated with Qatar and started to import LNG for
fulfilling the energy requirement of the country. Conversely, the opponents of this project have filed
cases in courts of law. The court decisions are still pending, and could affect the import of LNG in
the country.



Sustainability 2019, 11, 192 5 of 21

2.2.5. Bad Governance

The power and energy sector of Pakistan (PESP) has faced bad governance for a long time.
The main reason is the political influence on energy entities from the public sector. The main political
parties, which govern the country, have badly damaged the administrative structure of these entities by
hiring incompetent employees on a political basis. As a result of bad governance, the PESP has faced
non-technical losses and the theft of gas and electricity in highly politically influenced and insecure
areas of Pakistan. The problem of circular debt is also interlinked with this constraint.

2.3. Energy Production, Import, and Consumption

The primary energy production and energy usage have deteriorated with the passage of time in
Pakistan as depicted in Figure 2. There are different factors involved in it. Examples are: the intense
reliance on oil and gas, a curtailing of the demand for oil in terms of quantity, ignoring hydro projects,
circular debt, insufficient funds, bad governance, and political influences. Figure 3 highlights that
the net energy imports have been increasing gradually, while the commercial usage of energy has
increased sharply in recent years. Pakistan, like other developing countries, imports crude oil from
Arabian countries, and LNG from Qatar, to fulfill its energy requirement. Pakistan has also planned to
import electricity from Kyrgyzstan and Tajikistan, and develop many energy projects under the China
Pakistan Economic Corridor (CPEC) project.

Sustainability 2018, 10, x FOR PEER REVIEW  5 of 21 

 

2.3. Energy Production, Import, and Consumption 

The primary energy production and energy usage have deteriorated with the passage of time in 

Pakistan as depicted in Figure 2. There are different factors involved in it. Examples are: the intense 

reliance on oil and gas, a curtailing of the demand for oil in terms of quantity, ignoring hydro projects, 

circular debt, insufficient funds, bad governance, and political influences. Figure 3 highlights that the 

net energy imports have been increasing gradually, while the commercial usage of energy has 

increased sharply in recent years. Pakistan, like other developing countries, imports crude oil from 

Arabian countries, and LNG from Qatar, to fulfill its energy requirement. Pakistan has also planned 

to import electricity from Kyrgyzstan and Tajikistan, and develop many energy projects under the 

China Pakistan Economic Corridor (CPEC) project.  

 

Figure 2. Trends of primary energy production and energy usage.  

  

Figure 3. Trends of net energy import, net energy usage, and commercial energy usage. 

2.4. The Role of FDI in Pakistan’s Power and Energy Sector 

The energy requirements of Pakistan are inflating quickly as the population of the country has 

been following an increasing trend for many years. The GOP has taken steps to make sure that there 

is sufficient energy security to go along with the expansion in natural resources. Pakistan has hydro 

and coal resources, which, if exploited, could be helpful to fulfill the energy requirements of the 

country in the future. The latest power production policy was announced in 2015 by the government 

of Pakistan (GOP), in which it offered different incentives to attract domestic and foreign investors 

Figure 2. Trends of primary energy production and energy usage.

Sustainability 2018, 10, x FOR PEER REVIEW  5 of 21 

 

2.3. Energy Production, Import, and Consumption 

The primary energy production and energy usage have deteriorated with the passage of time in 

Pakistan as depicted in Figure 2. There are different factors involved in it. Examples are: the intense 

reliance on oil and gas, a curtailing of the demand for oil in terms of quantity, ignoring hydro projects, 

circular debt, insufficient funds, bad governance, and political influences. Figure 3 highlights that the 

net energy imports have been increasing gradually, while the commercial usage of energy has 

increased sharply in recent years. Pakistan, like other developing countries, imports crude oil from 

Arabian countries, and LNG from Qatar, to fulfill its energy requirement. Pakistan has also planned 

to import electricity from Kyrgyzstan and Tajikistan, and develop many energy projects under the 

China Pakistan Economic Corridor (CPEC) project.  

 

Figure 2. Trends of primary energy production and energy usage.  

  

Figure 3. Trends of net energy import, net energy usage, and commercial energy usage. 

2.4. The Role of FDI in Pakistan’s Power and Energy Sector 

The energy requirements of Pakistan are inflating quickly as the population of the country has 

been following an increasing trend for many years. The GOP has taken steps to make sure that there 

is sufficient energy security to go along with the expansion in natural resources. Pakistan has hydro 

and coal resources, which, if exploited, could be helpful to fulfill the energy requirements of the 

country in the future. The latest power production policy was announced in 2015 by the government 

of Pakistan (GOP), in which it offered different incentives to attract domestic and foreign investors 

Figure 3. Trends of net energy import, net energy usage, and commercial energy usage.



Sustainability 2019, 11, 192 6 of 21

2.4. The Role of FDI in Pakistan’s Power and Energy Sector

The energy requirements of Pakistan are inflating quickly as the population of the country has
been following an increasing trend for many years. The GOP has taken steps to make sure that there is
sufficient energy security to go along with the expansion in natural resources. Pakistan has hydro and
coal resources, which, if exploited, could be helpful to fulfill the energy requirements of the country in
the future. The latest power production policy was announced in 2015 by the government of Pakistan
(GOP), in which it offered different incentives to attract domestic and foreign investors to invest in
power projects. The major aims of this policy are the following: (a) To supply an adequate power
production capacity with the minimum cost; (b) To boost up, and make sure of, the exploitation of
domestic resources; (c) To provide a win–win situation to all key players and obtain their confidence in
the process; and (d) Be accustomed to a secure environment [2].

The comparison of FDI in different sectors of Pakistan is shown in Figure 4. It highlights that
the power and energy sector of Pakistan (PESP) has received a comparatively higher amount of FDI
(about 35.58 percent), followed by the communication and financial business sectors (24.26 percent
and 21.26 percent, respectively) in previous years. FDI in PESP has contributed significantly to the
overall economic growth of the country over this period. The flows of FDI in the PESP and economic
growth are shown in Figure 5. Both economic growth and FDI showed upward trends at the beginning
of the period, while FDI continued in an upward trend until the year 1998. In the year 1998, Pakistan
tested its nuclear missiles to attain atomic power at the international level. As a result, Pakistan faced
different economic sanctions internationally and was confronted with the consequences in the form of
a downward trend in FDI.

Sustainability 2018, 10, x FOR PEER REVIEW  6 of 21 

 

to invest in power projects. The major aims of this policy are the following: a) To supply an adequate 

power production capacity with the minimum cost; b) To boost up, and make sure of, the exploitation 

of domestic resources; c) To provide a win–win situation to all key players and obtain their confidence 

in the process; and d) Be accustomed to a secure environment [2]. 

The comparison of FDI in different sectors of Pakistan is shown in Figure 4. It highlights that the 

power and energy sector of Pakistan (PESP) has received a comparatively higher amount of FDI 

(about 35.58 percent), followed by the communication and financial business sectors (24.26 percent 

and 21.26 percent, respectively) in previous years. FDI in PESP has contributed significantly to the 

overall economic growth of the country over this period. The flows of FDI in the PESP and economic 

growth are shown in Figure 5. Both economic growth and FDI showed upward trends at the 

beginning of the period, while FDI continued in an upward trend until the year 1998. In the year 1998, 

Pakistan tested its nuclear missiles to attain atomic power at the international level. As a result, 

Pakistan faced different economic sanctions internationally and was confronted with the 

consequences in the form of a downward trend in FDI. 

The other major possible reasons for the downward trend in FDI were the political turmoil and 

the security situation in Pakistan. In the year 1999, Pakistan faced a severe political crisis; 

consequently, the military took over the civilian government based on allegations of bad governance 

and other political issues. After the 9/11 terrorist attacks in the United States, Pakistan participated in 

the war against terrorism. As a result, the security situation in Pakistan became paralyzed, and 

investors avoided investing in Pakistan. After a certain number of years, the relationship of Pakistan 

with other countries, and its political and security situation, became better. Thereafter, FDI showed 

an upward trend from 2005 to 2008. From the year 2009, FDI showed a mixed trend for the subsequent 

period. However, the economic growth of Pakistan has followed an upward trend since the year 2002. 

In recent years, Pakistan has quietly succeeded in attracting foreign investors by offering tax 

incentives and providing a secure environment in the country. In the last five years, a number of new 

power projects were installed with the help of foreign investment [10]. The major projects, which 

were installed during the period 2014–2018, include GENCO-II, Guddu CC, Quaid-e-Azam (a solar 

plant), Nandipur (a thermal plant), Crest Energy, Chasnupp C-3 (nuclear), Chasnupp C-4 (nuclear), 

United Energy (wind), Patrind (hydel), Neelum Jehlum (hydel), Port Qasim (coal), Balloki (RLNG), 

and Tarbela T-4 Unit-17 (Hydel) [2]. Pakistan receives FDI from different countries, such as China, 

the United Kingdom, and the United States. After starting the CPEC project, the amount of Chinese 

investment in Pakistan has been significantly increased as compared to other countries [11].  

 

Figure 4. Sector-wise Foreign Direct Investment for the period 2001–2017 

 

 

 

 

 

Figure 4. Sector-wise Foreign Direct Investment for the period 2001–2017.

Sustainability 2018, 10, x FOR PEER REVIEW  7 of 21 

 

 

 

Figure 5. Trends of foreign direct investment (FDI) (Current U.S.$) in the power and energy sector 

of Pakistan (PESP) and the GDP growth per capita (%). 

3. Theoretical and Literature Framework 

3.1. Foreign Direct Investment (FDI) and Economic Growth 

The economic literature revolves around two main theories—modernization and dependency 

theories—to elaborate the linkage between FDI and economic growth [12]. According to 

modernization theory, FDI helps to increase economic growth based on the significance of capital 

investment for achieving growth. FDI is the main source of technology transfer from developed 

countries to developing countries, which provides assistance to promote the domestic industry. 

Usually, developing countries suffer from less developed infrastructure, political and economic 

instability due to insufficient resources. It is generally claimed that FDI could be helpful for the 

transfer of knowledge, marketing expertise, managerial skills, and different opportunities to access 

the market [13,14]. 

On the other side, according to the dependency school theory advocated by D O'Hearn [15], V 

Bornschier [16], and C Stoneman [17], FDI inflows can show a negative relationship with economic 

growth in the long-run. The basic reason was that the First World countries after World War II 

became wealthier by mining different resources from Third World countries. The developing 

countries were inadequately rewarded for their natural resources, which led to continuous poverty 

in those countries. The theorists found that capitalism is a basic cause for labor division at a global 

level. As a result, FDI can create hurdles for growth and increase the income inequality, which can 

negatively affect economic growth in the long-run. 

There could also be some other reasons for the negative linkage between FDI and economic 

growth. The most important reason is that foreign investment can reduce the production level of 

domestic firms through competition in the market. Usually, foreign firms face lower marginal costs 

because of a firm-specific advantage, which provides them with the opportunity to captivate demand 

away from domestic firms. As a result, their cost is increased and production level decreased. There 

is also another reason that foreign firms may not be willing to spread firm-specific knowledge to 

domestic firms. As a result, the production of domestic firms could lead to an adverse situation due 

to backward technology and less-skilled workers [18]. 

The debate about the relationship of FDI to economic growth has been extensively studied in the 

literature. However, the empirical results are varied across countries based on domestic human 

capital, infrastructure, and domestic policies to promote foreign investment and trade. Some studies 

revealed the direct linkage of FDI with economic growth, while there are also many studies in the 

literature that have highlighted the inverse linkage of FDI with economic growth. Studies that have 

specifically focused on FDI in the power and energy sector and its effect on economic growth are 

Figure 5. Trends of foreign direct investment (FDI) (Current U.S.$) in the power and energy sector of
Pakistan (PESP) and the GDP growth per capita (%).



Sustainability 2019, 11, 192 7 of 21

The other major possible reasons for the downward trend in FDI were the political turmoil and
the security situation in Pakistan. In the year 1999, Pakistan faced a severe political crisis; consequently,
the military took over the civilian government based on allegations of bad governance and other
political issues. After the 9/11 terrorist attacks in the United States, Pakistan participated in the war
against terrorism. As a result, the security situation in Pakistan became paralyzed, and investors
avoided investing in Pakistan. After a certain number of years, the relationship of Pakistan with other
countries, and its political and security situation, became better. Thereafter, FDI showed an upward
trend from 2005 to 2008. From the year 2009, FDI showed a mixed trend for the subsequent period.
However, the economic growth of Pakistan has followed an upward trend since the year 2002.

In recent years, Pakistan has quietly succeeded in attracting foreign investors by offering tax
incentives and providing a secure environment in the country. In the last five years, a number of new
power projects were installed with the help of foreign investment [10]. The major projects, which
were installed during the period 2014–2018, include GENCO-II, Guddu CC, Quaid-e-Azam (a solar
plant), Nandipur (a thermal plant), Crest Energy, Chasnupp C-3 (nuclear), Chasnupp C-4 (nuclear),
United Energy (wind), Patrind (hydel), Neelum Jehlum (hydel), Port Qasim (coal), Balloki (RLNG),
and Tarbela T-4 Unit-17 (Hydel) [2]. Pakistan receives FDI from different countries, such as China,
the United Kingdom, and the United States. After starting the CPEC project, the amount of Chinese
investment in Pakistan has been significantly increased as compared to other countries [11].

3. Theoretical and Literature Framework

3.1. Foreign Direct Investment (FDI) and Economic Growth

The economic literature revolves around two main theories—modernization and dependency
theories—to elaborate the linkage between FDI and economic growth [12]. According to modernization
theory, FDI helps to increase economic growth based on the significance of capital investment for
achieving growth. FDI is the main source of technology transfer from developed countries to
developing countries, which provides assistance to promote the domestic industry. Usually, developing
countries suffer from less developed infrastructure, political and economic instability due to insufficient
resources. It is generally claimed that FDI could be helpful for the transfer of knowledge, marketing
expertise, managerial skills, and different opportunities to access the market [13,14].

On the other side, according to the dependency school theory advocated by D O’Hearn [15],
V Bornschier [16], and C Stoneman [17], FDI inflows can show a negative relationship with economic
growth in the long-run. The basic reason was that the First World countries after World War II became
wealthier by mining different resources from Third World countries. The developing countries were
inadequately rewarded for their natural resources, which led to continuous poverty in those countries.
The theorists found that capitalism is a basic cause for labor division at a global level. As a result, FDI
can create hurdles for growth and increase the income inequality, which can negatively affect economic
growth in the long-run.

There could also be some other reasons for the negative linkage between FDI and economic
growth. The most important reason is that foreign investment can reduce the production level of
domestic firms through competition in the market. Usually, foreign firms face lower marginal costs
because of a firm-specific advantage, which provides them with the opportunity to captivate demand
away from domestic firms. As a result, their cost is increased and production level decreased. There
is also another reason that foreign firms may not be willing to spread firm-specific knowledge to
domestic firms. As a result, the production of domestic firms could lead to an adverse situation due to
backward technology and less-skilled workers [18].

The debate about the relationship of FDI to economic growth has been extensively studied in the
literature. However, the empirical results are varied across countries based on domestic human capital,
infrastructure, and domestic policies to promote foreign investment and trade. Some studies revealed
the direct linkage of FDI with economic growth, while there are also many studies in the literature



Sustainability 2019, 11, 192 8 of 21

that have highlighted the inverse linkage of FDI with economic growth. Studies that have specifically
focused on FDI in the power and energy sector and its effect on economic growth are rarely available
in the empirical literature. Most of the prior studies have focused on the analysis of overall FDI and its
relationship to economic growth along with different exogenous variables.

The studies that focused on a single country to explore the nexus of FDI–economic growth
include MA Almfraji, MK Almsafir, and Y Liu [19]; C Zhao and J Du [20]; M Belloumi [21]; F Khatun
and M Ahamad [12]; Y Hao, L Zhu and M Ye [22]; JS Mah [23]; MA Fadhil and MK Almsafir [24];
C Chakraborty and P Nunnenkamp [25]; S Anwar and S Sun [26]; and CF Tang and BW Tan [27].
The studies that selected multiple countries to analyze the nexus of FDI–economic growth include
P Gupta and A Singh [28]; S Iamsiraroj [29]; A Omri and B Kahouli [30]; G Agrawal [31]; D Herzer [18];
S Adams [13]; P Srinivasan, M Kalaivani, and P Ibrahim [32]; M Al-Iriani [33]; and SL Gui-Diby [34].

For example, in the case of a single country to examine the nexus of FDI–economic growth,
MA Almfraji, MK Almsafir, and Y Liu [19] used time-series data for the period 1990–2010 by focusing
on Qatar as a sample. Using Vector Auto-Regression (VAR) and Granger causality tests, the results of
the study showed a significant effect of FDI inflows on economic growth in the long-run. C Zhao and
J Du [20] used a unit root test, the vector error correction model (VECM), the Augmented-Dickey–Fuller
(ADF) test, and a co-integration test, and found a non-significant causal relationship between FDI and
economic growth in the context of China for the period 1985–2003.

Moreover, M Belloumi [35] applied the ARDL bounds testing technique to study the relationship
among trade openness, economic growth, and FDI by using data on Tunisia for the period 1970–2008.
The findings of the study highlighted that there is no significant causality between economic growth
and FDI. More specifically, F Khatun and M Ahamad [12] could not find causality between FDI in the
energy sector and economic growth in both the long-run and the short-run by using Granger causality
tests in case of Bangladesh.

In the case of multiple countries to analyze the nexus of FDI–Economic growth, P Gupta and
A Singh [28] used a panel of data on BRICS countries for the period from 1992 to 2013. Using the
ordinary least square (OLS) technique, the Johansen co-integration technique, and VECM, the results
showed a causal relationship between FDI and economic growth in the context of China, Brazil,
and India. Furthermore, the results also showed a short-run causal relationship between FDI and
economic growth in the case of China. S Iamsiraroj [29] applied the fixed effect model and the
Generalized Method of Moments (GMM) model to a sample of 124 countries for the time span
1971–2010. The findings established the direct linkage of FDI with economic growth, while economic
freedom, trade openness, and labor force, as the major determinants of FDI, were found to directly
increase the income growth.

Moreover, A Omri and B Kahouli [30] observed the relationship between FDI, energy consumption,
and economic growth by constructing a panel dataset of 65 countries for the period 1990–2011. They
divided the panel dataset more into three sub-panel datasets based on various income levels. Using
simultaneous equations with GMM, the results revealed bi-directional causality between FDI and
economic growth in some countries. G Agrawal [31] employed VEC Granger causality and panel
co-integration, and confirmed causality between FDI and economic growth by using a panel dataset
on BRICS countries for the period 1989–2012. Table 1 shows a summary of the main empirical studies
about the FDI–economic growth nexus.



Sustainability 2019, 11, 192 9 of 21

Table 1. A Summary of Empirical Studies on the Foreign Direct Investment (FDI)–Economic Growth Nexus.

Author (s) Country Sample Period Analysis Technique Findings

Single Country Studies

Y Hao, L Zhu and M Ye [22] China 1995–2010
The vector error correction model (VECM), fully

modified ordinary least squares (FMOLS)
Bi-directional causality exists in the

long-run

JS Mah [23] China 1983–2011 Johansen co-integration test; Granger causality test Mixed Results

MA Fadhil and
MK Almsafir [24]

Malaysia 1975–2010
Unit root tests, Johansen Co-integration test,

Hierarchical Multiple Regressions (HMR)
Significant positive relationship.

C Chakraborty and
P Nunnenkamp [25]

India 1987–2000 Granger causality tests, Johansen co-integration.
Bi-directional causality in the

manufacturing sector.

S Anwar and S Sun [26] Malaysia 1970–2007 Generalized Method of Moments (GMM) Significant positive relationship.

CF Tang and BW Tan [27] Malaysia 1972–2009
Unit root tests, Johansen–Juselius co-integration test,

Granger Causality tests, ECM
Bi-directional causality

Multi-Country studies

D Herzer [18] 44 developing countries 1970–2005 Heterogeneous panel co-integration techniques
On average: a negative effect in

most of the countries

S Adams [13] Sub-Saharan African countries 1990–2003 Ordinary least square (OLS) model, Fixed effect model
Mixed results, positive results in

case of OLS

P Srinivasan, M Kalaivani
and P Ibrahim [32]

SAARC countries 1970–2007
Johansen co-integration test, VECM, the Impulse

response function
Bi-directional causality exists in all

selected countries except India

M Al-Iriani [33]
Bahrain, Kuwait, Oman, Saudi

Arabia, and United Arab Emirates
1970–2004 Granger causality test, Panel co-integration test Bi-directional causality

SL Gui-Diby [34] 50 African Countries 1980–2009 System generalized method of moment (SYS-GMM)
Mixed results, 1980–1994 negative,

1995–2009 positive



Sustainability 2019, 11, 192 10 of 21

3.2. Energy Consumption and Economic Growth

In the economics literature, the debate about the nexus of energy consumption and economic
growth was initiated by J Kraft and A Kraft [36], and found the strongest evidence of a relationship
between these variables by using data on the United States for the period 1947–1974. Afterward, many
researchers examined causal relationships by using Granger causality and tested four hypotheses:
(a) the conservation hypothesis, (b) the neutrality hypothesis, (c) the feedback hypothesis, and (d) the
growth hypothesis [37].

Neoclassical economists, such as ER Berndt [38] and EF Denison [39], argued that energy is not the
significant factor that causes economic growth based on the assumption that energy affects economic
growth only in definite ways. On the contrary, ecological economists, such as RU Ayres and I Nair [40],
proposed a model in which they highlighted energy as the main factor of production based on the
Laws of Thermodynamics. Afterward, other researchers, such as CJ Cleveland, R Costanza, CA Hall,
and R Kaufmann [41], also endorsed their model by finding significant evidence about the relationship
between economic production and energy. Furthermore, DI Stern [42] also considered energy to be
a vital factor in production.

A fairly considerable number of studies have focused on the linkage of energy consumption
with economic growth in many countries. The studies that focused on a single country to analyze
the relationship between these variables include I Ozturk and A Acaravci [43]; X-P Zhang and
X-M Cheng [44]; N Bowden and JE Payne [45]; M Shahbaz, M Zeshan, and T Afza [46]; AS Alshehry
and M Belloumi [47]; W Oh and K Lee [48]; M Belloumi [21]; G Erdal, H Erdal, and K Esengün [49];
F Karanfil [50]; W Lise and K Van Montfort [51]; K Bakhsh, S Rose, MF Ali, N Ahmad, and
M Shahbaz [52]; and F Khatun and M Ahamad [12]. The studies that concentrated on multiple
countries to examine the energy consumption–economic growth nexus include VC Govindaraju and
CF Tang [53]; E Lau, X-H Chye, and C-K Choong [54]; RPP Pradhan [55]; N Apergis and JE Payne [56];
J Asafu-Adjaye [57]; AM Masih and R Masih [58]; S Noor and M Siddiqi [59]; C-C Lee, C-P Chang, and
P-F Chen [60]; and B-N Huang, MJ Hwang, and CW Yang [61].

For example, in the case of a single country to analyze the nexus of energy consumption and
economic growth, I Ozturk and A Acaravci [43] used the ARDL technique and Granger causality tests,
and revealed a relationship among economic growth, employment rate, and energy consumption;
however, while carbon emissions and energy consumption did not show causality with economic
growth, the employment rate showed a causal relationship with economic growth in Turkey for the
sample period 1968–2005. In addition, X-P Zhang and X-M Cheng [44] used a multivariate model to
analyze the relationship among carbon emissions, urban population, economic growth, and energy
usage by selecting China as a sample for the period 1960–2007. Using co-integration and Granger
causality tests, the results highlighted the unidirectional causality between energy consumption and
economic growth in the long-run.

With the same view, M Shahbaz, M Zeshan, and T Afza [46] analyzed the relationship between
renewable and non-renewable energies and economic growth by selecting Pakistan as a sample for the
period 1972–2011. Using ARDL and Granger causality tests, the results established a long-run causal
relationship between energy consumption and economic growth. AS Alshehry and M Belloumi [47]
examined the inter-relationship between economic activity, energy consumption, and energy price
for Saudi Arabia by using data for the period 1971–2010. Using Johansen multivariate co-integration
tests and VECM, the results indicated that there is unidirectional causality running from energy
consumption to economic growth in the long-run.

In the case of multiple countries to examine the nexus of energy consumption and economic
growth, VC Govindaraju and CF Tang [53] employed the co-integration technique and VECM to
analyze the relationship among CO2 emissions, economic growth, and coal consumption in India
and China. The results highlighted the causality among coal consumption, economic growth, and
CO2 emissions in the case of China, but not in India. The results confirmed a unidirectional causal
relationship between CO2 emissions and economic growth. E Lau, X-H Chye, and C-K Choong [54]



Sustainability 2019, 11, 192 11 of 21

studied the causality between energy consumption and economic growth in the context of 17 Asian
countries by using a panel of data for the time duration from 1980 to 2006. The results of the
study revealed that there is a long-run equilibrium in the selected countries. Furthermore, energy
consumption showed direct causality with economic growth both in the long-run and in the short-run.

In addition, RPP Pradhan [55] explored the relationship of energy consumption, electricity
consumption, and oil consumption with economic growth by selecting SAARC countries as a sample
for the time duration 1970–2006. Using the Johansen co-integration technique and VECM, the results
of the study highlighted unidirectional and bidirectional causality among the variables across the
selected countries based on the type of energy consumption. N Apergis and JE Payne [56] applied the
Pedroni co-integration technique and VECM, and revealed unidirectional causality between economic
growth and energy consumption by using data on six Central American states for the period 1980–2004.
A summary of important empirical studies on the energy consumption–economic growth nexus is
shown in Table 2.



Sustainability 2019, 11, 192 12 of 21

Table 2. A summary of Empirical Studies on the Energy Consumption (EC)–Economic Growth Nexus

Author (s) Country Sample Period Analysis Technique Findings

Single Country Studies

W Oh and K Lee [48] Korea 1970–1999 Granger causality and VECM Unidirectional causality from EC to GDP

M Belloumi [21] Tunisia 1971–2004 Granger causality and VECM
Bi-directional causality in the long-run;

Unidirectional causality in the short-run

N Bowden and JE Payne
[45]

USA 1949–2006 Toda–Yamamoto Unidirectional causality from EC to GDP

G Erdal, H Erdal, and K
Esengün [49]

Turkey 1970–2006
Granger causality test, Johansen

co-integration test
Bi-directional causality

F Karanfil [50] Turkey 1970–2005 Granger causality test, Co-integration test Unidirectional causality from GDP to EC

W Lise and K Van
Montfort [51]

Turkey 1970–2003 Co-integration test Unidirectional causality from GDP to EC

Multi-Country studies

J Asafu-Adjaye [57]
The Philippines, Thailand,

India, Indonesia
1971–1995;
1973–1995

Granger causality test, Co-integration test
Bi-directional causality in case of The

Philippines and Thailand; Unidirectional
causality in case of India and Indonesia

AM Masih and R Masih
[58]

6 Asian countries 1955–1990
Granger causality test, Co-integration

test-ECM
Mixed results

S Noor and M Siddiqi
[59]

5 South Asian Countries 1971–2006
Granger causality test, Co-integration

test-ECM
Mixed results

C-C Lee, C-P Chang,
and P-F Chen [60]

22 OECD countries 1960–2001 Panel Co-integration-Panel VEC Overall, Bidirectional causality

B-N Huang, MJ Hwang,
and CW Yang [61]

82 countries with different
income levels

1972–2002 GMM, Vector Auto-Regression (VAR) model
Mixed results; Unilateral causality in
middle and high-income countries



Sustainability 2019, 11, 192 13 of 21

4. Materials and Methods

This section contains the empirical models and techniques to find causality among the FDI in the
power and energy sector, the energy consumption, and the economic growth of Pakistan in both the
long-run and the short-run.

4.1. Empirical Approach and Data Collection

The Vector Error Correction Model (VECM) and Vector Auto-Regression (VAR) are the two
prominent empirical models that are usually employed to identify Granger causality among variables
in such studies. VAR can be employed if the variables show integration at first order I(1) with no
co-integration; otherwise, VECM can be applied in the case of co-integration with the same order of
integration [44]. Hence, there is the prerequisite to detecting the order of integration of each variable
before selecting VECM or VAR.

We employed two unit roots tests, the Augmented-Dickey–Fuller (ADF) and Philips–Perron
(PP) tests, to check the stationarity of each variable of the model. After identifying it, we employed
the Johansen co-integration test to analyze the long-run relationship among variables of the model.
We employed VECM to detect causality among variables of the model in the long-run and short-run
by following the approach adopted by the prior studies of M Belloumi [21], and G Erdal, H Erdal,
and K Esengün [49]. Furthermore, we employed the variance decomposition (VDC) test to have more
consistent results by following the prior study conducted by S-D Park [62].

We used annual time-series data on FDI in the power and energy sector of Pakistan, energy
consumption, and gross domestic product (GDP) for the period 1990–2017. The data were obtained
from the State bank of Pakistan (SBP) and World Development Indicators (WDI).

4.2. Empirical Models

To find the co-integration and causality among FDI in the power and energy sector, energy
consumption, and GDP by using the Johansen co-integration test and VECM, in line with a prior
study [12], this study ponders the following equations:

∆lnFD It =
K11

∑
i=1

α11i ∆lnFD It−i +
k12

∑
j=1

α12j ∆lnGDPt−j +
k13

∑
l=1

α13l ∆lnECt−l + α13 ECTt−1+ ∈1t + α10 (1)

∆lnECt =
K21

∑
i=1

α21i ∆lnECt−i +
k22

∑
j=1

α22j ∆lnFD It−j +
k23

∑
l=1

α23l ∆lnGDPt−l + α23 ECTt−2+ ∈2t + α20 (2)

∆lnGDPt =
K31

∑
i=1

α31i ∆lnGDPt−i +
k32

∑
j=1

α32j ∆lnECt−j +
k33

∑
l=1

α33l ∆lnFD It−l + α33 ECTt−3+ ∈3t + α30 (3)

In Equations (1) to (3), FDI, EC, and GDP represent foreign direct investment, energy consumption,
and gross domestic product, respectively, as a proxy for economic growth. All variables are set into
their natural logarithmic form before the empirical analysis. It is helpful to interpret the series in
growth terms after considering the first difference. ECT stands for error correction term, which
highlights the long-run effect in these variables; κs shows the lag count; and ∆s are the difference
operators to detect short-run disturbances in these variables. Furthermore, ∈1t, ∈2t, and ∈3t are the
error terms. The causation of all endogenous variables of the model is interlinked with their lag
values and the disequilibrium value of the preceding period. ECTs are usually used to capture the
long-run effect in the model. If all of the variables of the model are out of equilibrium, then there is
a requirement to adjust the dependent variable to minimize the error. This is generally known as the
adjustment of equilibrium error [12].

For the time-series data, it is required to check the stationarity for each series by using unit root
tests. If the linear combinations of non-stationary series convert into their stationary form with the



Sustainability 2019, 11, 192 14 of 21

same order of integration, the co-integration approach is applied [63]. If the variables are co-integrated,
VECM can be employed to find the Granger causality among the variables. We adopted the same
approach to find the causality among FDI in the PESP, energy consumption, and economic growth
as depicted in Figure 6. In this procedure, in Equation (1), GDP (EC) shows Granger causality to FDI
if the coefficients of lagged GDP (EC) or the coefficient of the lagged error correction term ECTt−1
shows statistical significance. Similarly, in Equation (2), FDI (GDP) shows Granger causality to EC
if the coefficients of lagged FDI (GDP) or the coefficient of the lagged error correction term ECTt−2
shows statistical significance. Likewise, in Equation (3), EC (FDI) shows Granger causality to GDP if
the coefficients of lagged EC (FDI) or the coefficient of the lagged error correction term ECTt−3 shows
statistical significance.

Sustainability 2018, 10, x FOR PEER REVIEW  2 of 21 

 

integrated, VECM can be employed to find the Granger causality among the variables. We adopted 

the same approach to find the causality among FDI in the PESP, energy consumption, and economic 

growth as depicted in Figure 6. In this procedure, in Equation (1), GDP (EC) shows Granger causality 

to FDI if the coefficients of lagged GDP (EC) or the coefficient of the lagged error correction term 

𝐸𝐶𝑇𝑡−1 shows statistical significance. Similarly, in Equation (2), FDI (GDP) shows Granger causality 

to EC if the coefficients of lagged FDI (GDP) or the coefficient of the lagged error correction term 

𝐸𝐶𝑇𝑡−2 shows statistical significance. Likewise, in Equation (3), EC (FDI) shows Granger causality to 

GDP if the coefficients of lagged EC (FDI) or the coefficient of the lagged error correction term 𝐸𝐶𝑇𝑡−3 

shows statistical significance. 

 

Figure 6. The nexus of FDI in the power and energy sector of Pakistan (PESP), Energy Consumption, 

and Economic Growth. 

5. Empirical Results 

5.1. Descriptive Statistics 

Table 3 highlights the descriptive statistics for each variable of the model. The average value of 

FDI is 490.69 with a standard deviation of 347.24, which shows the higher variations among the values 

of FDI. The minimum value for FDI is 80 with the maximum value of 1285.44. The average value of 

energy consumption is 465.83 with a standard deviation of 33.58, which shows less variations among 

the values. The minimum value for energy consumption is 397.27 with a maximum value of 523.76. 

The mean value of GDP is 799.09 with a standard deviation of 385.33, which highlights the higher 

variations among the values of GDP. The minimum value of GDP is 371.57 with a maximum value 

of 1547.85. 

Table 3. The Descriptive Statistics. 

5.2. Unit Root Tests 

We checked the stationarity of each variable, including FDI, energy consumption, and GDP, by 

using the Augmented-Dickey–Fuller (ADF) and Philips–Perron (PP) unit root tests; the results are 

shown in Tables 4 and 5, respectively. The criteria to decide on a stationary or non-stationary series 

is dependent on the test statistics and probability values of the variables. The results of both tests— 

Variables Units Mean Median Minimum Maximum Std. Dev. 

Foreign Direct 

Investment 

Current USD 

in Millions 
490.69 322.56 80.00 1285.44 347.24 

Energy 

Consumption 

Kg of Oil 

equivalent 

(Per Capita) 

465.83 469.24 397.27 523.76 33.58 

GDP 

Current USD 

in Millions 

(Per Capita) 

799.09 606.70 371.57 1547.85 385.33 

Figure 6. The nexus of FDI in the power and energy sector of Pakistan (PESP), Energy Consumption,
and Economic Growth.

5. Empirical Results

5.1. Descriptive Statistics

Table 3 highlights the descriptive statistics for each variable of the model. The average value of
FDI is 490.69 with a standard deviation of 347.24, which shows the higher variations among the values
of FDI. The minimum value for FDI is 80 with the maximum value of 1285.44. The average value of
energy consumption is 465.83 with a standard deviation of 33.58, which shows less variations among
the values. The minimum value for energy consumption is 397.27 with a maximum value of 523.76.
The mean value of GDP is 799.09 with a standard deviation of 385.33, which highlights the higher
variations among the values of GDP. The minimum value of GDP is 371.57 with a maximum value
of 1547.85.

Table 3. The Descriptive Statistics.

Variables Units Mean Median Minimum Maximum Std. Dev.

Foreign Direct
Investment

Current USD in Millions 490.69 322.56 80.00 1285.44 347.24

Energy
Consumption

Kg of Oil equivalent
(Per Capita)

465.83 469.24 397.27 523.76 33.58

GDP
Current USD in Millions

(Per Capita)
799.09 606.70 371.57 1547.85 385.33

5.2. Unit Root Tests

We checked the stationarity of each variable, including FDI, energy consumption, and GDP,
by using the Augmented-Dickey–Fuller (ADF) and Philips–Perron (PP) unit root tests; the results are
shown in Tables 4 and 5, respectively. The criteria to decide on a stationary or non-stationary series is
dependent on the test statistics and probability values of the variables. The results of both tests—ADF
and PP—highlight that all of the variables of the models are non-stationary at the level; however, these
variables are converted to be stationary at the first difference with a I(1) order of integration.



Sustainability 2019, 11, 192 15 of 21

Table 4. The Results of Augmented-Dickey–Fuller (ADF) Unit Root Tests.

Variables

Augmented-Dickey–Fuller (ADF) Test

Order of
Integration

Constant Constant and Trend

At Level
At 1st

Difference
At Level

At 1st
Difference

∆LNFDI
−1.3986
(0.5680)

−4.7820
(0.0008)

−4.2279
(0.0162)

−4.6716
(0.0049)

I(1)

∆LNEC
−2.5164
(0.1228)

−3.5833
(0.0134)

−0.4776
(0.9784)

−4.7532
(0.0041)

I(1)

∆LNGDP
0.1483

(0.9636)
−4.4949
(0.0015)

−1.6087
(0.7626)

−4.5154
(0.0072)

I(1)

Note: The corresponding probability values are given in parenthesis.

Table 5. The Results of the Philips–Perron (PP) Unit Root Tests.

Variables

Philips–Perron (PP) Test

Order of
Integration

Constant Constant and Trend

At Level
At 1st

Difference
At Level

At 1st
Difference

∆LNFDI
−1.4154
(0.5598)

−4.7771
(0.0008)

−2.5017
(0.3247)

−4.6541
(0.0051)

I(1)

∆LNEC
−2.4232
(0.1451)

−3.5833
(0.0134)

−0.5413
(0.9746)

−4.7524
(0.0041)

I(1)

∆LNGDP
0.10918
(0.9605)

−4.4826
(0.0016)

−1.6087
(0.7626)

−4.4992
(0.0073)

I(1)

Note: The corresponding probability values are given in parenthesis.

5.3. Johansen Co-Integration and Granger Causality Tests

Before applying the Granger causality tests, the Johansen Co-integration technique was applied
to analyze the co-integration among the variables of the model. The results of this approach are
displayed in Table 6. The number of lags is determined by following the Akaike Information Criterion
(AIC). On the basis of trace and maximum Eigenvalue tests, the hypothesis of ‘none’ co-integrating
equations in the model is rejected at the 5% significance level. Hence, it can be extracted that FDI,
energy consumption, and GDP have at least one co-integration equation, which highlights the long-run
integration among the variables of the model.

Table 6. The Results of the Johansen Co-integration Test.

Number of Co-Integration
Equations

Eigenvalue
Trace Test Max. Eigenvalue Test

λtrace
5% Critical

Value
Prob. λmax

5% Critical
Value

Prob.

None ** 0.586 35.69 29.80 0.009 22.896 21.132 0.028
At most 1 0.385 12.80 15.50 0.122 12.625 14.265 0.089

Note: ** specifies 5% significance level to reject the hypothesis.

After finding the co-integration among the variables, the VECM was applied to ascertain the
sources and specify the directions of causality among FDI in the PESP, energy consumption, and
GDP in the long-run and the short-run. The results are shown in Table 7. The decision criteria are
dependent on the test statistics, which comprise the values of t-tests and Wald tests. The Wald tests
were employed to analyze the causality among variables in the form of a group. The results of Wald
test-1 do not show mutual Granger causality of energy consumption and FDI to GDP, χ2 = 3.7613



Sustainability 2019, 11, 192 16 of 21

(0.1525). Furthermore, the results of Wald test-2 confirm the mutual Granger causality of GDP and FDI
to energy consumption, χ2 = 6.6050 (0.0368). Moreover, the results of Wald test-3 do not highlight the
mutual Granger causality of GDP and energy consumption to FDI, χ2 = 2.8156 (0.2447).

Table 7. The Results of the Granger Causality Test (VECM).

Dependent
Variables

Sources of Causation
Short-Run

Relationship
Long-Run

Relationship
Short-Run Granger Causal Relationship Long-Run

∆LNFDI ∆LNEC ∆LNGDP ECTt−i

∆LNFDI -
1.3999

(0.2367)
0.5704

(0.4501)
0.7986

(0.4275)
No causality No

∆LNEC
0.00108
(0.9738)

-
6.5928 **
(0.0102)

−4.0363 *
(0.0001)

GDP causes
EC

Yes

∆LNGDP
1.0448

(0.3067)
3.0630 ***
(0.0801)

-
1.3564

(0.1798)
EC causes

GDP
No

Note: *, **, and *** represent the 1%, 5%, and 10% significance levels, respectively. The corresponding probability
values are given in parenthesis.

The results highlight that both GDP and energy consumption do not have a causal relationship
with FDI in both the short-run and the long-run. In contrast, positive bi-directional causality is found
to run from GDP to energy consumption and from energy consumption to GDP in the short-run
at the 5% and 10% significance levels, respectively. This predicts that an increase in GDP leads to
an increase in energy consumption and vice versa. It can be extracted that the economic growth of
Pakistan is dependent on energy consumption, as it plays a vital role in creating economic activity in
the country. Our results are consistent with the findings of the previous studies conducted by G Erdal,
H Erdal, and K Esengün [49], J Asafu-Adjaye [57], C-C Lee, C-P Chang, and P-F Chen [60], C-C Lee
and C-P Chang [64], S Paul and RN Bhattacharya [65], S-H Yoo [66], and J Asafu-Adjaye [57] to find
the causality between economic growth and energy consumption in the context of different countries.

Bi-directional causality between GDP and energy consumption is inevitable for Pakistan, which
is a rapidly growing developing country. Bi-directional causality has also been found in the case of
many emerging countries, such as Turkey and India. Indeed, the economic growth helps to accelerate
the energy consumption at the beginning. On the other side, technological development caused by
economic growth helps to bring energy sources to the country, which stimulate the economic growth.
Because Pakistan is highly dependent on external energy sources, any hurdle in the way of energy
supply could disrupt the energy consumption. As a result, the overall economic development of the
country could be adversely affected.

Furthermore, the coefficient of ECTt−1 is found to be insignificant, which indicates that a long-run
equilibrium relationship does not exist from GDP and energy consumption to FDI in Equation (1).
The coefficient of ECTt−2 is found to be significant at the 1% level of significance in Equation (2); so,
it confirms the presence of a negative long-run equilibrium relationship from FDI and GDP to energy
consumption. This result is similar to the findings of the previous study conducted by F Khatun and
M Ahamad [12], which found a negative long-run equilibrium relationship from FDI and GDP to
energy consumption in the context of Bangladesh. As we have mentioned earlier, Pakistan is facing
the problem of circular debt and receiving a large amount of FDI, which consists mainly of loans.
If Pakistan could not pay back these loans in the future, then the economy of Pakistan is likely to
be negatively affected by yet more accumulated debt. Eventually, the energy consumption could
be adversely affected in the long-run. The coefficient of ECTt−3 is found to be insignificant, which
highlights that a long-run equilibrium relationship does not exist from FDI and energy consumption
to GDP in Equation (3).

In addition, Table 8 highlights the results of the variance decomposition test. The results
demonstrate that GDP shows a strong self-explanatory power in the short-run, while it is decreased to



Sustainability 2019, 11, 192 17 of 21

91% in the long-run. The other two variables, FDI and energy consumption, do not show shocks to
the GDP in the short-run. Moreover, 94% of FDI is explained by shocks to the FDI in the short-run.
This self-explanatory power of FDI is decreased to 89% in the long-run. In the short-run, GDP
accounts for 6% of FDI, while FDI is affected by the energy consumption in the long-run. Furthermore,
energy consumption shows a self-explanatory power of 82% and 24% in the short-run and long-run,
respectively. In the short-run, 0.25% of FDI is explained by shocks to energy consumption and increases
over time, followed by GDP. These findings suggest that energy consumption is highly affected by
economic growth in the short-run.

Table 8. The Results of the Variance Decomposition Test.

Variance Decomposition of LNGDP Variance Decomposition of LNFDI Variance Decomposition of LNEC

Period LNGDP LNFDI LNEC Period LNGDP LNFDI LNEC Period LNGDP LNFDI LNEC

1 100.000 0.0000 0.0000 1 5.9930 94.0070 0.0000 1 17.5759 0.2483 82.1758
2 95.0154 0.5998 4.3848 2 2.9564 94.8890 2.1546 2 30.2690 5.8008 63.9302
3 94.1765 0.6920 5.1314 3 2.9420 93.3473 3.7106 3 25.4088 16.3689 58.2224
4 93.0484 0.8583 6.0933 4 3.3556 91.7630 4.8813 4 21.2041 27.1569 51.6390
5 92.5040 0.9614 6.5346 5 3.7874 90.5917 5.6209 5 16.7429 37.6393 45.6178
6 92.0632 1.0592 6.8777 6 4.0831 89.8014 6.1155 6 13.2055 46.8122 39.9824
7 91.7666 1.1398 7.0936 7 4.2783 89.2817 6.4400 7 10.5498 54.4693 34.9809
8 91.5337 1.2124 7.2540 8 4.3952 88.9452 6.6596 8 8.6843 60.6554 30.6603
9 91.3544 1.2764 7.3692 9 4.4615 88.7297 6.8088 9 7.4308 65.5681 27.0011

10 91.2087 1.3340 7.4573 10 4.4938 88.5943 6.9118 10 6.6233 69.4453 23.9314

6. Conclusions and Policy Implications

This study highlighted the present situation of the PESP and empirically analyzed the causality
among the FDI in the power and energy sector, the energy consumption, and the economic growth of
Pakistan for the period 1990–2017. We employed ADF and PP unit root tests to check the stationarity
of each variable. The results of these tests highlight that all of the variables of the models are
non-stationary at the level; however, these variables are converted to be stationary at the first difference
with a I(1) order of integration. After converting the variables into their stationary form, we employed
the Johansen co-integration technique and a Granger causality test (VECM) to find the causality among
variables in the long-run and short-run. Moreover, we employed the variance decomposition (VDC)
test to yield more consistent results.

The sector-wise comparison of FDI reveals that the PESP has received a relatively higher amount
of FDI than other sectors of the economy in recent years. Furthermore, the trends in energy production
and energy usage reveal a substantial gap in previous years. The empirical results of the study
confirmed the presence of a positive bi-directional causal relationship between energy consumption
and economic growth. It refutes the assumption of neoclassical theory that energy is unbiased to
growth. It also indicates that the declining trend in energy consumption could be harmful to economic
growth and vice versa. Therefore, policy-makers should formulate policies to ensure the availability of
energy and efficient energy usage for the production of goods and services.

Furthermore, the results of the study highlight that there is a negative long-run equilibrium
relationship between FDI and GDP with energy consumption. Presently, the power and energy
sector of Pakistan (PESP) is facing a severe problem of circular debt while also receiving loan-based
investments to meet its needs. If Pakistan could not pay back its loans in the future, the economy
of Pakistan is likely to be negatively affected by yet more accumulated debt. Ultimately, the energy
consumption could be adversely affected. We suggest that the GOP should attain the minimum
debt level and discourage loan-based investments. They should find alternative investment sources
(without loans) and also formulate policies to increase the tax collection and export level.

Moreover, the GOP should make serious efforts to deal with the major constraints on the power
and energy sector, such as intense reliance on oil and gas, de-rated capacity, circular debt, energy
security and threats, and bad governance. It should adopt alternative, and less costly, energy sources



Sustainability 2019, 11, 192 18 of 21

to decrease the intense reliance on oil and gas. The de-rated capacity of energy units could be better
by investing more funds to overhaul the energy units. The problem of circular debt could be fixed by
real investment (without loans), effective management, and control over the cash flows. It is necessary
to take effective security measures in remote areas to exercise control over energy security problems.
Better governance, by hiring productive staff and controlling the corruption factor, could be beneficial
to improve the performance of Pakistan’s power and energy sector.

Author Contributions: Conceptualized, drafted methodology, data collected & analyzed, and wrote-original
manuscript, R.L.; reviewed and supervised this study, L.L.

Funding: The APC was funded by Nanjing Agricultural University, China.

Acknowledgments: The authors would like to acknowledge the financial support provided by Nanjing
Agricultural University, China. Furthermore, we acknowledge the comments and suggestions given by
anonymous reviewers that have significantly improved the quality of our work, and the overall support of
Nadeem Khan from Nanjing Agricultural University, China to complete this study.

Conflicts of Interest: The authors declare that the research was conducted in the absence of any commercial or
financial relationships that could be construed as a potential conflict of interest.

Abbreviations

ADF Augmented-Dickey Fuller
AIC Akaike Information Criterion
ARDL Autoregressive Distributed Lag
CPEC China Pakistan Economic Corridor
CPPA Central Power Purchase Agency
DISCOS Distribution Companies
ECT Error Correction term
FDI Foreign Direct Investment
GDP Gross Domestic Product
GENCOS Generation Companies
GMM Generalized Method of Moments
GOP Government of Pakistan
IPPs Independent Power Producers
KESC Karachi Electric Supply Corporation
LNG Liquefied Natural Gas
NTDC National Transmission & Dispatch Company
OGDCL Oil and Gas Development Company Limited
PAEC Pakistan Atomic Energy Commission
PARCO Pak Arab Refinery Limited
PESP Power and Energy Sector of Pakistan
PHPL Power Holding Private Limited
POL Pakistan Oilfields Limited
PP Philips-Perron
PPL Pakistan Petroleum Limited
PRL Pakistan Refinery Limited
PSO Pakistan State Oil
SAARC South Asian Association for Regional Cooperation
SNGPL Sui Northern Gas Pipelines Limited
SSGCL Sui Southern Gas Company Limited
VAR Vector Auto Regression
VECM Vector Error Correction Model
WAPDA Pakistan Water and Power Development Authority



Sustainability 2019, 11, 192 19 of 21

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	Introduction 
	Overview of Pakistan’s Power and Energy Sector 
	The Structure of Pakistan’s Power and Energy Sector 
	Suppliers of Primary Energy 
	Power Generators and Power Distributors 
	End Consumers 

	Major Constraints on Pakistan’s Power and Energy Sector 
	Intense Reliance on Oil/Gas 
	De-Rated Capacity 
	Circular Debt 
	Energy Security and Threats 
	Bad Governance 

	Energy Production, Import, and Consumption 
	The Role of FDI in Pakistan’s Power and Energy Sector 

	Theoretical and Literature Framework 
	Foreign Direct Investment (FDI) and Economic Growth 
	Energy Consumption and Economic Growth 

	Materials and Methods 
	Empirical Approach and Data Collection 
	Empirical Models 

	Empirical Results 
	Descriptive Statistics 
	Unit Root Tests 
	Johansen Co-Integration and Granger Causality Tests 

	Conclusions and Policy Implications 
	References