Sociology and Anthropology 6(11): 845-853, 2018 http://www.hrpub.org 
DOI: 10.13189/sa.2018.061105 

Urbanisation and Energy Crisis: the Case of Lagos State 

Lai Olurode1, Wakeel Isola2,*, Demola Adebisi2 

1Department of Sociology, Faculty of Social Science, University of Lagos, Lagos State, Nigeria 
2Department of Economics, Faculty of Social Science, University of Lagos, Lagos State, Nigeria 

Copyright©2018 by authors, all rights reserved. Authors agree that this article remains permanently open access under 
the terms of the Creative Commons Attribution License 4.0 International License 

Abstract  The study employed in-depth interviews to 
collect information from households living in the upper 
class areas of Magodo, Lagos and those living in the slum 
areas of Iwaya. The locations were chosen purposively. 
The responses from the interviewees indicate that both high 
and lower neighbourhoods in Lagos experience epileptic 
power supply and that resident have learnt to cope with the 
power situation using diverse strategies of coping. The 
various responding mechanisms adopted by those 
consumers, however, are based on financial capabilities. 
From the interviews conducted, it was apparent that both 
high income and low income families tend towards the use 
of generators. However, they also make use of lamps and 
solar energy in few cases. Also, both classes of families use 
gas stoves as an alternative to electric stoves for cooking. 
And occasionally they use kerosene stoves. Planning ahead 
was a recurring feature among the households, which 
indicated how they prepared for the eventualities of power 
outages. The study concludes that the way out of the 
problem is to fully implement the Power Sector Reforms. 
In addition, there is the urgent need to diversify the sources 
of generating electricity in Nigeria and mitigate the 
problem of corruption, which has been the bane of the 
sector over the years.  

Keywords  Urbanization, Megacity, Epileptic Power 
Supply, Lagos State 

 

1. Introduction
A visit to a typical urban scene in most of the third world 

countries will bear an eloquent testimony to a breakdown 
of municipal governance.  It is a common experience that 
frequent power outage, poor road network, slums and 
mountains of refuse and other signs of urban decay have 
become the hallmarks of many of these urban cities. In 
spite of this, migrants have continued to flow in without 
regard for the huge pressure on infrastructure and social 
services. That urbanization poses a threat to social services 
in third world cities is therefore not in doubt.  

 Perhaps, it is not a mere coincidence that a high rate of 
urbanization has spurred the development of some 
megacities across the globe. According to the United 
Nations [34], there were 31 megacities globally and this 
number is projected to rise to 41 by 2030. Of the world’s 31 
megacities in 2016, 24 are located in the less developed 
regions. China alone according to this study had six 
megacities in 2016, while India had five. Africa can only 
boast of three countries that have attained the status of a 
megacity namely Kinshasa, Cairo and Lagos. The growth 
and development of the megacities are expectedly, not 
without some challenges such as access to electricity, 
which has been a source of concern in less developed 
countries. 

Legros et al, [16] admit that about 1.5 billion people lack 
access to electricity in the less developed countries (LDCs). 
In relation to other regions of the world, the study state that 
625 million and 560 million people are without access to 
modern fuels and electricity in sub-Saharan Africa. It 
further stated that less than 200 million people in East 
Asia and the Pacific lack access to electricity. 

 About 79% of the people are without electricity access 
in developing countries. 74% of them are in sub-Saharan 
Africa, compared to the 28% in LDCs. This means that 
even though access to energy varies widely across LDCs, 
energy access is far lower in poorer developing countries 
than in richer ones Legros et al, [16]. The implication of 
this is also that a large percentage of the population is 
without access to modern fuels. According to USAEE [32] 
in 2012, out of the 1.3 billion people who lack access to 
electricity, over 600 million are in sub-Saharan Africa, 
while over 300 million come from India alone. However, 
the World Economic Outlook WEO, [35] maintains that 
about 16% of the world population (i.e. 1.2 billion people) 
lack access to electricity in 2016.  

In Nigeria, while electricity access has grown from 27.3% 
in 1990 to 57.7% in 2014 World Bank, [34], the problem of 
urbanization has continued to play down the impact of such 
growth over time. Currently, out of the 170 million of 
Nigeria’s population, about 98 million are without access 
to electricity. The national electrification rate in Nigeria as 
at the end of 2014 was 45%, out of which urban 



846  Urbanisation and Energy Crisis: the Case of Lagos State  
 

 

electrification rate was 55%, while rural electrification rate 
was 36%. Similarly, in terms of biomass for cooking, the 
population relying on biomass in Nigeria is 134 million; 76% 
of this relied on the traditional use of biomass in 2014 
WEO [35]. It means that generally in Nigeria, access to 
modern energy is very low and the energy crisis is very 
high. The low rate of rural electrification in Nigeria and 
inaccessibility to modern energy has made the rural-urban 
migration a necessity and an irresistible trend. This has 
further exacerbated the problem of urbanization and 
deepened the energy crisis in the urban areas, especially in 
Lagos State. Expectedly, the fact that urbanization has 
occurred arbitrarily in Lagos has exerted a severe strain on 
existing infrastructure and contributed immensely to 
energy crisis in the state. Resolving this urban growth 
problems vis-à-vis those of the energy crisis should be of 
paramount interest to Nigeria; especially Lagos State. This 
would help to fast-track the goal of achieving sustainable 
development in the state and improve the living conditions 
of the citizenry. 

Against this background, this study seeks to evaluate the 
pushing effects of urbanization and unstable electric power 
supply on the growth of the Lagos State economy. The 
motivation for the study stems primarily in the realization 
that poor electricity supply in the face of a rising 
urbanization demand could pose a devastating problem on 
growth. Hence, the need to offer suggestions that can 
ameliorate the challenges.  

The relevant questions this study addresses include: Is 
there any gap between the secondary energy supply such as, 
electricity and the requirements of the city? What are the 
strategies employed to cope with the problem of the 
electricity gap on the households? These questions will be 
analyzed within the context of power sector reforms in 
Nigeria for necessary policy options. 

The rest of the study is organized as follows: section 2 
presents the stylized facts on the population of  Lagos 

State and electricity sector in Nigeria, with special 
reference to Lagos. Review of relevant literature is 
presented in section 3. Sections 4 and 5 focus on the 
methodology and results of the study. 

Stylized Facts on the Population and Electricity 
Infrastructure in Lagos State  

Lagos State Population and Trend 
Lagos, the 8th largest city in Africa, has continued to 

experience an unprecedented growth in its population since 
1950. The National Bureau of Statistics (NBS) [19] and 
National Population Commission [20] put the population 
of Lagos at 325,000 and 8,859,000 in 1950 and 2005, 
respectively. However, Lagos achieved the status of a 
mega city in 2010, with a population of 10,781,000. It has 
been projected that by 2030 the population will be about 
24,239, 000. This is trend is shown in figure 1. 

Electricity in Nigeria 

The electricity industry began in Nigeria towards the end 
of the 19th century. The first generating plant was installed 
in Lagos in 1898 by the colonial government and was 
managed by the Public Works Department (PWD). In 1950, 
the government passed the Electricity Corporation of 
Nigeria Ordinance No. 15. Thereafter, several other 
legislations were enacted. These include the Niger Dam 
Authority (NDA) Act of Parliament of 1962 and the Decree 
4 of June 1972, by which the National Electric Power 
Authority (NEPA) was established. NEPA was mandated 
to maintain an efficient, coordinated and economic system 
of electricity supply to all parts of Nigeria. The law made 
NEPA a monopoly by making it the sole body responsible 
for the generation, transmission, distribution and marketing 
of electricity. 

 

Figure 1.  Trend of population of Lagos state 

 



  Sociology and Anthropology 6(11): 845-853, 2018 847 
 

 

As a state-owned establishment, NEPA was inefficient 
in service delivery, innovation and management. In an 
effort to reverse the poor electricity tale, the government 
decided in 2000 to embark on a comprehensive review of 
the sector, in terms of policy and institutional reforms. 
NEPA and its successor company, the Power Holding 
Company was corporatized and commercialized and this 
enabled the organization to review its tariffs upward 
without an appreciable increase in quantum of electricity 
generation. The most radical change came with the passage 
of the Electric Power Sector Reform Act (EPSRA) in 2005 
which made Nigeria to effectively join the global 
restructuring and deregulation trend. Under the reform, 
NEPA/PHC was broken into 18 companies, comprising 6 
generators, 11 distributors and one transmission company. 
In addition, the deregulation of the sector again opened up 
the market for the Independent Power Producers and other 
private initiatives by other stakeholders including state 
governments, such as Lagos State. 

Current Situation with Lagos State Electricity 

Lagos State is the only Nigerian state with a very 
aggressive Ministry of Energy and Mineral Resources. The 
establishment of this ministry was borne out of the fact that 
the Lagos State Government has in recent times embarked 
on several energy-related projects which range from 
Independent Power Plants to Solar Energy Projects and to 
Public Lighting largely inspired by the power sector reform. 
It also covers Household energy and emissions calculators 
Lagos State Electricity Board [14]. The Independent Power 
Plants (IPPs) set up by the State are designed to improve 
electricity access by taking the state off the national grid. 
The State previously operated 3 IPPs at Akute, Lagos 
Island and Alausa. It has so far installed 32.55MW, 
connected to more than 50 load centers and supplied over 
70KM of public lighting. According to the Lagos State 
Electricity Board, the IPPs have helped to drastically 
improve the electricity supply reliability from 30% to about 

99% on the average, making them more effective in 
providing better service to the populace. The State also 
currently has two additional IPPs: the Mainland Power and 
the Peninsula Integrated Power Project. The two IPPs have 
a combined capacity 14.8MW. To ensure that the State 
sustains and improves on its present energy supply 
condition, it embarks on a state-wide energy audit with the 
aim of collating a comprehensive database of the real-time 
power demand of Lagosians and that of the installed 
capacity from the grid. Consequently, over 13,000 
residential, industrial and commercial locations were 
audited at the end of 2013 and the exercise revealed that 
only a little above 10% of electricity demand by the state 
was met by the national grid. The state discovered over 
17,000 generators in the audited locations, meaning that 
each location has at least 1 generator. This translated to the 
consumption of about 162,000 litres of diesel per day and 
resulted in about 178lbs carbon emission per day. In order 
to curb the volume of emissions arising from electricity 
consumption in the metropolis, the Lagos State Electricity 
Board (LSEB) recently took a stand in favor of renewable 
energy.  The office of the LSEB in Ikeja currently 
generates about 70% of its energy from a 12kWp Solar 
farm installed within its premises LSEB, [15]. 

Nigeria only generates less than 5000MW for a 
population of 170 million. Incidentally, Lagos State 
accounts for 40% of the total electric supply for industrial, 
commercial and domestic demands as characterized by the 
power supply companies, thus highlighting the picture of 
the problem. For example, in 2013, the demand for 
electricity was approximately 5000MW in the Eko Disco 
Zone alone Eko Disco [5]. In 2011, the distribution 
capacity of both Ikeja and Eko Discos was put at 854MW 
and 796MW respectively, giving a combined total of 
1650MW. Also, the customer population of each of the 
Discos was put at 658, 701 and 286, 758 respectively The 
Nigeria Energy Support Programme (NESP) [30].  A 
summary of this picture is depicted in table 1.

Table 1.  ELECTRICITY SUPPLY GAP in LAGOS STATE in Megawatts (MW) 

  
Source: Nigeria Energy Support Programme (2015) and own computation. DC (Distribution Capacity). MW (megawatts). 



848  Urbanisation and Energy Crisis: the Case of Lagos State  
 

 

2. Literature Review 
The relationship between urbanization and energy 

related crisis has received a scholarly attention in the 
literature. Parikh and Shukla [23] examined the role of 
urbanization, energy consumption and green-house 
emissions in economic development. The study employed 
a multiple regression framework using a cross section of 
data to analyze the indicators of urbanization and other 
economic indicators. It was observed that aggregate energy 
consumption increases with urbanization.  By the same 
token, Shahbaz and Lean [25] analyzed the relationship 
among urbanization, industrialization and energy 
consumption in Tunisia between 1971 and 2008. It 
employed the autoregressive distributed lag (ARDL) 
bounds testing approach as well as the Granger causality 
tests to analyze the secondary data which cover the 
variables of interest. Findings from the study suggest that a 
bidirectional causality exists between industrialization and 
energy consumption. Additionally, it was observed that 
urbanization intensified the volume of energy consumption 
in Tunisia over the period studied. The study, thus, called 
for the examination of the nexus between industrialization 
and urbanization to fast-track the development process. 
Similarly, Shen et al [26] investigated the relationship 
among urbanization, sustainability and energy utilization 
in China. In the study, the trend among the variables was 
analyzed and it was observed that a positive relationship 
between growth, urbanization and energy demand in China 
existed. The study therefore concluded that if urbanization 
grows faster than predicted, China might face a long term 
resource shortage. In the same vein, Wang [33] analyzed 
the impact of urbanization on China’s energy consumption. 
The study defined two types of energy use in the 
urbanization process as residential energy consumption 
(REC) and production energy consumption (PEC), 
observing however that growth enhanced by urbanization 
increased REC while PEC was consistently reduced 
between 2001 and 2005 in China.  

Certain other studies have also focused on the 
correlation between urbanization and energy consumption, 
where it was observed that a positive relationship exists 
between urbanization and energy use. For instance, Jones 
[13] conducted a cross-sectional study on 59 LDCs and 
observed that urbanization significantly increased energy 
use. Imai [9] empirically observed that urbanization 
contributed to energy crisis in China. Zhou et al [36] 
identified and analyzed three energy-consuming sectors 
that are strongly linked with urbanization as residential, 
industry and transportation. The study fundamentally 
observed a negative relationship between energy demand 
and urbanization. Ewing and Rong [6] observed that more 
urban areas had very reduced energy consumption 
per-capita in Canada.  Similarly, other studies have 
focused on the causal link between urbanization and energy 
consumption. A study by Liu [17] revealed that 

urbanization has a positive causal effect on energy 
consumption in China. Fan and Xia [7] found out the same 
results in China. Mishra et al [18] observed that short term 
causality exists between energy consumption and 
urbanization in the Pacific Island Countries. In another 
study by Halicioglu [8], it was observed that causality runs 
from prices, urbanization and GDP to energy consumption 
in Turkey between 1968 and 2005. 

World Bank [34] report on African urbanization 
revealed that African countries lag behind their peers in 
developing countries in terms of infrastructure provision. 
Access to electricity reaches only 16 percent of African 
citizens, when compared with the 41 percent in other 
developing countries. Average power consumption is 124 
kilowatts per capita, or 10 percent of that in the rest of the 
developing world. African firms report losing 5 percent of 
their sales because of frequent outages. This figure jumps 
to 20 percent for informal firms. While private firms are 
eager to explore the potential of African growing markets, 
lack of infrastructure constitute major obstacles to private 
investment.  

According to Arnulf and Jayant [1], rapid migration and 
natural population growth in cities can overwhelm the 
provision of basic urban services, particularly for the poor 
urban dwellers. Several hundred million urbanites in low 
and middle income nations lack access to electricity and 
are unable to afford cleaner, safer fuels, which result 
in-significant adverse consequences for human health and 
local air quality.  

Supporting Sub-Saharan African Municipalities with 
Sustainable Energy Transitions SAMSET [28] showed that 
total population in South Africa is growing at 1 percent per 
annum. The population is predominantly urban, and 
currently 64 percent of the approximately 52 million total 
population live in towns or cities, of which 40 percent are 
located in the large metros. This is expected to increase to 
70 percent by 2030. Cities and towns produce 80 percent of 
South Africa’s Gross Value Added (GVA), and home to 
around two-thirds of the population. With the 
predominantly urban growth, South Africa has not been 
able to address the challenges of poverty levels 
substantially. The main energy dimensions of this include 
thermally uncomfortable housing and lack of access to 
modern affordable energy sources. Poor households spend 
14 percent, on average, of their income on basic energy 
needs, as opposed to 2 or 3 percent for wealthier 
households. In South Africa, the modern energy focus has 
been on electricity provision. The report also showed that 
national electrification rate levels are 87 percent when 
compared to 36 percent in 1994. However, a significant 
number of households remain without electricity 
connection. The current electrification backlog is 1.2 
million for the informal and 2.1 million formal households.  

Simon and Innocent [27], in their review of literature of 
the nexus between urbanization and energy demand in 
Ghana revealed that energy for lighting in urban Ghana is 



  Sociology and Anthropology 6(11): 845-853, 2018 849 
 

 

predominantly electricity. Though available to all urban 
dwellers, it is inaccessible to urban poor who still depend 
on candles for lighting or get connected illegally from their 
neighbours. The supply of electric power is also very 
unreliable, marked by persistent power fluctuations and 
blackouts. As a result of this, many people have resorted to 
the use of diesel generators, with high pollution levels, to 
satisfy their energy electricity needs. 

In terms of studies in Nigeria, Babanyara and Saleh [2] 
focused on urbanization and fuel wood usage as a source of 
energy in Nigeria between 1990 and 2000. Fuel price hikes, 
rural-urban migration and urbanization were identified as 
the major factors causing fuel wood energy demand in 
Nigeria. It was also confirmed that the country lost an 
annual average of 409,700 hectares of forest to 
urbanization. It then recommended the harnessing of 
renewable energy sources as a panacea for reducing the 
consumption rate of fuel wood in Nigeria. Jiboye [12] 
examined the issues and challenges involved in effective 
urban governance in Nigeria. Three major issues of 
sustainable development and governance, urbanization 
challenges and the necessity for effectively managing 
sustainable urbanization were addressed in the study. It 
was observed that the pervasiveness of urban growth in 
Nigeria has a strong link to globalization, population 
explosion and industrialization. It therefore called for a 
participatory and collaborative effort in addressing 
urbanization crisis.  

The Economic Commission for Africa (ECA) [4], in its 
report on urbanization across cities in the world showed 
that Lagos is Nigeria’s richest state, producing about $90 
billion a year in goods and services, making its economy 
bigger than that of most African countries, including 
Ghana and Kenya. In terms of population, it adds 600,000 
people annually to Nigeria’s population. The report 
concluded that a fastest growing state like Lagos without 
commensurate improvements in social services has pushed 
Lagos to its cliff edge.  

According to a report on the energy sector in Lagos 
conducted by Department for International Development 
(DFID) [3], Lagos was identified as a megacity of over 20 
million people and as the economic capital of Nigeria. Its 
rapid growth places pressure on resources and the 
ecosystem to the extent that these services could not 
support the needs of its citizens. The report also presented a 
stylized fact about the energy situation in Lagos State. The 
report showed that; (1) power deficit in Lagos equal 
9,000-10,000MW and low utilization of generating 
capacity; (2) 40% of the population has no access to the 
electricity grid and inadequate transmission capacity; (3) 
150kWh/yr. average annual consumption; (4) 80% of the 
population relying on diesel generators; (5) governance 
challenges federal-state ownership of management of 
assets; (6) minimal renewable energy in Lagos energy mix 
and; (7) fossil fuel subsidies in place.  

The risk factors facing the Lagos energy- electricity 

sector are highlighted in the report. The report showed that: 
(1) 30 million people will be residing in Lagos in 2030; (2) 
200,000 engineers will be required for the energy sector 
over the next 15 years; (3) $14 to $33 billion is required to 
fund investment in energy-electricity generation by 2030 
depending on technology; (4) 200MW new generation 
capacity will be required for planned mass transit 
infrastructure and; (5) 16,000 to 27,000MW of new 
generation capacity will be required in 2030. 

The potential interventions as shown in the report 
included: (1) development of offshore gas; (2) embedded 
generation-independent power plant (conventional and 
renewable); (3) municipal energy fund to finance rural and 
urban solar projects; (4) community biogas project; (5) 
offshore wind; (6) compressed natural gas transportation; 
(6) promotion of energy efficient appliances and; (7) 
building regulation. 

From the stylized facts on the Lagos energy sector, this 
study aims to carry out a pilot study of the nexus between 
urbanization and electricity crisis in Lagos, with a view to 
revealing and understanding the severity of the electricity 
crisis in the state. The benefit of this pilot study is that it 
gives a glimpse of what the bigger picture might look like. 

3. Methods 
To arrive an in-depth understanding of the coping 

strategies of Lagos residents to the epileptic power supply, 
two households with differing social status were 
interviewed. The first household was chosen from the 
upper class areas of Magodo, Lagos. The household 
include  a family of five who live in a duplex while the 
other household was selected from the slum areas of Iwaya, 
Yaba, Lagos, which is a family of seven living in a single 
room apartment In choosing the representative sample, a 
random sampling method was adopted.  

The following processes were involved in the final 
section procedure for the household in Magodo area. (i) 
Certain criteria were laid out, which include that the 
housing must be a Duplex, with fence all rounds.  Also 
there was a security by the Gate side. (2) The addresses of 
the duplex were taken. (3) The Chairman of the Landlord 
Association was contacted first. (4) The purpose of the  
exercise was well communicated to each and every 
landlord after a formal letter soliciting for their cooperation 
were served to each of them. (5) The purpose of the 
exercise was communicated to each participant before the 
day. (6) A piece of paper which carried a “yes” or “no” of 
addresses of the participants was shuffled and whichever 
option came up would serve as a representative for the   
assignment.  

The same procedure was carried out in Iwaya, Yaba 
corridor/axis except that the assumption of being a duplex 
with fence and security gate was ruled out.  The sample, to 
a very large extent, appeared as a true reflection of the 



850  Urbanisation and Energy Crisis: the Case of Lagos State  
 

 

population of households in Nigeria, thus exhibiting the 
rich and poor dichotomy. In addition, a case study 
illustrating a typical day in the life of an average Lagos 
state resident was discussed. 

The locations were chosen purposively. The intention 
was to select two households with differing social class and 
status, in order to understand their experiences and coping 
strategies with the power situation in Lagos. Magodo is 
known to be a highbrow area in Lagos while Iwaya is one 
of the lower class neighbourhoods in Lagos. In the course 
of this discussion the household from Magodo will be 
referred to as Household A (HHA) and the household from 
Iwaya will be referred to as Household B (HHB). The 
research methodology employed in this work has been 
extensively used in the analysis of other related social 
economic issues (see for example, Olurode, [21], [22] and 
Tade [29] among others. 

In spite of the differing social class and status of the two 
households focused in this study, the interview revealed 
that the coping strategies adopted by them were similar but 
different in terms of intensity and amount. This will be 
discussed accordingly in the subsequent headings. 

4. Results and Discussion of Findings 

Regularity of Power Supply 

In discussing the frequency, duration and stability of 
power supply in Lagos, the two households though in 
opposite ends of the city, claimed that power supply has 
been much better of late. They stated that unlike previous 
experiences when there could be no power supply for two 
to three days consecutively (and in extreme cases for weeks) 
electricity supply has become much better because they 
now enjoy better power supply. Upon further probing, the 
interviewer noted that the ‘better power supply’ the 
consumers alluded to could be for a period of 12 hours in a 
day. In their words:  

“if I had probably had this interview a month ago, I 
would have said power supply is really bad 
however, of recent we’ve been enjoying better 
power supply, We have light at night and during the 
day, at night from like 8 till 8 the following morning 
and then maybe they’ll now bring light at around 
like 12 till 2, then 8 again till 8 again the next 
morning…” (IDI, HHA) 

“For now the power supply is very stable unlike 
before, because whenever I get home, I find out that 
there’s light, there’s light, so most of the things we 
are able to do it with electricity” (IDI, HHB) 

Even though the above account suggests that the power 
situation might have somewhat improved in Lagos, 
respondents also noted the problems in the quality and 
distribution of power. 

“…But about a month ago, we hardly use to have 
power from Disco…and now that there is light, 
sometimes it is not usually enough to power all the 
appliances in the house, I don’t understand but its 
like the power is not distributed evenly. Downstairs 
light is full while upstairs is not at all, while all the 
sockets downstairs are working, all the lights are 
working , those upstairs will not and because we 
can’t put on the generator when there’s light we 
make use of  torches and lamps…” (IDI, HHA) 

Alternative Source of Power 

Many residents of Lagos are unable to rely solely on the 
national grid power supply from the Discos. This is as a 
result of previous experiences of unsteady public power 
supply. Many, therefore, resort to using an alternative 
source for themselves. In the two households interviewed, 
alternative source of power ranged from the use of 
industrial generators, to the smaller sized generators 
(popularly known as ‘I pass my neighbour’) and even to the 
use of electric charged lamps, solar charged lamps, electric 
charged torches and Kerosene lanterns.  In the words of 
one of the respondents:  

“We rely on generators at night, and if there is no 
diesel for the generator, we have charged 
torchlights that we use, and in the mornings we 
rarely put on the generator, we make use of the 
charged lamps and torchlights and at night, we put 
on the generator from 7 till 10pm max” (IDI, HHA) 

It is also important to mention that although none of the 
households make use of inverters or solar energy as 
alternative sources of power, they mentioned having 
knowledge of neighbours and friends who have such 
experiences. This point to the fact that inverters and solar 
energy are also popular means of generating power among 
the residents in Lagos. 

“I even know people who solely rely on solar 
energy, they don’t bother with Discos anymore” 
(IDI, HHA) 

And although Kerosene lanterns are not as common as it 
was before, it is still commonly used among the lower 
income families. The respondents from Iwaya mentioned 
that kerosene lanterns are among their major source of 
light. 

‘We have a kerosene lamp in the kitchen, which we 
use while cooking (IDI, HHB) 

Not too surprising, the respondent from Magodo felt it 
was archaic and outdated to use kerosene lamps. In their 
opinion: 

“Kerosene lamps? No, not at all, that’s like from 
the 19th century” (IDI, HHA) 



  Sociology and Anthropology 6(11): 845-853, 2018 851 
 

 

Dealing with Cooking and Other Domestic Tasks 

Owing to the high rate of urbanization in Lagos, many 
residents have abandoned the traditional ways of cooking, 
carrying out house chores using more modern methods. 
Instead of the use of charcoals and firewood (which are still 
very common in rural areas) residents of Lagos prefer the 
use electric appliances such as electric cookers, electric 
irons and so on. This might partly be due to the fact that 
electrical appliances are better suited to an urban area as 
they are more space efficient. However, the epileptic power 
a supply has resulted in residents seeking alternative ways 
of executing their domestic chores. It is often common 
experience that residents experience electricity power 
disruption, in the middle of their cooking which makes 
looking for alternative sources of power imperative for 
them. From the interview, it was gathered that the most 
common alternatives sought after were gas cookers and 
kerosene stoves for cooking, and for other domestic chores 
such as ironing. These alternatives have been used as 
rescues whenever there was power supply disruption. In 
the words of the respondents:  

“we iron our clothes beforehand, then for washing, 
we make use of the dry cleaner. We have washing 
machine, but we rarely use it because of the power 
situation, so what we do is we pile up the clothes 
until there is light, although we kind of make our 
plans separate from the possibility of power supply 
from Disco, we really don’t rely on Disco” (IDI, 
HHA) 

“We don’t store foods as much, because of the 
unstable power supply, because we might not have 
light for like two three days, we hardly use the 
Mikano, it’s the small gen we use often and that one 
cannot carry the freezer, so we hardly buy food in 
bulk to store. So what we do is buy what we can eat 
within a short period of time”. (IDI, HHA) 

“to generate water, we often have to use the 
pumping machine to pump water, and for that we 
need to put on the mikano gen…but if there’s no 
diesel we either use Meruwa (water sellers) or go 
fetch water from a neighbouring house”  (IDI, 
HHA) 

“To grind pepper I have to use local grinder, the 
stone grinder which makes it very difficult unlike if 
there’s electricity, I can use the electric blender 
which makes it easier” (IDI, HHB) 

“To straighten our clothes when there is no light, 
we fold and put under the pillow or sometimes we 
can take it to somewhere there is light to iron, we 
also take chargeable things like phone, torch to 
charge and pay a token sum to get them charged” 
(IDI, HHB) 

A Day in the Life of an Average Lagos State Resident 

An average resident lives far away from the place of 
work, thus he has to wake up at 5.00 a.m. or thereabout.  
His/her travels time to work would be some two hours to 
his/her place of residence. However, while he/she is 
planning to get his/her clothes ready, public power supply 
goes off. Upon waking up, he rushes his prayers, quickly 
gets hold of the pressing iron to complete the exercise. His 
plan to leave the house by 6.15 a.m. has to be given up. 
Public power went off before he could complete the ironing. 
Attempts to put his power generator (popularly called I 
pass my neighbour) is frustrated. There is not enough fuel 
in the generator and the plug looks bad. 

Having given up on ironing, he rushes out to the bus stop 
to meet a long queue. Of course, he makes it late to work 
but much before his boss could arrive. But the line has been 
drawn. Upon getting inside his office, he quickly charges 
his phone which had run out of power. He also has enough 
time to boil water to make tea as he could not make 
breakfast before leaving the house. A day or two before he 
had thrown away all the fruits and food in his freezer. They 
had gone bad because of epileptic power supply.  

But our average resident is having a sigh of relief as 
additional hours are being added to public power supply. 
He now spends less diesel and petrol. But still, he is unable 
to plan as constant public power supply cannot be 
guaranteed. For the most part, he has to contend with 
‘never expect power always’ – a sad commentary on the 
acronym of the old agency saddled with public power 
supply – NEPA. 

At his backyard, the Lagos resident would have some 
disused generators – a junk backyard of a sort. Not a small 
percentage of his monthly income is spent on diesel or 
petrol purchase. He has to sleep most night without public 
power supply. Whenever the weather is unfriendly, he is 
forced to sleep in the open, not minding severe mosquito 
bite, which makes many vulnerable to malaria – a killer 
disease. 

5. Conclusions 
An assessment of the reliability of power supply in 

Lagos State shows that all the respondents agreed to the 
relative stability of electricity, which has made them to 
enjoy their electricity-powered appliances. This is a pointer 
to the fact that time dimension is an important factor when 
assessing the reliability of electricity supply in Nigeria. In 
fact, electricity is more stable during the rainy season in 
Nigeria.  During this period, hydro power Stations 
generate optimally, with attendant positive effects on the 
quantum of electricity supply in Nigeria. In other words, 
the various efforts of the Lagos State government to boost 
power supply in Lagos has been complemented by the 
climatic factor. The implication of this is that there is a 
need to ensure an appropriate energy mix in the generation 



852  Urbanisation and Energy Crisis: the Case of Lagos State  
 

 

of electricity in Nigeria. This argument has been 
extensively discussed elsewhere; see for example Isola [10] 
and [11]. There is no doubt that the quantum of electricity 
generated in Nigeria is still very low. A comparative 
analysis of Nigeria with her supposed counterparts the 
United Energy Information Agency data is able to show 
that in 2016 the install generating capacity in Brazil was 
150,000 megawatts; Similarly, South Africa generated 
42,000 MW; while Egypt generated 33,000 MW. Nigeria’s 
installed capacity is 6,953 MW, but highest daily output in 
October, 2017 was about 4,600 Mw. This is considered too 
dismal for an economy which experts say needs a 
minimum of 44,000 MW. Perhaps it has become necessary 
to take a cue from other countries such as Peru, Argentina 
and Chile where the privatization of power infrastructure 
has been effective. In Argentina for instance, power 
generation post-privatization rose from about 12,000 MW 
in 1992 to about 23,000 MW in 2002. The reverse is the 
case in Nigeria, which explains the high electricity supply 
gap in Lagos State. This also explains the need to revisit the 
privatization process of the DisCos and the GenCos. This 
will be to ensure and appreciate the beauty of transferring 
of government companies to the private sector as it was 
done to the Telecommunication Industry. 

Finally, the responses from the interviewees indicate that 
both high and lower neighbourhoods in Lagos experience 
unstable epileptic power supply and that resident have 
learnt to cope and adapt with the power situation using 
diverse strategies of coping. The coping mechanisms, 
however, are based on financial capabilities. From the 
interviews, it was apparent that both high income and low 
income families tend towards the use of generators. 
However, they also make use of lamps and solar energy in 
few cases. Both classes of families also use gas stoves as an 
alternative to electric stoves for cooking and occasionally 
they use kerosene stoves. Planning ahead was also a 
recurring feature among the households and families, 
which indicated how they prepared for the possibility of 
power outage. Planning ahead is thus part of the 
respondents’ coping mechanisms. The way out of the 
problem is to fully implement the Power Sector Reform. 
This is capable of providing an efficient supply of power in 
the urban cities and rural areas. More importantly, this can 
be achieved through the rural electrification initiatives. 

 

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	1. Introduction
	2. Literature Review
	3. Methods
	4. Results and Discussion of Findings
	5. Conclusions
	REFERENCES