Population and Environment (2022) 44:46–76
https://doi.org/10.1007/s11111-022-00407-y
ORIGINAL PAPER
Spatial heterogeneity in drinking water sources 
in the Greater Accra Metropolitan Area (GAMA), Ghana
Jacob Doku Tetteh1 · Michael R. Templeton2 · Alicia Cavanaugh3 · 
Honor Bixby4 · George Owusu5 · Sandow Mark Yidana6 · Simon Moulds2 · 
Brian Robinson3 · Jill Baumgartner4 · Samuel Kobina Annim7 · 
Rosalind Quartey7 · Samilia E. Mintah7 · Ayaga Agula Bawah8 · Raphael E. Arku9 · 
Majid Ezzati8,10 · Samuel Agyei‑Mensah1 
Accepted: 17 July 2022 / Published online: 12 August 2022 
© The Author(s) 2022
Abstract
Universal access to safe drinking water is essential to population health and well-
being, as recognized in the Sustainable Development Goals (SDG). To develop 
targeted policies which improve urban access to improved water and ensure equity, 
there is the need to understand the spatial heterogeneity in drinking water sources 
and the factors underlying these patterns. Using the Shannon Entropy Index and 
the Index of Concentration at the Extremes at the enumeration area level, we ana-
lyzed census data to examine the spatial heterogeneity in drinking water sources and 
neighborhood income in the Greater Accra Metropolitan Area (GAMA), the largest 
urban agglomeration in Ghana. GAMA has been a laboratory for studying urban 
growth, economic security, and other concomitant socio-environmental and demo-
graphic issues in the recent past. The current study adds to this literature by telling 
a different story about the spatial heterogeneity of GAMA’s water landscape at the 
enumeration area level. The findings of the study reveal considerable geographical 
heterogeneity and inequality in drinking water sources not evidenced in previous 
studies. We conclude that heterogeneity is neither good nor bad in GAMA judg-
ing by the dominance of both piped water sources and sachet water (machine-sealed 
500-ml plastic bag of drinking water). The lessons from this study can be used to 
inform the planning of appropriate localized solutions targeted at providing piped 
water sources in neighborhoods lacking these services and to monitor progress in 
achieving universal access to improved drinking water as recognized in the SDG 6 
and improving population health and well-being.
Keywords Drinking water sources · Spatial heterogeneity · Inequality · Census 
data · GAMA · Ghana
*  Samuel Agyei-Mensah 
 sagyei-mensah@ug.edu.gh
Extended author information available on the last page of the article
1V o3l:.(1234567890)
Population and Environment (2022) 44:46–76 47
Introduction
The past decade has witnessed significant progress in access to drinking water 
sources globally (Mosello, 2017). Despite these improvements, there are consider-
able disparities in access to and use of improved water1 within cities of the develop-
ing world (Alba et al., 2020; Cha et al., 2021; Deshpande et al., 2020; Mutono et al., 
2022). Since access to improved drinking water is a central concern for popula-
tion health and well-being, several international organizations including the United 
Nations, the World Health Organization (WHO), and United Nations Children’s 
Fund (UNICEF) have been very proactive in setting targets and providing support 
for universal access to safe drinking water. For example, the (United Nations, 2015) 
Sustainable Development Goal (SDG) 6 sets the agenda for addressing inequality 
in global access to water for all by 2030 with goal 10 aiming at reducing inequali-
ties between and within countries. The 2030 Agenda further commits member states 
to “leave no one behind” and states that SDG indicators should be disaggregated, 
where necessary, by income, sex, age, race, ethnicity, migratory status, disability, 
and geographic location (WHO/UNICEF Joint Water Supply Sanitation Monitor-
ing Programme, 2015). To track progress made with regard to universal coverage, 
it is essential to understand the geographical variability in drinking water sources 
and examine the factors driving spatial patterns of drinking water sources and their 
heterogeneities.
We focus on sub-Saharan Africa (SSA) because a large proportion of the world’s 
population without access to improved drinking water live in this region (Prins et al., 
2022; UNICEF & WHO, 2019), so in a sense SSA is emblematic of the very core 
of the struggle for improved drinking water. In addition, SSA has the fastest urban 
population growth; by 2050, SSA’s cities will be home to approximately 950 mil-
lion more people (OECD/SWAC, 2020). Yet, much of the growth has not been well 
planned, putting a strain on existing infrastructure and services, especially in emerg-
ing settlements (Güneralp et  al., 2017). As SSA rapidly urbanizes and improves 
across economic metrics, demand for access to crucial urban services and infrastruc-
ture is growing. Equitable access to quality and affordable housing, clean household 
energy, efficient transportation, and improved drinking water could improve health, 
well-being, and productivity in cities (WHO, 2016).
Despite recent attention to household access to improved water and sanitation 
in resource poor settings, particularly in SSA cities, wide geographical inequities 
in access to safe, reliable, and affordable water persist within cities (Armah et al., 
2018; Deshpande et  al., 2020; Hopewell & Graham, 2014; Pullan et  al., 2014). 
While access to urban drinking water in SSA is considered highly heterogeneous 
(Pullan et al., 2014), within-city water use patterns in SSA cities remain understud-
ied (Adams & Smiley, 2018; Armah et al., 2018; Stoler et al., 2013), presenting a 
barrier to municipal policy formulation and evaluation.
1 An improved drinking water source is the source that has the potential of delivering safe water by 
nature of its design and construction (UNICEF & WHO, 2019).
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 48 Population and Environment (2022) 44:46–76
Previous studies on variations in drinking water sources in SSA have largely focused 
on between-country analyses (Adams & Smiley, 2018; Armah et al., 2018; Deshpande 
et al., 2020; Hopewell & Graham, 2014; Pullan et al., 2014). A few studies have also 
examined disparities in drinking water within countries and major SSA cities (Cha et al., 
2021; Cole et al., 2018; Grace et al., 2017; Osei et al., 2015; Songsore & McGranahan, 
1998; Thompson et al., 2000). However, only a handful of studies have examined water 
drinking patterns at localized settings2 for fast growing metropolitan cities in SSA (see 
Alba et al., 2019; Cha et al., 2021; Cole et al., 2018; Thompson et al., 2000), which is 
needed to better understand inequality in the provision of local infrastructure and essen-
tial services.
Ghana has achieved broad economic progress in recent decades which is reflected 
in improvements in the household environment, including access to improved water 
and sanitation and cleaner cooking fuels (Arku et al., 2016). Accra, Ghana’s capital, 
has engulfed its surrounding districts (often referred to as the Greater Accra Metro-
politan Area) in an expansion characterized by low-density urban sprawl (Akubia 
& Bruns, 2019; Owusu, 2013; Owusu & Oteng-Ababio, 2015). As a result, it faces 
numerous urban development challenges, including inadequate urban drainage system, 
inadequate housing, poor connecting roads, and high traffic congestion (Cobbinah 
et  al., 2020). In this regard, the provision of improved water sources as one of the 
priorities of SDG 6 is relevant as it seeks to achieve universal and equitable access 
to improved drinking water for all by 2030 (Deshpande et al., 2020; United Nations, 
2015; UNICEF & WHO, 2019). However, to develop targeted policies which improve 
urban access to improved drinking water and ensure equity, there is a need to under-
stand the geographical heterogeneity and inequality in drinking water sources.
GAMA is the largest urban agglomeration in the country and accounts for almost a 
quarter of the national GDP (Gaisie et al., 2019). It has become a laboratory for study-
ing urban growth, resource securities, and other concomitant socio-environmental and 
demographic issues within the recent past (see Aliu et al., 2021; Bixby et al., 2022; 
Dapaah & Harris, 2017; Gaisie et al., 2019) and the current study adds to this bur-
geoning literature by telling a different story about the heterogeneity of GAMA’s water 
landscape at the enumeration area level. Previous studies relied on sample survey data 
of selected neighborhoods of GAMA and were not comprehensive enough to iden-
tify fine-scale patterns (Ablo & Yekple, 2018; Asante-Wusu & Yeboah, 2020; Benneh 
et al., 1993; Songsore & McGranahan, 1993; Stoler et al., 2012b). An exception is the 
case of Moulds et al. (2022) that used census data to partially analyze sachet water 
consumption among the administrative districts of Ghana but did not examine the spa-
tial heterogeneities of drinking water sources at the enumeration area level.
To analyze the spatial heterogeneity in drinking water sources, we employed the 
Shannon’s Entropy Index to demonstrate the diversity in sources of drinking water at 
the enumeration area level. We also used the Index of Concentration at the Extremes 
2 A locality or localized setting is defined as a distinct population cluster (also designated as inhabited 
place, populated center, settlement) which has a name or locally recognized status (GSS, 2010a). Locali-
ties are sometimes also referred to as “communities” in this article.
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Population and Environment (2022) 44:46–76 49
to examine neighborhood wealth status. Characterizing spatial heterogeneity of 
drinking water sources is important as it provides insights into the varied sources of 
drinking water along with the drivers of water consumption. Additionally, it helps 
us to know the different strategies people use in their water consumption as well as 
identify priority areas for intervention. Spatial heterogeneity is good if it means that 
residents of EAs can find improved drinking water which is publicly managed and 
affordable. Heterogeneity is bad if it means that residents of EAs are not consist-
ently finding improved drinking water or only finding the more expensive types of 
improved drinking water, for example, vendor provided.
We specifically address two main research questions: (1) How much heterogene-
ity in drinking water sources exists within neighborhoods in GAMA?; and (2) does 
heterogeneity in drinking water source type differ by neighborhood wealth status? 
The findings of the study can be used to inform the planning of appropriate local-
ized solutions and monitor progress in achieving universal access to safe water as 
recognized in the Sustainable Development Goal 6 and improving population health 
and well-being.
Urban water access in Africa
The research questions posed in this paper intersect with several established fields 
of research that provide an empirical and theoretical context for studying spatial het-
erogeneities in water sources. We first briefly consider broad perspectives on sources 
of urban drinking water. Next, we examine the factors which drive heterogeneity and 
inequality.
Sources of drinking water
To begin with, there are three broad perspectives on how best to deliver safe drink-
ing water in urban areas in the developing world. The first examines the expansion 
of piped water infrastructure facilitating the chlorination and filtration of water 
prior to its distribution (Burrows, 2019). The second view emphasizes individual 
and household-level interventions such as chlorine-based disinfectants, filtration, 
and solar disinfection that can be done cheaply and evaluated easily (Geremew & 
Damtew, 2020; WHO, 2019). The third, and most recent, highlights the growth of 
a large private sector that distils and distributes water mostly via sachets, bottles, 
and dispensers (Burrows, 2019; Moulds et al., 2022; Prasetiawan et al., 2017; Zhen 
et al., 2019).
Urban water access in SSA cities is heterogeneous. Planned and affluent resi-
dential areas generally have access to piped water services, whereas low-income 
and peri-urban areas often lack access to the piped network and largely depend on 
non-piped water services such as sachet water, tanker services, and bottled water 
(Cole et  al., 2018; Deshpande et  al., 2020; Geremew & Damtew, 2020; WHO, 
2019). However, even where piped water is available, the use of non-piped sources 
for drinking water is commonplace (Moulds et  al., 2022). These broad categories 
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 50 Population and Environment (2022) 44:46–76
can further be divided into a multiplicity of water sources as provided by the Joint 
Monitoring Programme (JMP) of the WHO and the UNICEF in the JMP ladder for 
drinking water services. This new ladder defines 5 service levels. Improved sources are 
associated with the safely managed, basic, or limited drinking water services3 while 
the unimproved and surface water service levels4 are categorized as unimproved 
(UNICEF & WHO, 2019, see also Table 1). As shown in Table 1, most of the water 
source types in GAMA are improved sources.
Factors influencing water source heterogeneity and inequality
The review of literature that follows provides the setting for explaining why hetero-
geneity in drinking water sources exists. Our goal is not to measure these factors in 
the analysis, but rather to use them to explain the drivers behind these heterogenei-
ties. We hope that future research could incorporate them more explicitly into an 
explanatory framework for water source heterogeneity.
Colonial and post‑colonial imprint on the urban landscape
The legacies of uneven development during the colonial and post-colonial period are 
critical in understanding inequalities in water access in urban areas in SSA. One of 
the central characteristics of colonial urbanization was residential and spatial seg-
regation perpetuated by unjust land policies, resulting in inequalities in water infra-
structure in a number of African cities (Bohman, 2012; Dill & Crow, 2014; Njoh & 
Akiwumi, 2011; Peloso et al., 2018; Songsore et al., 2009; Tempelhoff, 2003, 2017). 
Myers (2003) gives an account of how unequal power influenced the production of 
space under colonial rule in the cities of Nairobi, Lusaka, Zanzibar, and Lilongwe. 
Njoh and Akiwumi (2011) note that access to improved water supply in East African 
cities was a function of the duration of the colonial era: access was greater in cities 
within countries that experienced longer periods of colonization than those in which 
the colonial era was brief.
Colonial policies have also had a profound impact in shaping the spatial structure 
of Accra (Andersson, 2017; Brand, 1972; Harris, 2021; Songsore et al., 2009). Harris 
(2021) notes that the variegated nature of water access in Accra can be traced to the lega-
cies of infrastructure and development during the colonial period that served to condition 
uneven infrastructure and water flows. Based on field work in Accra, Andersson (2017) 
observed that the city of Accra is an example of how “segregation works in cyclical, 
3 A limited drinking water service is an improved source for which collection time exceeds 30 min for a 
round trip including queuing; A basic drinking water service is an improved source provided the collec-
tion time is not more 30 min of round trip including queuing; A safely managed drinking water service 
is an improved water source located on premises, available when needed and free from fecal and priority 
chemical contamination (UNICEF & WHO, 2019).
4 An unimproved drinking water service is drinking water from an unprotected dug well or unprotected 
spring; A surface water drinking service is drinking water directly from a river, dam, lake, pond, stream, 
canal, or irrigation canal (UNICEF & WHO, 2019).
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Population and Environment (2022) 44:46–76 51
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Table 1  Classification of drinking water source types in GAMA
Household drinking water facility type in the Number of households Households coverage Grouped coverage Classification/grouping Improved/
Census module questionnaire (in %) (in %) unimproved 
systems
Pipe-borne inside dwelling 266,341 27.2 64.2 Piped water sources Improved
Pipe-borne outside dwelling 276,048 28.2
Public tap/standpipe 86,669 8.8
Bottled water 10,728 1.1 32.8 Vendor sources Improved
Sachet water 283,291 28.9
Tanker supply/vendor provided 27,120 2.8
Borehole/pump/tube well 14,891 1.5 2.5 Other sources Improved
Protected well 4723 0.5
Rain water 1533 0.2
Protected spring 3380 0.3
Unprotected well 1098 0.1 0.5 Other sources Unimproved
Unprotected spring 218 0.0
River/stream 2162 0.2
Dugout/pond/lake/dam/canal 992 0.1
Other 933 0.1
 52 Population and Environment (2022) 44:46–76
self-reinforcing patterns,” supporting the assertion that segregation and inequality that 
existed because of colonial policy is an important part in explaining the contemporary 
socio-spatial structure. Similar segregation policies existed in other colonial West Afri-
can towns such as Freetown and Dakar (Bigon, 2012; Phillips, 2002).
There is also a growing body of literature on how water governance processes 
since the post-colonial neoliberal regime of water privatization and the failure of the 
state to provide sufficient water to the population have led to the presence of new 
water delivery regimes in GAMA including sachet and bottled water, water tankers, 
and water vendors (see Alba et  al., 2019; Asante-Wusu & Yeboah, 2020; Bartels 
et al., 2018; Tutu & Stoler, 2016; Yeboah, 2006). It is also interesting to note that 
since independence in 1957, the residents of the city of Accra have been instrumen-
tal in the water network’s granular extension into neighborhoods and across different 
strata. Thus, what we see today reflects the processes of integration and fragmenta-
tion of the water network (Uitermark & Tieleman, 2021). Thus, GAMA is character-
ized by a multiplicity of water sources including in house piping, private standpipe, 
communal standpipe, sachet water, bottled water, and water from vendor.
Provision of water infrastructure
Closely related to the colonial and post-colonial imprint on the landscape is the 
issue of the provision of water infrastructure. Recent research in Lilongwe, Malawi, 
shows that investments in the production of extra water resources mostly benefited 
those who were already better served (Tiwale et al., 2018). Thus, pipes are not just 
conduits of water but also of power; infrastructural developments are shaped by 
economic, social, and political forces that co-determine socio-ecological inequali-
ties (Tiwale et al., 2018). Since the establishment of Lilongwe as a planned city in 
Malawi, networked infrastructure has grown inequitably over space and time, favor-
ing newly planned central and northern zones of the city that include parliament, 
ministries, embassies, government offices, hotels, commercial and industrial areas, 
and the airport while neglecting the low-income areas growing along the southern 
part of the city (Tiwale, 2019).
In the Accra Metropolitan Area of Ghana, having water connection at home 
does not necessarily guarantee regular supply because of water rationing and 
intermittent water flow (Peloso et  al., 2018; Stoler et  al., 2012a). Because of 
the uneven water supply outlets within the city, multiple water provision sys-
tems have emerged such as tankers, sachet water, and boreholes with a plural-
ity of actors whose practices are informed by a range of motives. These motives 
go beyond profit-making, political legitimacy, patronage, and petty corruption 
to include solidarity, religious beliefs, and pragmatic choices (Alba et  al., 2020). 
Maintenance issues with respect to water infrastructure have also restricted 
water access. In Lusaka, Zambia, the urban water infrastructure built during the 
1960s and 1970s has not undergone any major expansion and is insufficient to 
meet the needs of the current population  (Hubbard et  al., 2020).  A World Bank 
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Population and Environment (2022) 44:46–76 53
report published in 2017 also noted the problem of aging infrastructure in the 
water sector and its accompanying effects, such as leakage of water pipes, and 
called for more investment in that sector (Van den Berg & Danilenko, 2017). 
Lack of piped water system maintenance has also been reported by Thompson 
et  al. (2000) for some cities in East Africa. In some instances, the lack of, or 
limited access to, water in informal low-income and slum neighborhoods is 
largely due to deliberate policy of city authorities. Where city authorities view 
emerging slums or poor communities as occupying illegal lands or squatting, 
they are unlikely to make any infrastructure and service investments in these 
areas, despite continuous population growth and pleas for these investments by 
residents (Awumbila et al., 2014; Sinharoy et al., 2019).
There are also issues of trust and human rights when it comes to the provision 
of water infrastructure. Whereas in Cape Town water quality and satisfaction are 
linked to trust in government, this is not the case in parts of Accra. For residents 
of Nima in Accra, water access and quality are important for people’s lives, but 
are less strongly connected to a sense of governmental responsibility (Harris, 
2021). Similarly, in South Africa, water privatization signaled an immense con-
flict because the country’s constitution indicated that everyone has a right to 
have access but privatization excluded many poor black South Africans. This is 
not the case in Ghana where there is a general acceptance of a need to pay for 
water delivery service (Yates & Harris, 2018).
Dapaah and Harris (2017) provide an entitlement approach to water access 
that broadens the perspective beyond infrastructural endowments (e.g., piped 
water), to include a range of other socioeconomic, socio-cultural, and local insti-
tutional characteristics. They note in their study in two communities in Accra, 
Ghana, that among other factors that are important to everyday negotiations and 
entitlements related to water access are familial and kin networks, water stor-
ing options available to households and vendors, the distance and waiting time 
to fetch water, and local leaders’ perceptions of water issues, particularly how 
these compare with broader citizen understandings.
Private sector participation in urban water provision and management in 
many parts of Africa has increased significantly to address the deficit in piped 
water access. Thus, the consumption of sachet and bottled water has become 
very common among many households in Ghana, Nigeria, and Sierra Leone 
(Dada, 2009; Fisher et  al., 2015; Stoler et  al., 2013). The increasing patronage 
of sachet water in particular despite some of the issues raised about its qual-
ity (see Dzodzomenyo et  al., 2018; Mosi et  al., 2019) reflects both the failures 
of municipal water management as well as a lack of funding to extend water 
services to deprived areas (Stoler, 2017; Stoler et  al., 2012b, 2013; Yeboah, 
2006). There is also a growing body of literature on how water governance 
processes such as the role of multiple private water vendors and tanker driv-
ers shape the distribution and access to water especially in peri-urban and low 
income neighborhoods of GAMA (Alba et  al., 2019; Bartels et  al., 2018; Tutu 
& Stoler, 2016).
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 54 Population and Environment (2022) 44:46–76
Population growth and urban expansion
In many parts of Sub-Saharan Africa, population growth and urban territory 
expansion make it difficult for the state and municipal authorities to provide water 
infrastructure in pace with the increasing needs of the population (Asante-Wusu 
& Yeboah, 2020; Ayeni, 2017; Cobbinah et  al., 2019; Stoler et  al., 2013). This is 
because the distribution systems of network pipes have not changed in any remark-
able way since the early independence era. Between 1975 and 2010, the urban 
population in the Global South tripled, growing by 2 billion people. Most of this 
growth occurred in Sub‐Saharan Africa and Asia where water insecurity, or the 
lack of access to adequate and safe water for a healthy and productive life, was 
already shaping lives and inhibiting development (Adams, 2018). Many of the 
worst affected areas are slums and informal settlements and areas of intensified 
growth (Adams, 2018; Angoua et  al., 2018; Dos Santos et  al., 2017). Thus, over 
the past decade, a great deal of research has emerged seeking to better understand 
population growth impacts on water access in Africa (Aliu et  al., 2021; Ayeni, 
2017; Cobbinah et  al., 2019, 2020; Dominguez Torres, 2012; Dos Santos et  al., 
2017; Hopewell & Graham, 2014; Stoler et al., 2013). Expansion of water service 
delivery has not happened alongside rapid urbanization. In particular, there is a dis-
connect between water service delivery and urbanization in Ghana. Water strate-
gies and investments have remained sector-specific and have occurred outside of 
broader considerations related to urban expansion and the need to serve the rapidly 
expanding informal and peri-urban settlements (Mosello, 2017).
Financial costs
Financial costs are paramount when it comes to understanding variations in water 
use in urban Africa. The cost of water and the cost of installing water infrastruc-
ture have risen due to privatization of water services. Thus, extending service infra-
structure to low-income peri-urban areas and newly developed housing schemes is 
expensive and often technically difficult (Dos Santos et al., 2017). Moreover, having 
access to a pipe in the home or compound does not guarantee water delivery or ade-
quate piped water quality. Paying for water can be challenging for many residents, as 
documented in cities in Malawi, South Africa, Tanzania, and Namibia (see Adams 
& Smiley, 2018; Cole et al., 2018; Mitlin & Walnycki, 2016). In the Greater Accra 
region of Ghana, the main utility water company, Ghana Water Company Limited 
(GWCL), is finding it increasingly difficult to keep its customers current with their 
water bills and provide adequate service because of poor cost recovery issues relat-
ing to untimely bill payment from the customers (Sualihu et  al., 2017). Studies 
conducted in Nima, an urban informal settlement in Accra, show that residents are 
concerned about the quality of water, connection fees, and monthly water bills. The 
findings provide valuable information that policymakers and water utilities can use 
to assess the feasibility and cost effectiveness of extending household taps to poor 
urban settlements (Adams & Vásquez, 2019).
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Population and Environment (2022) 44:46–76 55
The research presented here explores the diversity in drinking water sources 
within the various enumeration areas of GAMA. We examine the association 
between these multiple drinking water sources and income inequalities along with 
the factors driving these diversity, with the goal of identifying priority areas for pol-
icy intervention.
Method
Study area
The study was undertaken in the Greater Accra Metropolitan Area (GAMA). 
Administratively, GAMA has undergone various transformations and fragmentation. 
Table  2 shows that GAMA was formally divided into three main districts: Accra 
Metropolitan Area (AMA), Tema Municipal Area (TMA), and the Ga District (GSS, 
2005). In 2004, these local government areas increased from three to four and later 
doubled in 2008 in response to mainly the phenomenon of urban growth and sprawl 
(Owusu, 2015). As of 2012, GAMA comprised of 12 metropolitan, municipal, and 
district assemblies (MMDAs) (Fig.  1, Table  2). For this analysis, we use the 12 
MMDAs present from 2012. Presently, this contiguous built-up metropolitan area 
has 25 MMDAs (Ghana-Districts, 2020) with estimated projection over 4.7 million 
residents (GSS, 2020). These MMDAs are where policy decisions are implemented.
Of the 12 administrative districts, the AMA has the largest population of over 
1.6 million people while Adenta Municipal Area recorded the lowest population of 
about 78,200 (Table 2). In 2010, GAMA recorded a population of close to 3.8 mil-
lion inhabitants occupying 5019 enumeration areas (EAs). The AMA has the most 
EAs, followed by the Ga South Municipal Area, then by the TMA while Kpone 
Katamanso District is observed as having the least EAs coverage (See Table  2; 
Fig. 3).
Based on census reports, the Ga District experienced the highest growth rate of 
about 58% annually from 1960 to 2010, followed by the TMA (47.5%) with AMA 
experiencing the least growth rate of about 9% even though is the most populated 
region. The whole of GAMA, notwithstanding, grew at about 15% annually from 
1960 to 2010 (see Fig. 2).
Urbanization and urban expansion are central to our understanding of variation 
in water demand and use in GAMA. Accra Metropolitan Area (AMA)’s popula-
tion growth in recent decades is largely due to its growing position as an industrial, 
administrative, and commercial center (Agyei-Mensah & Wrigley-Asante, 2014). As 
the seat of government, the high cost of land and limited residential spaces have 
push migrants and low-income residents into the creation of slums and squatter set-
tlements which often lack essential services such as water and sanitation (Yankson 
& Bertrand, 2012). Although the population of Tema Metropolitan Area (a planned 
industrial hub) has increased beyond the core communities since independence, 
housing developments and water provision has been undertaken within the con-
text of planning before development. The Ga Districts have experienced perhaps 
the most significant population growth over the years because of the availability of 
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 56 Population and Environment (2022) 44:46–76
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Table 2  Population and EA distribution in GAMA by administrative units 2012
Administrative sub-division Total population 2000 Administrative sub-division Administrative Administrative Total population Number of EAs 
(1988) (2004) sub-division sub-division 2010 in 2010
(2008) (2012)
Accra Metropolitan Area 1,658,937 AMA AMA AMA 1,665,086 1929
LaDMA 183,528 207
LeKMA LeKMA 227,932 288
Tema Municipal Area 506,400 TMA TMA TMA 292,773 379
KKDA 109,864 132
AshMA AshMA 190,972 260
AdMA AdMA 78,215 261
Ga District 550,468 GEMA GEMA LaNMA 111,926 219
GEMA 147,742 228
GWMA GWMA GWMA 219,788 363
GCMA 117,220 172
GSMA GSMA 411,377 581
Sources: Derived from Population Census Reports for 2000 and 2010 (GSS, 2005, 2014a, b, c, d, e, f, g, h, i, j, k, l, m; Owusu, 2015)
Population and Environment (2022) 44:46–76 57
Fig. 1  Sub-Administrative demarcation of GAMA as at the 2010 PHC
undeveloped land and congestion in AMA. This growth constrains access to water 
provision (Owusu, 2015; Yankson & Bertrand, 2012).
In terms of water supply, GAMA is served mainly with surface water from two 
major water treatment plants: the Kpong and the Weija Treatment Plants. About 
8% of water also comes from the Teshie Desalination Plant if it is in opera-
tion. The Weija Treatment Plant and the Teshie Desalination Treatment Plant are 
located within GAMA (Fig. 1) while the Kpong Treatment Plant is located 54 km 
Fig. 2  Population of GAMA from 1960 to 2010 (source: Derived from Ghana Statistical Service, Popu-
lation Census Reports for 1960, 1970, 1984, 2000, 2010 censuses) (see Census Office, 1960, 1975; GSS, 
1987, 2005, 2012; Yankson & Bertrand, 2012)
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 58 Population and Environment (2022) 44:46–76
North-East of Tema (GWCL, 2020a, c). These plants are under the management of 
the GWCL—the main urban water utility company in Ghana (GWCL, 2020b). For 
the purposes of their operations, GAMA is divided into three regions: Accra East, 
Accra West, and Tema (GWCL, 2018).
Research design and analytical framework
This analysis relies on the full microdata from the 2010 Population and Housing 
Census (PHC) from the Ghana Statistical Service of Ghana (GSS). Using this data, 
we constructed an enumeration area (EA)-level dataset to examine spatial hetero-
geneities in drinking water sources in GAMA. The datasets are geo-referenced to 
the EA level, of which all the 5019 EAs in the GAMA were used for our analysis 
(see Table 2, Fig. 3). An EA, which has a mean area of 0.301 k m2, is an area of 
land demarcated in order to enumerate houses, structures, and households during 
the Census (GSS, 2010a). These small geographic units represent sub-communities, 
allowing us to examine variations within communities that are typically subsumed 
into larger districts. Using this dataset, we first constructed an entropy index that 
provides a continuous measure of heterogeneity of drinking water sources in each 
EA. Second, we grouped the drinking water sources of each household into four 
categories: piped water sources, vendor sources, other improved sources, and other 
unimproved source (see Table  1) to describe the similarities and differences of 
drinking water sources of the 12 districts. Furthermore, we estimated the income 
inequalities of neighborhoods across GAMA. Lastly, we estimated associations 
between the diversity of drinking water sources and neighborhood income segrega-
tion. With these indicators, we examine how variability in drinking water and segre-
gation are correlated as well as how they are spatially related using a bivariate local 
indicator of spatial association (BiLISA) approach along with the most common 
drinking water types.
Categorizing household sources of drinking water
We used all the water sources listed in the census. There are two questions on water 
sources included in the household module of the census. Our analysis relied mainly 
on answers to the question what is the main source of drinking water for the house-
hold? The 2010 PHC questionnaire survey lists 15 sources of water sources (GSS, 
2010b, see also Table 1).
We considered the classification scheme used by the JMP of the WHO and 
UNICEF. The scheme is categorized into the improved and unimproved sources 
of drinking water types. The improved sources include pipe-borne inside dwelling, 
pipe-borne outside dwelling, public tap/standpipe, borehole/pump/tube well, pro-
tected well, rainwater, protected spring, bottled water, sachet water, and tanker sup-
ply/vendor provided. Non-improved sources consist of the unprotected well, unpro-
tected spring, river/stream, and dugout/pond/lake/dam/canal (GSS, 2010b; UNICEF 
and WHO, 2019). The JMP further classifies improved household drinking water as 
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Population and Environment (2022) 44:46–76 59
being limited, basic, or safely managed services based on accessibility, availability, 
and quality criteria. However, the 2010 PHC lacks enough data for the estimation of 
these services (UNICEF and WHO, 2019).
Estimation of Shannon entropy index
We used the Shannon entropy index in order to offer greater insight into the spatial 
aspects of household drinking water inequality. This index is a continuous measure 
of the degree of variation that reveal the different dimensions in water insecurity 
and the multiple strategies households use to obtain drinking water. Therefore, we 
calculated the entropy index for each EA based on the diverse household drinking 
water sources. This index provides a quantitative measure (ranging from 0 to 1.912 
in Fig. 3) of the level of heterogeneity in drinking water sources among households 
in each EA. The Shannon entropy index was initially applied spatially in the context 
of segregation by Theil and Finizza (1971) and is defined in White (1986) as:
∑k
hi − p ln(p )j=1 ij ij
where h is the entropy at EA i, k is the number of individual drinking water sources, 
and pij is the proportion of a jth drinking water source in EA i ( pij=nij∕ni , nij is the 
count of jth drinking water source in an EA i, and ni is the total count of all drink-
ing water sources in an EA i) (Bandt, 2020; White, 1986). The higher the value of 
hi , the higher the diversity of drinking water sources. Lower values indicate lower 
diversity while a value of zero indicates that the community has only one drinking 
water source (Iceland, 2004; Reardon & Firebaugh, 2002). High diversity is associ-
ated with largely vendor water sources particularly sachet water while low diversity 
is associated with mainly the piped water sources.
Estimation of income inequality
We also considered how spatial income inequality varies across and within the 12 
districts and is associated with community water source variability. While wealth 
is considered a predictor of access to improved water, neighborhood context may 
disrupt households’ ability to access improved water sources. Thus, to get a better 
idea of how households navigate a complex water landscape, we examine how com-
munity economic status impacts these strategies.
We used the Index of Concentration at the Extremes5 (ICE) to classify EA-level 
socio-economic status (i.e. low- and high-income areas), by measuring the degree 
to which GAMA’s population is concentrated into extremes of wealth and poverty. 
5 ICE as developed by Massey “measures the spatial social polarizations of both deprived and privileged 
socio-economic groups simultaneously in one measure” (Chambers et  al., 2019; Krieger et  al., 2016; 
Massey, 2001).
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 60 Population and Environment (2022) 44:46–76
Consumption data in Ghana is available in the Ghana Living Standard Survey 6 
(GLSS 6),6 but it can only be disaggregated to the district-level. As part of our effort 
to produce an EA-level dataset, we employed a small area estimation procedure to 
produce consumption indicators at the EA-level (Elbers et al., 2003). This method 
borrows strength from survey information by fitting a linear mixed model with ran-
dom effects at the area-level to GLSS data and uses parameter estimates to predict 
consumption for all census households (Molina & Rao, 2010; Rodas et al., 2021). 
To develop the ICE metric, we grouped households by their relative position in the 
GAMA consumption distribution; households in the bottom 20% are considered 
low-income, while those in the top 20% are considered high income. ICE is defined 
as:
( )
ICEi = Ai − Pi ∕Ti
where, for EA i, Ai is the number of people in high-income households; Pi is the 
number of people in low-income households; and Ti is the EA-level population. ICE 
ranges from − 1 to 1, with negative values indicating concentration of poverty, while 
values closer to 1 indicate clustering of affluence (Krieger et al., 2016). EAs were 
then classified based on their ICE value; the bottom 20% of EAs were classified as 
low income or deprived while the top 20% were classified as high income or privi-
leged (Chambers et al., 2019; Krieger et al., 2016). This metric allows us to examine 
the extremes of GAMA’s consumption distribution in one metric, and allows us to 
identify the most polarized EAs.
Spatial analysis of drinking water source and neighborhood income
To identify where the associations between drinking water and neighborhood wealth 
emerge within GAMA, we applied bivariate local indicators of spatial associa-
tion7 (BiLISA) to two continuous variables representing diversity in drinking water 
sources (Table 2) and socio-economic status for each EA, the water entropy index, 
and ICE (Anselin et al., 2002). It identifies the relationship between the value of one 
variable at location i (xi) and the average of neighboring values for a second variable 
(i.e., spatial lag of yi). The BiLISA statistic is defined as:
∑
IB = cx w y
i i ij j
j
where c is a constant scaling factor, and wij are the elements of the spatial weights 
matrix. We define wij as a second-order Queen’s spatial weights matrix. The 
6 Consumption in the GLSS 6 is comprised of expenditure categories including Food and Non-Alcoholic 
Beverages; Alcoholic Beverages, Tobacco and Narcotics; Clothing and Footwear; Housing, Water, Electric-
ity, Gas and Other Fuels; Furnishings, Household Equipment and Routine Maintenance of the Household; 
Health; Transport; Communications; Recreation and Culture; Education; Hotels, Cafes and Restaurant; and 
Miscellaneous Goods and Services.
7 We used the open source GeoDa software (Anselin & Li, 2019) to implement this analysis.
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Population and Environment (2022) 44:46–76 61
resulting bivariate cluster map shows the spatial correlation between water inequal-
ity and income status.
Interpretation of this analysis is based on the idea that households in commu-
nities with different levels of wealth use different strategies to access improved 
water. Just because a household is in an affluent neighborhood does not mean that 
they have access to improved water; thus, the entropy index becomes a signal that 
households face barriers to accessing improved water beyond limited household 
budgets constraining consumption choices. Communities with high variability near 
areas of concentrated affluence indicate that households must employ a variety of 
strategies to obtain water and it is a signal that the water landscape is not as safe as 
it should be in GAMA. On the other hand, wealthy communities with low variabil-
ity may indicate that these areas have consistent and improved water sources since 
households that can afford them are not actively relying on alternative strategies to 
obtain water.
By the same token, poor communities will have less ability to make room in their 
household budgets to obtain improved water and are likely to have fewer options. 
Poorer communities with high variability may suggest that these communities have 
physical access to multiple sources, but some households cannot afford improved 
water and must employ alternative strategies. Poorer neighborhoods with little vari-
ability could signal that there are no alternatives to poor quality water, or that the 
community has access to improved drinking water and has no need to look else-
where. Thus, we use the BiLISA clusters to identify communities that face barriers 
to accessing improved water.
Results
Geographical variations/distribution in drinking water sources in GAMA
Generally, the most prevalent drinking water source among all the diverse sources of 
water is the piped water sources (i.e., pipe-borne inside dwelling (28.2%), pipe-borne 
outside dwelling (27.2%), and public tap/stand pipe (8.8%)) and this accounted for 
64.2% out of the 980,127 households in GAMA. This was followed by the 28.9% of 
sachet water prevalence (see Tables 1 and 3). On the other hand, tanker supply/vendor 
provided, borehole/pump/tube well, and bottled water sources constituted 2.8%, 1.5%, 
and 1.1% respectively. However, eight different drinking water sources were all less 
than 1%. They include protected well (0.9%), rain water (0.2%), protected spring (0.3%), 
unprotected well (0.1%), unprotected spring (0.02%), river/stream (0.2%), dam/pond/
lake/dugout/canal (0.1%), and other (0.1%). In effect, the unprotected spring was the 
least accessed drinking water source in all of the GAMA region. In terms of improved 
sources of drinking water, over 99% (n = 974,724) of households accessed an improved 
source of drinking water in this metropolitan region (see also Tables 1 and 3).
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 62 Population and Environment (2022) 44:46–76
Diversity of drinking water sources in GAMA
Figure 3 shows the Shannon entropy values of all the EAs within GAMA (n = 5019). 
This measure indicates the diversity of the various drinking water sources at the EA 
level across this urban agglomeration. This diversity helps us to understand the different 
choices households make in accessing multiple drinking water sources. The analysis 
reveals that 55 EAs within GAMA recorded a value of zero (i.e., EAs highlighted in 
red) meaning that these EAs had no diversity and only accessed a particular type of 
drinking water source. These no diversity EAs mostly utilized improved water sources 
(96.4%) with 58% of those sources being pipe-borne inside the dwelling and this can 
found mainly in the AMA and TMA. Other EAs that consume only sachet water and 
borehole/pump/tube well sources are seen mainly in the Adentan and Ga South Munici-
palities, respectively. The remaining 3.6% of the no diversity EAs utilized only unpro-
tected well. The highlighted EAs are included in the 10th percentile, demarcating a 
group of EAs that have the lowest diversity (n = 502). On the other hand, fewer EAs 
(n = 50) registered the most diversity (i.e., > 99th percentile). Households in these fewer 
EAs are observed to have depended on any of the 15 drinking water sources.
However, the majority of EAs show middling levels of diversity (n = 4467) 
accessing mostly the improved sources of drinking water (see Fig.  3). Thus, the 
entropy analysis shows that most places in GAMA fall somewhere in the middle of 
the distribution.
Fig. 3  Diversity of the various drinking water sources at the EA level
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Population and Environment (2022) 44:46–76 63
Neighborhood wealth and drinking water sources
Figure 4 shows the wealth indices of the EAs across the various districts of GAMA 
based on the Index of Concentration at the Extremes. These indices describe economic 
segregation in GAMA. Several wealthy neighborhoods can be found in the Accra 
Metropolitan Area, La Dade-Kotopon Municipal Area, Tema Metropolitan Area, La 
Nkwantanang-Madina Municipal Area, and the Ga East Municipal Area. Poorer areas 
can be seen more in districts such as the Ga South Municipal and Ga West Municipal 
Areas. Although the majority of EAs in GAMA fall under the middle-income bracket, 
the wealth map largely shows significant differences among the various districts.
Furthermore, we examined how the diversity of the water landscape is affected by 
socio-economic status, so we correlated the entropy index with the ICE to identify the 
areas of GAMA that are marked by concentrated affluence and concentrated poverty. 
Figure 5 presents the results from the cluster detection analysis from the diversity of 
various drinking water sources against low- and high-income residential areas, show-
ing the spatial association between diverse drinking water sources and wealth status. 
This figure shows a situation where clusters of high diversity in drinking water sources 
in high-income residential areas are mainly found in the Accra and Tema Metropolises 
along with La Dade-Kotopon and Ga East Municipalities. High-high clusters can also 
be observed within the Ledzokuku-Krowor Municipality as well as the lower parts 
of La Nkwantanang-Madina Municipality close to the Accra Metropolis boundary. It 
is also important to note that the abovementioned districts which are more urbanized 
Fig. 4  Neighborhood wealth status
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 64 Population and Environment (2022) 44:46–76
Fig. 5  Diversity in drinking water sources versus income status
also exhibited low–high clusters meaning that there are also high-income residential 
areas with low diversity in access to drinking water sources (Fig. 5).
The above scenario is contrasted with low diversity in low-income areas which 
can clearly be seen in the industrial zones between the Tema Metropolis and the 
Kpone Katamanso District. These are also observed in some significant sections of 
the Ga West, Ga Central, and Ga South Municipalities. On the other hand, high-
low clusters represent high diversity in drinking water sources in low-income areas 
and can be visibly seen in the large portions of the Ga West, Ga Central, and Ga 
South Municipalities alongside isolated sections of the Kpone Katamanso District 
which are all largely within the peri-urban areas of GAMA.
We were also interested in the most common types of drinking water against the 
backdrop of entropy and wealth status (Table 3). From Table 3, the residents of high 
diversity drinking water sources in high-income areas mostly consume sachet water 
(32.6%), pipe-borne inside dwelling (27.2%), pipe-borne outside dwelling (25.7%), 
public tap/stand pipe (9.3%), and then bottled water (2.1%). Also, the high diver-
sity in low-income areas patronized sachet water (32.7%), pipe-borne outside dwell-
ing (27.0%), pipe-borne inside dwelling (16.2%), public tap/standpipe (10.0%),and 
tanker services (4.8%) as their most common types of drinking water. For the low 
diversity in low-income neighborhoods, the most common drinking water sources 
were the pipe-borne outside dwelling (38.5%), sachet water (21.1%), pipe-borne 
inside dwelling (18.9%), public tap/standpipe (10.5%), and the tanker services 
(5.3%). In contrast, the low diversity in high-income areas commonly consume 
from the pipe-borne inside dwelling (44.9%), sachet water (24.6%), pipe-borne out-
side dwelling (23.5%), public tap/stand pipe (4.0%), and tanker services (1.5%). 
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Population and Environment (2022) 44:46–76 65
Table 3  Entropy/wealth status and most common drinking water types (in percentages)
Not significant High-high Low-low Low–high High-low GAMA total
Pipe-borne inside dwelling 24.5 27.2 18.9 44.9 16.2 27.2
Pipe-borne outside 29.8 25.7 38.5 23.5 27.0 28.2
dwelling
Public tap/standpipe 10.1 9.3 10.5 4.0 10.0 8.8
Bottled water 0.9 2.1 0.2 0.6 0.9 1.1
Sachet water 29.1 32.6 21.1 24.6 32.7 28.9
Tanker supply/vendor 3.2 1.2 5.3 1.5 4.8 2.8
provided
Borehole/pump/tube well 1.3 0.7 3.1 0.4 4.1 1.5
Protected well 0.4 0.4 0.6 0.1 1.3 0.5
Rain water 0.1 0.1 0.2 0.0 0.6 0.2
Protected spring 0.3 0.4 0.3 0.3 0.4 0.3
Unprotected well 0.0 0.1 0.3 0.0 0.3 0.1
Unprotected spring 0.0 0.0 0.1 0.0 0.1 0.0
River/stream 0.1 0.1 0.5 0.0 1.0 0.2
Dugout/pond/lake/dam/ 0.0 0.0 0.3 0.0 0.5 0.1
canal
Other (specify) 0.1 0.2 0.0 0.1 0.1 0.1
Irrespective of residents’ socio-economic status, sachet water usage is largely associ-
ated with areas of highly diverse drinking water sources making it ubiquitous while 
the pipe-borne water can normally be found in areas of low diversity.
Discussion
This study sought to examine spatial heterogeneity in drinking water sources and 
neighborhood income in GAMA. While previous research has explored drinking 
water sources based on sample survey data of selected neighborhoods of GAMA 
(Benneh et al., 1993; Songsore & McGranahan, 1993, 1998; Stoler et al., 2013), to 
the best of our knowledge, ours is the first to analyze drinking water sources based 
on census mapping at the enumeration area level. One important advantage of a cen-
sus is its comprehensive coverage which enables the researcher to analyze data at 
localized settings. The study adds to the growing body of literature notably among 
geographers who have explored inequality using census data at different spatial 
scales to study environmental and demographic issues (Arku et al., 2016; Cutter & 
Finch, 2008; Weeks et al., 2010).
Using the Shannon entropy index and the index of concentration at the extremes, 
we have showed considerable spatial diversity and accompanying inequalities in 
drinking water sources not evidenced in previous studies. There is evidence of high 
socio-economic areas with high diversity in drinking water sources as well as areas 
of high socio-economic status with low diversity in drinking water sources. Like-
wise, we also find areas of low socio-economic status with high diversity in drinking 
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 66 Population and Environment (2022) 44:46–76
water as well as areas of low socio-economic status with low diversity in drinking 
water sources.
By complementing the entropy/wealth measure with the most common types of 
water used, we have been able to provide evidence of how the meaning of heterogene-
ity in water sources differ in wealthy and poor EAs (see Table 3). Thus, heterogene-
ity in drinking water sources in GAMA is good as evidenced by the dominance of 
piped water sources which are at the top of the JMP ladder and are publicly managed, 
improved, and affordable. In addition, it can be argued that a significant proportion 
of the population also depend on vendor sources especially sachet water which sug-
gests a heavier burden in terms of costs placed on consumers. Thus, Table 3 provides 
compelling evidence that there are different strategies within each BiLISA category 
for accessing drinking water in GAMA and thus heterogeneity is neither good nor bad.
Given the segregated nature of Accra’s neighborhoods based on socio-economic 
status (Agyei-Mensah & Owusu, 2010), both the rich and the poor adopt multiple 
strategies in looking for drinking water. For the urban poor who may not have regu-
lar access or connection to pipe borne water, the alternatives available are sachet 
water, bottled water, water tankers, and in some instances unprotected well and 
rainwater. For the rich, many of whom may have access to pipe borne water inside 
dwelling; the use of multiple sources such as sachet water and bottled water may 
reflect the perception of water quality and irregular flow of pipe borne water as well 
as water rationing. Perceived and actual quality of water from Ghana’s piped system 
is highly variable as noted by Morinville (2017). Unfortunately, census data does not 
provide questions on water quality. The use of sachet water among many residents of 
GAMA (see Table 2 and Fig. 3) reinforces Moulds et al. (2022) assertion that sachet 
water has become ubiquitous in urban Ghana.
With regard to the factors driving these patterns, our results suggest multiple fac-
tors related to challenges with the municipal water delivery system and govern-
ance, wealth differences, population growth and urban expansion, and the colonial 
and post-colonial imprint on the urban landscape. The impact of these factors varies 
significantly based on geographical location. The Accra Metropolitan Area (AMA) 
is the oldest settlement among the administrative districts of GAMA, and home to 
the Gas—the indigenous settlers of Accra. Most residents here depend on multiple 
water sources such as pipe borne water followed by sachet water with some seg-
ments of the population depending on bottled water and water tankers. Note that 
most of the water sources here are improved water sources going by JMP ladder. 
The drivers of water consumption pattern at AMA can be traced to the colonial and 
post-colonial era. As noted in the literature on colonial urbanization, Accra’s spatial 
structure was heavily influenced by the colonialists (Agyei-Mensah & Owusu, 2010; 
Andersson, 2017; Bohman, 2012; Brand, 1972; Harris, 2021; Songsore et al., 2009). 
Areas such as Airport Residential Area, Ridges, and Cantonments were provided 
with well laid out infrastructure in terms of the provision of water services. This has 
continued into the post-colonial era with the residential facilities being provided for 
top African civil and public servants and the diplomatic community.
The use of multiple water sources in the indigenous Ga areas such as Jamestown, 
Ussher Town, Chorkor and Teshie can be traced to the legacies of uneven infrastruc-
ture development during the colonial period, intermittent water flows and rationing 
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Population and Environment (2022) 44:46–76 67
as well as payment of water bills (see Adams & Vásquez, 2019; Brand, 1972; Harris, 
2021; Sualihu et al., 2017). Population growth and urban expansion driven largely 
by migration has also pushed migrants who come into the city into slums or informal 
settlements (such as Nima, Maamobi and Sabon Zongo) and peri urban areas such 
as Abokobi, Amasaman, and Kpone with limited supply of pipe-borne water ser-
vices. EAs in these low-income areas depend on multiple sources of water outside 
the main formal system. Even where there are water connections, the taps do not 
flow regularly due to the rationing system as well as lack of maintenance and aging 
water pipes and lines (Dapaah & Harris, 2017; Harris, 2021). As a result, they resort 
to other multiple sources such sachet water as well as tanker water sources. In addi-
tion, it is important to note that the La Dade-Kotopon Municipal Area (LaDMA) as 
well as the Ledzokuku-Krowor Municipal Area (LeKMA) share very similar char-
acteristics since they were recently carved out of the AMA (see Table 2).
Compared to AMA, the situation in the Tema Metropolitan Area (TMA) looks 
different. Here, most of the population depend on piped water sources. In addition, 
segments of the population also consume sachet and bottled drinking water. 
As noted earlier, the case of Tema Metropolis can be traced to investments in the 
provision of water infrastructure that accompanied the development of TMA as a 
planned industrial city by the state after independence in 1957 (Kirchherr, 1968; 
Songsore et  al., 2009). These developments were driven by the establishment of 
the Tema Development Corporation and subsequently the growth of private estate 
developers that led to the expansion of the traditional core residential communities 
(communities 1–12) to the current 25 communities. It is noteworthy that all these 
communities obtain their water through the Ghana Water Company Limited. TMA’s 
situation has largely been driven by planning before development and its ability to 
control population growth and urban expansion by the provision of planned residen-
tial communities. The use of sachet and bottle water by segments of the population 
may reflect on some of the challenges in the piped borne supply system relating to 
rationing and intermittent flows (Asante-Wusu & Yeboah, 2020) as well as the qual-
ity of water coming from the taps.
A different pattern emerges in the Adentan Municipality where residents depend 
largely on sachet water, followed by pipe borne, tankers, and bottled water. Compared 
with AMA and TMA, this area is relatively new with most development occurring after 
the 1980s. Many housing developments in the Adentan area were constructed without 
formal planning in terms of the provision of water infrastructure as well as electricity 
and tarred roads, and most settlements extend beyond the limits of the two main water 
delivery systems. The use of vendor water sources such as sachet water and tanker ser-
vices for drinking in many households in the Adentan Municipality reflects in part the 
unavailability of piped borne water systems in some homes and where they exist the 
intermittent flow/rationing (Alba et  al., 2019; Bartels et  al., 2018; Dapaah & Harris, 
2017; Tutu & Stoler, 2016). Thus, most households resort to sachet water, bottled water, 
and tanker services. Population growth and lack of access to land in AMA have pushed 
many people to the outskirts including Adentan Municipality. In most cases, residen-
tial facilities have been put up without the provision of water systems. Thus, this situa-
tion reflects largely the unavailability of pipe-borne water systems creating a demand for 
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 68 Population and Environment (2022) 44:46–76
sachet water and tanker service deliveries. Thus, unlike TMA, it reflects a development 
before planning approach.
Unlike AMA, LaDMA, LeKMA, TMA, and the Adentan Municipality described 
above, the Ga District, namely the Ga East, Ga West, Ga Central, and Ga South Munic-
ipalities as well as the La Nkwantanang-Madina Municipality, depend on multiple 
water sources. Sachet water is the dominant water use except for the Ga South which 
depends largely on piped borne water probably due to its closeness to the Weija Treat-
ment Plant. Other water sources here are piped water, tankers, bottled water, and some 
unimproved sources. Two major factors are driving water consumption here: popula-
tion growth and unavailability of water infrastructure. For example, the Ga District 
recorded the highest population growth rate of nearly 60 percent per annum between 
1960 and 2010 among the 12 districts of GAMA (Fig. 2). Most of this increase is due 
to lack of land in Accra and the movement of the population to the outskirts of the main 
city (Yankson & Bertrand, 2012). These movements to the outskirts are usually not 
accompanied by expansion in water infrastructure. Thus, there is a disconnect between 
population increase and water infrastructure in the Ga District (see also Mosello, 2017) 
as well as the other districts.
Our study has some limitations to consider for future work. The census data used 
here is the most recently available one for Ghana but still a decade old, with a 2021 
census currently being processed (delayed from 2020 due to the Covid-19 pandemic). 
Nevertheless, our study provides a valuable baseline against which to evaluate the data 
from this census, to identify key temporal trends, and use as benchmarks to measure the 
success of policies towards universal access. It should also be noted that our focus was 
on drinking water sources at the enumeration and household levels. As such, people’s 
water sources at work and school were not captured here as they are not represented in 
the census.
The analysis was also based essentially on census data and did not involve interviews 
of households. Thus, actual water users were not interviewed. With respect to water 
quality, some studies such as one by Sunkari and Danladi (2016) in the Accra Metropo-
lis on bottled drinking water indicate that the trace elements pose no risks as they are 
below the WHO and the Ghana Standard Authority’s guidelines. Another study in the 
Ga West Municipality on borehole water also showed that the physico-chemical prop-
erties for drinking water are within the required limits of the WHO except for total 
dissolved solids (TDS), total hardness, sodium  (Na+), and chlorine  (Cl−) which could 
be as a result of solid waste leachate and marine water intrusion (Sunkari et al., 2019).
Despite these limitations, the study provides a comprehensive portrait of the dif-
ferent drinking water sources in localized setting as well as the drivers of water 
consumption.
Conclusions
In this article, we have examined the spatial heterogeneity in drinking water 
sources within the neighborhoods of GAMA, and how they differ by neighbor-
hood wealth status. Prior literature on this subject in GAMA have mostly uti-
lized sample survey data. Our analysis relies on census data that provides a 
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Population and Environment (2022) 44:46–76 69
comprehensive coverage of sources of drinking water at the enumeration area 
level. Based on the Shannon entropy index and the ICE, we have shown consider-
able spatial heterogeneity and inequality in drinking water sources not evidenced 
in previous studies. By complementing the entropy/wealth status with the most 
common water sources, we conclude that heterogeneity is neither good nor bad 
judging by the dominance of both piped water sources and vendor sources such as 
sachet water.
The drivers of these heterogeneities are also not uniform and relate to a discon-
nect between population/urban territory growth and the provision of pipe borne 
water infrastructure.  Other factors relate to the segregated nature of the urban 
colonial and post-colonial structure, and challenges faced by municipal authori-
ties in their quest to provide adequate water services to the population. Poverty 
and wealth also shape the choices people make with respect to sources of drink-
ing water. Of course, there are also issues with the quality of pipe borne water, 
intermittent flow, rationing, and maintenance.
Taken together, our results suggest that GAMA’s water system is not oriented 
towards equity and that most residents adopt multiple strategies in their quest for 
household drinking water. It is also clear that some of housing developments in 
GAMA such as parts of the Ga District were not preceded by formal planning in 
terms of the provision of water infrastructure. This contrasts sharply with TMA 
which was a planned industrial city with provision for water infrastructure. For 
policy purposes, it is important that policy makers especially officials of GAMA, 
GWCL, and other agencies in water resources and infrastructure planning, or 
other anti-poverty initiatives in GAMA, recognize and understand the dramatic 
spatial heterogeneity of drinking water sources in GAMA. This is important 
because it is an indicator of profound inequality, and since water access is widely 
recognized policy priority per the SDG—Goal 6 and vital for improving popula-
tion health and well-being. Thus, interventions should focus on providing piped 
water sources in areas not covered with water supply as these sources are more 
affordable, safely managed, and high on the JMP ladder.
Data access and availability
Enumeration area level data with their respective household drinking water sources 
are provided as supporting information at http:// equita blehe alth yciti es. org/d ata- 
downl oad/. Individual level data and shapefiles may be requested from Ghana Statis-
tical Service or at https:// statsg hana.g ov.g h/ gssdat adow nload spage. php.
Acknowledgements For the purpose of Open Access, the author has applied a CC BY public copyright 
licence to any Author Accepted Manuscript version arising from this submission.
Funding This work is supported by the Pathways to Equitable Healthy Cities grant from the Wellcome 
Trust (209376/Z/17/Z).
1 3
 70 Population and Environment (2022) 44:46–76
Declarations 
Conflict of interest The authors declare no competing interests.
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, 
which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long 
as you give appropriate credit to the original author(s) and the source, provide a link to the Creative 
Commons licence, and indicate if changes were made. The images or other third party material in this 
article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line 
to the material. If material is not included in the article’s Creative Commons licence and your intended 
use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permis-
sion directly from the copyright holder. To view a copy of this licence, visit http:// creat iveco mmons. org/ 
licen ses/ by/4. 0/.
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Authors and Affiliations
Jacob Doku Tetteh1 · Michael R. Templeton2 · Alicia Cavanaugh3 · 
Honor Bixby4 · George Owusu5 · Sandow Mark Yidana6 · Simon Moulds2 · 
Brian Robinson3 · Jill Baumgartner4 · Samuel Kobina Annim7 · 
Rosalind Quartey7 · Samilia E. Mintah7 · Ayaga Agula Bawah8 · Raphael E. Arku9 · 
Majid Ezzati8,10 · Samuel Agyei‑Mensah1 
1 Department of Geography and Resource Development, University of Ghana, P.O. Box LG 59, 
Legon-Accra, Ghana
2 Department of Civil and Environmental Engineering, Imperial College London, London, UK
3 Department of Geography, McGill University, Montreal, Canada
4 Department of Epidemiology, Biostatistics and Occupational Health, McGill University, 
Montreal, Canada
5 Institute of Statistical Social and Economic Research, University of Ghana, Accra, Ghana
6 Department of Earth Science, University of Ghana, Accra, Ghana
7 Ghana Statistical Service, Accra, Ghana
8 Regional Institute for Population Studies, University of Ghana, Accra, Ghana
9 Department of Environmental Health Sciences, University of Massachusetts Amherst, Amherst, 
USA
10 MRC Centre for Environment and Health, School of Public Health, Imperial College London, 
London, UK
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