Abstract
Flood events in West Africa have devastating impacts on the lives of people. Additionally, developments such as climate change, settlement expansion into flood-prone areas, and modification of rivers are expected to increase flood risk in the future. Policy documents have issued calls for conducting local risk assessments and understanding disaster risk in diverse aspects, leading to an increase in such research. Similarly, in a shift from flood protection to flood risk management, the consideration of various dimensions of flood risk, the necessity of addressing flood risk through an integrated strategy containing structural and non-structural measures, and the presence of residual risk are critical perspectives raised. However, the notion of “residual risk” remains yet to be taken up in flood risk management-related academic literature. This systematic review seeks to approach the notion of residual risk by reviewing information on flood impacts, common measures, and recommendations in academic literature. The review reveals various dimensions of impacts from residual flood risk aside from material damage, in particular, health impacts and economic losses. Infrastructural measures were a dominant category of measures before and after flood events and in recommendations, despite their shortcomings. Also, spatial planning interventions, a more participatory and inclusive governance approach, including local knowledge, sensitisation, and early warning systems, were deemed critical. In the absence of widespread access to insurance schemes, support from social networks after flood events emerged as the most frequent measure. This finding calls for in-depth assessments of those networks and research on potential complementary formal risk transfer mechanisms.
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Introduction
Flood events in West Africa have inflicted devastating impacts on the lives of its inhabitants (Badou et al. 2019). Region-wide flood events, such as in 2007 (UN OCHA 2007), 2009 (UN OCHA 2009), 2010 (UN OCHA 2010), 2012 (UN OCHA 2012), 2016 (UN OCHA 2016), or most recently in 2020 (ERCC 2020), illustrate they are reoccurring more frequently, and with high severity in many places, causing large-scale loss and damage. The Emergency Events Database (EM-Dat), which records essential disaster data on a global scale, identifies 249 large-scale flood events (> 10 fatalities or 100 affected people), which caused approximately 3800 deaths and affecting about 25 million people from 1991 to 2019 in the Economic Community of West African States (ECOWAS) (EM-Dat 2020). ECOWAS member states include Benin, Burkina Faso, Ivory Coast, The Gambia, Ghana, Guinea, Guinea-Bissau, Liberia, Mali, Niger, Nigeria, Senegal, Sierra Leone, Cape Verde, and Togo (ECOWAS 2020). Furthermore, despite uncertainties in several precipitation indices (Dosio et al. 2019), Global Climate Models (GCMs) and Regional Climate Models (RCMs) indicate shorter, more intense, and later rainy seasons for West Africa due to climate change (Vizy and Cook 2012; Dunning and Black 2018; Dosio et al. 2019). This trend is expected to lead to an increase in harmful flood and drought events in the region (Akinsanola and Zhou 2019). Moreover, human activity, such as dam construction, alters natural river regimes (Mahe et al. 2013), whilst intensive urban expansion is projected to continue in flood exposed areas such as the Niger river and low-elevation coastal zones (LECZ) along the Gulf of Guinea up to 2030 (Güneralp et al. 2015).
In research as well as policy-making, there has been a growing awareness for the need to shift from a flood protection paradigm to flood risk management (FRM) (Hartmann and Albrecht 2014; Evers et al. 2016; Thomas and Knüppe 2016; Roos et al. 2017). Whilst in the conventional flood protection paradigm, floods are usually addressed in a top-down manner by centrally implemented structural measures; an FRM approach calls for an integrated and synergetic combination of structural and non-structural measures implemented by various actors in a polycentral and participatory manner (Grabs et al. 2007; WMO 2009; Sayers et al. 2013; Challies et al. 2016; Milman et al. 2018). Contrary to conventional flood protection approaches, FRM also led to the perspective that flood risk can seldomly be reduced entirely, thus requiring strategies to address the residual risk that remains unaddressed despite risk-reducing measures being in place or their potential failure (Plate 2002; Ludy and Kondolf 2012; Arrighi et al. 2018). Similarly, according to current perspectives in the field of Disaster Risk Reduction (DRR), residual risk is termed as “the disaster risk that remains in unmanaged form, even when effective disaster risk reduction measures are in place, and for which emergency response and recovery capacities must be maintained” (UNDRR 2020a, online). Therefore, “the presence of residual risk implies a continuing need to develop and support effective capacities for emergency services, preparedness, response and recovery, together with socioeconomic policies such as safety nets and risk transfer mechanisms, as part of a holistic approach” (UNDRR 2020a, online).
In addition, FRM seeks an expansion of risk dimensions to encompass not only the possibility of material damage but also health impacts, economic damages, the destruction of cultural heritage or impaired livelihood opportunities, and ensuing poverty (EU 2007; WMO 2009). The need for a broader and more thorough understanding of disaster risk as a basis for achieving DRR has also been underscored in the realm of policy. For example, in 1989, the United Nations proclaimed the decade of 1990–2000 as the “International Decade for Natural Disaster Reduction” to enhance international cooperation on the topic (UN 1989). Moreover, the Hyogo Framework for Action 2005–2015 (HFA) already called for local risk assessments and to effectively integrate disaster risk considerations into policies, planning, and programming (UN 2005). Also, with its first priority, the ensuing Sendai Framework for Disaster Risk Reduction 2015–2030 (SFDRR) emphasises the importance of understanding disaster risk in all its dimensions (such as vulnerability, capacity, exposure, and hazard) as well as their interconnected impacts to inform disaster risk management meaningfully (UN 2015). Those developments have led to an increased number of publications discussing local flood impacts and efforts of FRM within the academic literature, also for the West African region. However, those publications are mainly case studies and thus primarily provide context-specific information on a local level.
Previous review studies on academic literature relating to FRM in West Africa have not yet summarised works for the entire region with a systematic review approach. On the regional scale, work focussing on such literature includes a review of gaps and challenges of FRM that has been carried out in four selected coastal West African cities (Ouikotan et al. 2017). However, besides considering a limited number of coastal cities, it did not apply a systematic review approach. Similarly, Badou et al. (2019) have carried out a literature review that summarised flood statistics, triggers of floods, solutions for prevention and mitigation of flood effects as mentioned by research, and future research priorities. Even though it is based on academic case studies, it does not offer a systematic approach to the research synthesis. Moreover, FRM-related review studies in the West African region have often focussed on one country or city. Also, they are either occupied with Nigeria or Ghana. On the one hand, for Nigeria, there are reviews on the impact of floods on Nigeria’s achievement of the sustainable development goals (Echendu 2020), on sustainable FRM-practices in flood-prone areas of Nigeria (Cirella and Iyalomhe 2018), on the challenges and opportunities of FRM in Nigeria (Oladokun and Proverbs 2016), and on the National Disaster Management Framework of Nigeria (Olanrewaju et al. 2019). For the city of Lagos in Nigeria, review papers examined the FRM practices of public and private actors (Adelekan 2016) and factors relating to the flood hazard, exposure and vulnerability, and challenges to reducing them (Nkwunonwo et al. 2016). On the other hand, for Ghana, there are reviews on current flood risk management practices as well as gaps and opportunities for improving resilience (Almoradie et al. 2020) and on emerging trends in FRM in the country (Ahadzie and Proverbs 2011). Of those reviews, only a few followed a systematic review approach. Furthermore, none of them explicitly considered the aspect of residual risk and how its resulting impacts are addressed. Therefore, applying such a review approach to all West African countries will enable a broader discussion of trends in FRM at the regional level.
The aim of this review is to better understand the role of residual risk in FRM-related research for the region of West Africa. To achieve this, the article provides a systematic review of academic literature (journal articles and book chapters) and the contextual information it provides for FRM-related aspects in the region of West Africa. The analytical approach of this paper and its research questions to collect data on FRM measures and residual risk is summarised in Fig. 1, drawing upon the perspectives of FRM and DRR mentioned above. This review’s approach is to use the onset of the most recent flood event contained within the case study as a point of reference, to determine whether risk remained unmanaged or not. Thus, this review first analyses those FRM measures that have been applied before the onset of the most recent flood event, as reported in the case study. Second, the analysis focusses on the observed flood impacts as evidence-based indications of residual flood risk that materialised despite previous risk-reducing measures being implemented. Third, measures that have been applied after the onset of the most recent flood event to deal with the impacts of residual flood risk are analysed. Finally, recommendations produced as part of research to further address residual flood risk will be summarised in this review.
Analytical approach of the review paper and visualisation of research questions
Method
In environmental sciences, systematic reviews are increasingly carried out in research relating to climate change adaptation (Berrang-Ford et al. 2011; Ford et al. 2014, 2016; Lesnikowski et al. 2015; Epule et al. 2017; Biesbroek et al. 2018; Shaffril et al. 2018; Owen 2020), drought risk (Kamara et al. 2018; Hagenlocher et al. 2019), and to FRM (Wellens et al. 2013; Abbas et al. 2016; Nordbeck et al. 2019; Carrick et al. 2019) due to their ability to provide a comprehensive summary of existing trends and foci in academic and/or grey literature. However, the variation in methodological approaches and the varying levels of transparency have been pointed out and were met with a set of proposed components by Berrang-Ford et al. (2015) for the standardisation of such research concerning the research questions/aim, data source, and document selection, and analysis and presentation of results. This study is seeking to address each of those aspects as a guide for enhanced transparency in this review paper. Furthermore, the article draws upon guidance from Siddaway et al. (2019) and Mengist et al. (2020) on the procedure of carrying out this systematic review, which is outlined in the section. Also, the article illustrates the review process in the form of a flow chart (Fig. 2) as recommended by the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement, which formulates a minimum set of items for reporting the review procedure (Page et al. 2021).
adapted from Page et al. 2021)
Flow chart of review procedure (
Documents that were written in either English or French were searched for using sets of relevant English and French search terms (Annex 1). The keywords were selected in those languages since they are the most prevalent official languages in the ECOWAS region (with the exception of Guinea-Bissau and Cape Verde). Research areas in selected documents were mapped to illustrate a potential reporting bias in the geographical representation of West African countries in the final data set. Research published from 1991 onward up to 2019 was selected because the earliest large-scale flood event within the UN’s “International Decade for Natural Disaster Reduction” (1990–2000) in ECOWAS states listed on the EM-Dat database occurred in 1991 (EM-Dat 2020). The final set of search terms was selected in an iterative process by seeking additional keywords identified in relevant articles that were in previously identified documents. The saturation point was deemed to be reached when several newly added search terms were only adding a small single-digit number to the number of articles obtained by the query. The final set of terms was searched on 29th July 2020.
As outlined in Fig. 2, relevant literature was searched for in Web of Knowledge and Scopus because they are the most extensive databases for peer-reviewed research. Additionally, African Journals Online (AJOL) was included as a database because it contained additional relevant research from local research institutions that mainly were not listed in the other two databases. However, the authors are aware that additional relevant research might be published in other databases as those considered for this review. After the initial search yielded 2934 documents, 885 duplicates were removed, which resulted in a list of 2049 unique documents. Original research articles, in the form of peer-reviewed articles and book chapters containing primary data from field-based research, were selected as document types for this review. The explicit explanation of the primary data collection process was taken as a quality criterion for the inclusion of a document into the review.
The retrieved documents were screened in three rounds of review. The first round of screening was done by the primary author, who assessed the title, abstract, and keywords of each article, indicating their relevance by stating “yes”, “no”, or “perhaps”. Similarly, in the second round of screening, the entire list of articles was assessed independently by a team of eight reviewers to minimise personal selection bias, of which each member received a share of the entire set of articles. The team of reviewers then also indicated the relevance of each article by stating “yes”, “no”, or “perhaps”, without seeing the results of the first round of screening. The purpose of the third review round was to arbitrate judgments in case the first and the second rounds of review differed in their judgment, or if both parties submitted “perhaps”. The final reviewer indicated “yes” or “no” to make the final judgment based on the title, abstract keywords, and the full article if necessary. All reviewers assessed the relevance of articles based on the same inclusion and exclusion criteria (Fig. 2). Documents were included if they unambiguously focussed on floods but excluded if they combined information about flood impacts or FRM measures with other hazards or with climate change in an inseparable way. Also, studies were excluded that focussed merely on assessing the physical flood hazard but provided no information on the research questions. Contrarily, those that contained information on impacts and responses (flood impacts from FRM measures before and after the most recent flood event or recommended measures to reduce residual flood risk further) were included. Finally, only research that contained primary data and that was carried out in the selected West African countries of interest was included. Selected West African countries are the member states of ECOWAS, namely Benin, Togo, Senegal, The Gambia, Guinea, Guinea-Bissau, Mali, Ivory Coast, Sierra Leone, Burkina Faso, Niger, Nigeria, Ghana, Liberia, and Cape Verde. Research that was purely based on secondary data or carried out outside of the countries of interest was excluded.
The process of screening by the reviewers led to a selection of 201 documents, which were read in their entirety to decide about their eligibility. The coding of information relating to the research questions was done by three reviewers, including the main author, using the software MAXQDA 2020. The reviewer team chose the software because of being able to easily exchange and merge project documents and its easy-to-operate user interface for coding text (VERBI 2021). Also, Excel sheets summarising each code can be exported and used to visualise and analyse the data as done for this review. To minimise bias in coding articles and deciding on their eligibility, the main author and the two other reviewers went through all 201 documents twice. If an impact or measure was mentioned to occur, or to be carried out, in a document, it was captured through open coding in MAXQDA. In this process, categories for impacts and measures emerged through continuously grouping and regrouping the results (Table 1). The information on impacts and measures are summarised by using descriptive statistics in this review. In addition, the working definitions for the categories of impacts and measures, as well as a comprehensive overview of the composition of each category of measures, can be found in Annex 8, 9, 10, and 11. Coded measures and impacts are counted once per document if they appear in the case study. This approach was chosen because the main research aim is to showcase the range of the composition of applied or recommended measures in FRM and the dimension of impacts in the case studies. It should also be made clear that one single document can have research areas in multiple countries. By reading the documents in their entirety during the coding process, 138 were finally included (Annex 2) and considered to be relevant for this review, also based on whether each document met the inclusion and exclusion criteria whilst being read in full-length (Fig. 2). In this process, 32 documents were excluded for not focussing on floods clearly enough, 16 for not providing enough information on FRM measures or flood impacts, 14 for not containing primary data, and 1 for not being published yet.
Results
Meta-information
The review analysis showed that the number of FRM-related articles has steadily increased from 2011 onward (Annex 3) and that the majority of selected articles mentioned Nigeria and Ghana as research areas (Annex 4). Those countries are followed by Senegal, Benin, Niger, Burkina Faso, Togo, and Ivory Coast. Furthermore Cape Verde, The Gambia, Sierra Leone, Mali, and Guinea-Bissau are countries that only featured once or twice in the selected articles. It is worth noting that the final set of selected articles did not represent Guinea and Liberia. Since most articles focussed on Nigeria and Ghana and urban or peri-urban areas (Annex 5), a bias towards those geographical areas must be considered in the results obtained. Furthermore, the geographic distribution of research areas was mapped (see Fig. 3). The map illustrates that, according to the Köppen-Geiger classification from 1980–2016 (Beck et al. 2018), the research area spans nine different climatic zones, of which the following five cover the majority of this area: tropical, rainforest (Af); tropical, monsoon (Am); tropical, savannah (Aw); arid, desert, hot (BWh); and arid, steppe, hot (BSh). It became apparent that the eastern part of the region is widely covered by the selected research. In contrast, the western part is barely covered, with the exception of the Senegalese coast, The Gambia and singular studies in Cape Verde, Guinea-Bissau, and Sierra Leone. Flood types that were encountered in the review (Annex 6) were pluvial floods (n = 93), fluvial floods (n = 83), coastal floods (n = 34), and groundwater floods (n = 9). The variety of methods applied in case studies also translates into a varying understanding of concepts that relate to FRM such as risk, vulnerability, adaptation, or coping. Methods for primary data collection (Annex 7) were surveys (n = 97), qualitative interviews (semi-structured, in-depth, and key-informant) (n = 73), focus groups (n = 40), photography/photo-elicitation (n = 13), workshops (n = 11), stakeholder meetings (n = 10), transect walks (n = 6), and collective mapping (n = 4). The following part of the section will summarise the information collected in the review process, based on the four research questions previously stated in chapter 1.
Geographical distribution of research locations in selected documents. The authors excluded publications [73] and [81] (see Annex 3) from the map due to not specifying the research locations sufficiently. One article can contain several research areas, resulting in 746 research locations from 138 selected documents. Admin boundaries retrieved from DIVA GIS (2020) and Köppen-Geiger climate classification data set from Beck et al. (2018)
Which existing risk-reducing measures were mentioned before the onset of the most recent flood event?
The analysis shows that observed FRM measures that were mentioned before the most recent flood event (appearing in 109 out of 138 documents) most often fell into the category of infrastructural measures (Fig. 4a), with drainage construction being the most outstanding among them (Fig. 4b). Also, flood defense structures, elevating of buildings or infrastructure, landfilling, dams/dikes, and dredging of rivers/channelisation were mentioned as infrastructural measures. Following infrastructural measures, a cluster of six categories of risk management measures before the onset of the most recent flood event showed an equal prevalence. This comprises the following categories (Fig. 4a) and measures (Fig. 4b): maintenance activities with measures such as clearing drainage infrastructure; mutual support with measures such as material support from the community and social relations; preparing/providing assistance and response with measures such as raising capacities for response and relief and the establishment of contingency plans; awareness-raising, training, and education with measures such as civic sensitisation to flood risk; policies with measures such as applying public policies to reduce flood risk and a flood control/development master plan; and, finally, relocation with measures such as permanent relocation.
Overview of categories (a) and measures before (b) and after (c) the onset of the most recent flood event as well as (d) recommended measures by FRM-related research (one document can contain several categories and measures)
Which impacts from the most recent flood event were mentioned in selected case studies?
Impacts from residual flood risk were analysed, which arose from the most recent flood event despite FRM measures or in their absence (appearing in 125 out of 138 documents). The results demonstrate that in the selected documents, flood impacts most frequently fall into the category of material damage (Fig. 5a) due to, for example, damaged buildings as the most outstanding impact, damaged possessions, damage to infrastructure, crop damage, loss of livestock, and damage of public facilities (Fig. 5b). However, health impacts (n = 180) also pose a significant risk resulting from a flood event in analysed case studies. They mostly materialise as fatalities, sickness, and spreading of disease, as well as fear/mental health problems. Besides, economic losses (n = 115) are frequent impacts resulting from flood events in analysed case studies. They often took the form of disruption of livelihoods/income loss, and financial damages. Additionally, environmental degradation (n = 74) played an important role in impacts which resulted from the most recent flood event in the selected documents. These impacts often resulted in damaged farming land/land degradation and a polluted environment. Finally, displacement and homelessness, lack of food/drinking water, interruption of social activities, and lack of mobility emerged as dimensions of flood impacts worth considering.
Categories of mentioned flood impacts from residual flood risks (a) and flood impacts (b) (one document can contain several categories and impacts)
Which measures were applied to deal with impacts from residual flood risk after the onset of the most recent flood event?
The following paragraph summarises measures that were applied to deal with impacts from residual flood risk after the onset of the most recent flood event (appearing in 121 out of 138 documents). Similarly to before the onset of the most recent flood event, infrastructural measures were performed most frequently after its onset (Fig. 4a). They often appeared as belated drainage/channel construction or by using sandbags as flood breaks (Fig. 4c). Also, measures of relocation (n = 116) were performed very frequently after the most recent flood event had started. In comparison to before the onset of the flood event, they strongly increased after its onset. These measures unfolded as temporary relocation, permanent relocation, moving/elevating property to a safe place, and migration. Also, measures of mutual support played a highly important role after the onset of the most recent flood event (n = 67). These measures were reported for example as receiving support from the social environment. It is worth noting that this measure was the most frequent after the onset of the most recent flood event. Despite being stated vaguely in many publications, some specified such mutual support activities as providing labour, mental, financial, or material support, borrowing money, and food or shelter to affected family members or friends. Moreover, reported measures focussing on providing/preparing assistance and a response played a crucial role after the onset of the flood event (n = 97). They were performed as governmental assistance, assistance from NGOs/relief organisations, or in general as provision of relief items. Compensations received from insurance companies did not play a significant role.
Which FRM measures were recommended to address residual flood risk?
Finally, measures that were recommended in selected documents to address residual flood risk were identified in 133 out of 138 documents. In contrast to practiced measures before and after the onset of the flood event, measures to adjust policies (n = 150) were most frequently recommended by selected documents to deal with residual flood risk (Fig. 4a). Such adjustments were recommended to better integrate groups at risk into decision-making, active collaboration among stakeholders, policies that alter the resources of people at risk, and policies which directly reduce flood risk (Fig. 4d). Aside from being widely practiced before and after the onset of the most recent flood event, infrastructural measures were again highly recommended (n = 139) for further risk reduction efforts. Other recommended measures comprise, for example, of drainage construction or improvement, dams/dikes, reinforcing buildings, and dredging river channels/channelisation. Additionally, more effort towards measures aimed at awareness-raising, training, and education (n = 119) were recommended by many selected documents. For example, those comprised of further efforts for civic sensitisation to flood risk and teaching of skills to cope with and adapt to floods. Interestingly, despite the fact that not many documents focussed on insurance explicitly in their assessments, it appears as the fifth-most frequently recommended measure.
Discussion
The academic literature analysed in this paper pinpoints the dimensions of impacts that resulted from residual flood risk for the West African region. They comprised most prominently material damage, health impacts, and economic losses, but also environmental degradation, displacement and homelessness, lack of food/drinking water, interruption of social activities, and lack of mobility. It is worth noting that the term “residual risk” was mentioned only once (Adelekan 2016) and not subject to direct analysis in any of the selected documents. Thus, the concept of residual risk has not yet been taken up in selected FRM-related literature. Material damage appeared to be a dominant category of impacts from residual flood risk (Fig. 5a) in selected research according to the analytical approach of this review (Fig. 1). Considering other types of impacts from residual flood risk identified by this review article more extensively will enrich the perspective of FRM. The most prevalent additional dimensions were health impacts and economic losses, which are also currently receiving increased attention due to being the most discussed impacts in the ongoing COVID-19 pandemic (Nicola et al. 2020; Holmes et al. 2020; El Zowalaty and Järhult 2020). This observation gains additional relevance regarding the low level of health care efforts to address flood impacts (Fig. 4a) as well as the high activity to modify livelihoods after the onset of the most recent flood event identified in this review (e.g. Ajibade et al. 2013, Hetcheli 2013, Schaer 2015, Ajaero 2017, Oyerinde et al. 2017, Markantonis et al. 2018, Atidegla et al. 2018, Afriyie et al. 2018; and Fig. 4a). The political momentum in ECOWAS countries for addressing the health and economic impacts of the COVID-19 pandemic (IMF 2020) could help to pursue the possibility of joining efforts in reducing the risk of impacts from both floods and pandemics. In doing so, the consideration of fear and mental health problems arising from either traumatic flood experiences or pandemics should not be neglected. Also, the various dimensions of flood impacts resulting from residual risk underscore the need for research that assesses the causal chains of flood impacts and their mutual influence on each other.
Moreover, the review elaborated that infrastructural measures have been the most observed category of measures in the selected case studies (Fig. 4a). The emphasis on infrastructural measures in FRM-related research is further underscored by a rare explicit application of nature-based solutions, as well as of recommendations for it (Fig. 4a). The tendency for implementing infrastructural measures could be observed before (e.g. Campion and Venzke 2013; Odemerho 2015; Adelekan 2016; Kablan et al. 2019) and after (e.g. Mbow et al. 2008, Schaer and Hanonou 2017, Owusu Twum and Abubakari 2019, Bottazzi et al. 2019) the most recent flood event. Still, infrastructural measures were often recommended in FRM-related research (e.g. Saidu 2009, Adewole et al. 2015, Serpantié et al. 2019; and Fig. 4a). The latter finding could point towards the inadequacies of existing systems, such as open drainage facilities blocked by waste (e.g. Lokonon 2016; Osayomi and Oladosu 2016; Danso and Addo 2017; Schlef et al. 2018) or having to resort to isolated efforts of flood defense structures on the house- or community-level, often in informal areas, with limited impact (Adelekan 2010; Schaer 2015; Bottazzi et al. 2018; Adekola et al. 2019). This was frequently mentioned in urban case studies. Also, the prevalence of recommendations for spatial planning interventions (Fig. 4a) has to be understood in light of the limitations of infrastructural measures. Frequently mentioned measures were, for example, improved land use planning which better considers flood risk (e.g. Wahab and Falola 2017; Tiepolo et al. 2019) or the enforcement of existing land use plans to avoid the new construction of buildings of infrastructure in high-risk areas (e.g. Onu et al. 2013; Ibitoye et al. 2019). However, it seems to remain a difficult task, regarding projections for urban expansion along the Niger river and low-elevation coastal zones (LECZ) along the Gulf of Guinea up to 2030 (Güneralp et al. 2015).
Regarding the polycentral and participatory approach of FRM, there appears to be a strong need for more participatory and inclusive governance to further reduce the impacts of residual flood risk further, given the strong recommendation by the selected documents for policy and law-related measures (Fig. 4a). Those recommendations are often pointed towards better collaboration among stakeholders (e.g. Olokesusi et al. 2015; Ntajal et al. 2017; Young et al. 2019), better integrating groups at risk in relation to decision-making (e.g. Komi et al. 2016; Frick-Trzebitzky and Bruns 2019), and altering their resources (e.g. Olanrewaju et al. 2019, Cirella et al. 2019). This need is also reflected in the current relative disregard of local knowledge and skills in dealing with floods (Fig. 4a). Hence, future research projects should include a focus on how widely present and existing local knowledge and skills could be better integrated into decision-making processes in a meaningful way (e.g. Bonye and Godfred 2011; Biconne 2014; Ajibade and McBean 2014; Ngwese et al. 2018). It has also become apparent in this review that the documents identified civic sensitisation to flood risk as a priority action area for further efforts in flood risk reduction (e.g. Agbola et al. 2012, Adeleye and Ayangbile 2016, Ottah 2017, Abass et al. 2019; and Fig. 4d). Such measures may include early warning systems, as they also appeared as a frequently recommended measure (e.g. Coker et al. 2014, Vissin et al. 2016, Egbinola et al. 2017; and Fig. 4d). The need for this could be further enlarged by expected climatic changes for West Africa, which are projected to lead to shorter yet more intense rainy seasons (Vizy and Cook 2012; Dunning and Black 2018; Akinsanola and Zhou 2019; Dosio et al. 2019).
Remarkably, the most widely practiced measure after the onset of a recent flood event was to seek support from the social environment (Fig. 4c). Whilst some documents did not define the measures more precisely (e.g. Boamah et al. 2015; Enete et al. 2016; Evadzi et al. 2018), others explicitly indicated them as providing labour, mental, financial, or material support, borrowing money, and food or shelter to affected family members or friends (e.g. Adelekan and Fregene 2015; Kielland 2016; Osman et al. 2016; Frick-Trzebitzky 2017; Ajaero et al. 2018). Thus, support from social networks can also aid in explaining the strong prevalence of temporary relocation after the onset of the flood events in case studies (Fig. 4c). Whilst indicating a high level of solidarity, the strong support within social networks also illustrates a lack of widespread access to or compensation by insurance schemes. More research could look into the types of risks shared in such social networks, their limitations, and which form of support aids in the recovery process. It is also worth exploring how efficient and effective those networks function in addressing residual flood risk, if the networks help alleviate inequality and if they are fair on their members. It could be of further interest if those social networks even take on the form of informal risk transfer arrangements, in which support is provided in exchange for social or financial benefits (UNDRR 2020b). This aspect is particularly interesting since many documents recommended insurance for further residual flood risk reduction, despite only a few providing an explicit assessment of its suitability or usage (e.g. Oyekale et al. 2013; Antwi-Boasiako 2016, 2017; Osayomi and Oladosu 2016; Glago 2019). Thus, exploring if insurance can be helpful to address residual flood risk whilst considering the presence of existing informal arrangements appears highly relevant in this research context.
Conclusion
As floods in the West African region have become increasingly frequent and devastating in the past decades, it is essential to give an account of which FRM measures and impacts from residual flood risk are primarily addressed in academic literature. This review found residual risk and its management to be treated implicitly, if at all. An explicit focus is missing in the current FRM-related research carried out in West Africa and will deserve more attention in future. Also, the review identifies that FRM measures frequently comprise of infrastructural measures, maintenance activities, mutual support (in particular seeking support from the social environment), and the preparation/provision of assistance and response measures both before and after the most recent flood event mentioned in case studies. Among those, infrastructural measures emerged as dominant FRM component in this review. Besides, temporary and permanent relocation activities were frequently observed after the onset of the most recent flood event in selected documents. In addition, recommendations provided in selected documents to reduce residual flood risk were mainly categorised as adjustments of policies, infrastructural measures, awareness-raising, training and education, and spatial planning interventions.
Furthermore, certain limitations of the study should be observed. It was beyond the scope of the review to collect information on the effectiveness and efficiency of individual measures. Besides, additional relevant research might be published in other databases beyond those considered for this review (Web of Knowledge, Scopus, and African Journals Online). In addition, most analysed research was carried out in only a few countries (Nigeria and Ghana) and specific geographical areas (urban + peri-urban and coastal). This aspect affects the generalisability of the results for the entire West African region. Consequently, future research should consider other potentially flood-affected countries and areas that have as well remained neglected by existing research so far. Therefore, analyses could assess if the spatial distribution of FRM-related research reflects the spatial distribution of flood impacts in ECOWAS countries, by for example drawing upon data from the EM-Dat database. Finally, the varying understanding of concepts relating to FRM such as risk, vulnerability, adaptation, or coping has to be observed when summarising such information on a meta-level. However, it is beyond the scope of this review to compare and contrast those variations.
Future studies could either embark on more complex modelling that approaches residual flood risk by researching the synergies of FRM-measures, their limitations in reducing the risk of flooding, and the various dimensions of impacts that arise from it. Or, as applied in this review, a focus on flood impacts that occur despite the implementation of FRM measures could also enrich case studies to approach residual flood risk from an empirical perspective. Moreover, more research on the role of social networks in the recovery from flood impacts, the range of impacts they usually cover, and the conditions that prevail within them will be highly relevant. It will also be necessary to research if and to what extent financial damages are covered and if those arrangements qualify as risk transfer mechanisms. Such research will help devise locally appropriate mechanisms that help address flood impacts that put people in financial need. Those efforts should be coupled with more thorough and detailed assessments of the suitability of insurance in addressing residual flood risk, given its currently limited role. Besides, future research could acknowledge the strong prevalence of infrastructural measures by investigating the problems that appear in implementing adequate flood-reducing infrastructure more deeply and how to overcome them. In addition, it could be relevant to research to what extent such measures could be complemented or substituted by nature-based solutions, which currently do not play a role in FRM-related West African case studies yet. Furthermore, the body of selected literature strongly raised the need for more participatory approaches that ensure the involvement of the population at-risk in decision-making and research. Such efforts could be focussed on but not limited to spatial planning interventions, awareness-raising training and education, and infrastructure construction. Finally, the use of local knowledge and skills in the form of FRM measures that the at-risk population already practices portrays another opportunity for such involvements. However, the latter aspect is not part of the dominant foci of practiced or recommended measures that this review identified but still should be subject to future research.
References
Abass K, Dumedah G, Frempong F (2019) Understanding the physical and human contexts of fluvial floods in rural Ghana. International Journal of River Basin Management:1–12. https://doi.org/10.1080/15715124.2019.1653310
Abbas A, Amjath-Babu TS, Kächele H, Usman M, Müller K (2016) An overview of flood mitigation strategy and research support in South Asia: implications for sustainable flood risk management. Int J Sust Dev World 23:98–111. https://doi.org/10.1080/13504509.2015.1111954
Adekola O, Lamond J, Adelekan I, Eze EB (2019) Evaluating flood adaptation governance in the city of Calabar, Nigeria. Climate and Development:1–14. https://doi.org/10.1080/17565529.2019.1700771
Adelekan I, Fregene T (2015) Vulnerability of artisanal fishing communities to flood risks in coastal southwest Nigeria. Climate Dev 7:322–338. https://doi.org/10.1080/17565529.2014.951011
Adelekan IO (2010) Vulnerability of poor urban coastal communities to flooding in Lagos, Nigeria. Environ Urban 22:433–450. https://doi.org/10.1177/0956247810380141
Adelekan IO (2016) Flood risk management in the coastal city of Lagos, Nigeria. J Flood Risk Manag 9:255–264. https://doi.org/10.1111/jfr3.12179
Adeleye BM, Ayangbile OA (2016) Flood vulnerability: impending danger in Sabon-Gari Minna, Niger State, Nigeria Ethiopian. J Environ Stud Manag 9:35. https://doi.org/10.4314/ejesm.v9i1.4
Adewole IF, Agbola SB, Kasim OF (2015) Building resilience to climate change impacts after the 2011 flood disaster at the University of Ibadan, Nigeria. Environ Urban 27:199–216. https://doi.org/10.1177/0956247814547679
Afriyie K, Ganle JK, Santos E (2018) ‘The floods came and we lost everything’: weather extremes and households’ asset vulnerability and adaptation in rural Ghana. Climate Dev 10:259–274. https://doi.org/10.1080/17565529.2017.1291403
Agbola BS, Ajayi O, Taiwo OJ, Wahab BW (2012) The August 2011 flood in Ibadan, Nigeria: anthropogenic causes and consequences. Int J Dis Risk Sci 3:207–217. https://doi.org/10.1007/s13753-012-0021-3
Ahadzie DK, Proverbs DG (2011) Emerging issues in the management of floods in Ghana. Int J SAFE 1:182–192. https://doi.org/10.2495/SAFE-V1-N2-182-192
Ajaero CK (2017) A gender perspective on the impact of flood on the food security of households in rural communities of Anambra state, Nigeria. Food Security 9:685–695. https://doi.org/10.1007/s12571-017-0695-x
Ajaero CK, Mozie AT, Abu IN (2018) Migrating from migratory waters to migration of livelihoods. Soc Indic Res 136:319–333. https://doi.org/10.1007/s11205-016-1524-x
Ajibade I, McBean G (2014) Climate extremes and housing rights: a political ecology of impacts, early warning and adaptation constraints in Lagos slum communities. Geoforum 55:76–86. https://doi.org/10.1016/j.geoforum.2014.05.005
Ajibade I, McBean G, Bezner-Kerr R (2013) Urban flooding in Lagos, Nigeria: patterns of vulnerability and resilience among women. Glob Environ Chang 23:1714–1725. https://doi.org/10.1016/j.gloenvcha.2013.08.009
Akinsanola AA, Zhou W (2019) Projections of West African summer monsoon rainfall extremes from two CORDEX models. Clim Dyn 52:2017–2028. https://doi.org/10.1007/s00382-018-4238-8
Almoradie A, Brito MM, Evers M, Bossa A, Lumor M, Norman C, Yacouba Y, Hounkpe J (2020) Current flood risk management practices in Ghana: gaps and opportunities for improving resilience. J Flood Risk Manag 13. https://doi.org/10.1111/jfr3.12664
Antwi-Boasiako BA (2016) Insurance and flood risk reduction in Ghana: do insurers penalise homeowners who take precautionary measures? Environ Hazards 15:343–355. https://doi.org/10.1080/17477891.2016.1209455
Antwi-Boasiako BA (2017) It’s beyond my control: the effect of locus of control orientation on disaster insurance adoption. Int J Dis Risk Reduction 22:297–303. https://doi.org/10.1016/j.ijdrr.2017.02.014
Arrighi C, Rossi L, Trasforini E, Rudari R, Ferraris L, Brugioni M, Franceschini S, Castelli F (2018) Quantification of flood risk mitigation benefits: a building-scale damage assessment through the RASOR platform. J Environ Manage 207:92–104. https://doi.org/10.1016/j.jenvman.2017.11.017
Atidegla SC, Koumassi HD, Houssou ES (2018) Variabilité climatique et production maraîchère dans la plaine inondable d’Ahomey-Gblon au Bénin. Int J Biol Chem Sci 11:2254. https://doi.org/10.4314/ijbcs.v11i5.2
Badou FD, Hounkpè J, Yira Y, Ibrahim M, Bossa AY (2019) Increasing devastating flood events in West Africa: who is to blame? In: Adegoke J, Sylla MB, Bossa AY, Ogunjobi K, Adounkpe J (eds) Regional climate change series: floods. WASCAL Publishing, Accra, Ghana, pp 84–90
Beck HE, Zimmermann N, McVicar TR, Vergopolan N, Berg A, Wood EF (2018) Present and future Köppen-Geiger climate classification maps at 1-km resolution. Sci Data 5:180214. https://doi.org/10.1038/sdata.2018.214
Berrang-Ford L, Ford JD, Paterson J (2011) Are we adapting to climate change? Glob Environ Chang 21:25–33. https://doi.org/10.1016/j.gloenvcha.2010.09.012
Berrang-Ford L, Pearce T, Ford JD (2015) Systematic review approaches for climate change adaptation research. Reg Environ Change 15:755–769. https://doi.org/10.1007/s10113-014-0708-7
Biconne R (2014) Knowledge sharing on climate change as a resource for adaptation processes: the case of Malika, Senegal. In: Macchi S, Tiepolo M (eds) Climate change vulnerability in Southern African cities. Springer International Publishing, Cham, pp 125–140
Biesbroek R, Berrang-Ford L, Ford JD, Tanabe A, Austin SE, Lesnikowski A (2018) Data, concepts and methods for large- n comparative climate change adaptation policy research: a systematic literature review. Wiley Interdiscip Rev Clim Change 9:e548. https://doi.org/10.1002/wcc.548
Boamah S, Armah F, Kuuire V, Ajibade I, Luginaah I, McBean G (2015) Does previous experience of floods stimulate the adoption of coping strategies? Evidence from cross sectional surveys in Nigeria and Tanzania. Environments 2:565–585. https://doi.org/10.3390/environments2040565
Bonye SZ, Godfred JS (2011) Traditional coping mechanisms in disaster management in the Builsa and Sissala districts of Northern Ghana. Eur J Soc Sci 25:204–218
Bottazzi P, Winkler M, Boillat S, Diagne A, Maman Chabi Sika M, Kpangon A, Faye S, Speranza C (2018) Measuring subjective flood resilience in suburban Dakar: a before–after evaluation of the “live with water” project. Sustainability 10:2135. https://doi.org/10.3390/su10072135
Bottazzi P, Winkler MS, Ifejika Speranza C (2019) Flood governance for resilience in cities: the historical policy transformations in Dakar’s suburbs. Environ Sci Policy 93:172–180. https://doi.org/10.1016/j.envsci.2018.12.013
Campion BB, Venzke J-F (2013) Rainfall variability, floods and adaptations of the urban poor to flooding in Kumasi, Ghana. Nat Hazards 65:1895–1911. https://doi.org/10.1007/s11069-012-0452-6
Carrick J, Abdul R, Rahim MSABA, Adjei C, Kalee HHA, Banks SJ, Bolam FC, Campos LIM, Clark B, Cowton J, Domingos IFN, Golicha DD, Gupta G, Grainger M, Hasanaliyeva G, Hodgson DJ, Lopez-Capel E, Magistrali AJ, Merrell IG, Oikeh I, Othman MS, Ranathunga M, Thilanka KR, Samuel CWC, Sufar EKH, Watson PA, Zakaria NNAB, Stewart G (2019) Is planting trees the solution to reducing flood risks? J Flood Risk Manag 12:635. https://doi.org/10.1111/jfr3.12484
Challies E, Newig J, Thaler T, Kochskämper E, Levin-Keitel M (2016) Participatory and collaborative governance for sustainable flood risk management: an emerging research agenda. Environ Sci Policy 55:275–280. https://doi.org/10.1016/j.envsci.2015.09.012
Cirella G, Iyalomhe F (2018) Flooding conceptual review: sustainability-focalized best practices in Nigeria. Appl Sci 8:1558. https://doi.org/10.3390/app8091558
Cirella G, Iyalomhe F, Adekola P (2019) Determinants of flooding and strategies for mitigation: two-year case study of Benin City. Geosciences 9:136. https://doi.org/10.3390/geosciences9030136
Coker AA, Adebayo CO, Odoemena BC, Akogun EO, Ezinne CG (2014) Flood and cassave productivity in Kogi State, Nigeria: a quantitative analysis using cross-sectional data. Ethiopian J Environ Stud Manag 7:599. https://doi.org/10.4314/ejesm.v7i6.2
Danso SY, Addo IY (2017) Coping strategies of households affected by flooding: a case study of Sekondi-Takoradi Metropolis in Ghana. Urb Water J 14:539–545. https://doi.org/10.1080/1573062X.2016.1176223
DIVA GIS (2020) Download data by country. https://diva-gis.org/gdata. Accessed 20 Aug 2020
Dosio A, Jones RG, Jack C, Lennard C, Nikulin G, Hewitson B (2019) What can we know about future precipitation in Africa? Robustness, significance and added value of projections from a large ensemble of regional climate models. Clim Dyn 53:5833–5858. https://doi.org/10.1007/s00382-019-04900-3
Dunning C, Black E (2018) Later wet seasons with more intense rainfall over Africa under future climate change. J Clim 31:9719–9738
Echendu AJ (2020) The impact of flooding on Nigeria’s sustainable development goals (SDGs). Ecosyst Health Sustainability 6:1791735. https://doi.org/10.1080/20964129.2020.1791735
ECOWAS (2020) Member states. https://www.ecowas.int/member-states/. Accessed 27 Oct 2020
Egbinola CN, Olaniran HD, Amanambu AC (2017) Flood management in cities of developing countries: the example of Ibadan, Nigeria. J Flood Risk Manag 10:546–554. https://doi.org/10.1111/jfr3.12157
El Zowalaty ME, Järhult JD (2020) From SARS to COVID-19: a previously unknown SARS- related coronavirus (SARS-CoV-2) of pandemic potential infecting humans - call for a One Health approach. One Health (Amsterdam, Netherlands) 9:100124. https://doi.org/10.1016/j.onehlt.2020.100124
EM-Dat (2020) The Emergency Events Database - Universite catholique de Louvain (UCL) - CRED, D. Guha-Sapir. https://www.emdat.be/emdat_db/. Accessed 24 Mar 2020
Enete AA, Obi JN, Ozor N, Mba CL (2016) Socioeconomic assessment of flooding among farm households in Anambra state, Nigeria. Int J Clim Change Strat Manag 8:96–111. https://doi.org/10.1108/IJCCSM-07-2014-0084
Epule TE, Ford JD, Lwasa S, Lepage L (2017) Climate change adaptation in the Sahel. Environ Sci Policy 75:121–137. https://doi.org/10.1016/j.envsci.2017.05.018
ERCC (2020) West and Central Africa | Floods. https://erccportal.jrc.ec.europa.eu/ercmaps/ECDM_20200916_West-Central-Africa_Floods.pdf. Accessed 25 Sep 2020
EU (2007) Directive 2007/60/EC of the European Parliament and of the Council of 23 October 2007 on the assessment and management of flood risks
Evadzi PIK, Scheffran J, Zorita E, Hünicke B (2018) Awareness of sea-level response under climate change on the coast of Ghana. J Coast Conserv 22:183–197. https://doi.org/10.1007/s11852-017-0569-6
Evers M, Jonoski A, Almoradie A, Lange L (2016) Collaborative decision making in sustainable flood risk management: a socio-technical approach and tools for participatory governance. Environ Sci Policy 55:335–344. https://doi.org/10.1016/j.envsci.2015.09.009
Ford JD, McDowell G, Jones J (2014) The state of climate change adaptation in the Arctic. Environ Res Lett 9:104005. https://doi.org/10.1088/1748-9326/9/10/104005
Ford JD, Stephenson E, Cunsolo Willox A, Edge V, Farahbakhsh K, Furgal C, Harper S, Chatwood S, Mauro I, Pearce T, Austin S, Bunce A, Bussalleu A, Diaz J, Finner K, Gordon A, Huet C, Kitching K, Lardeau M-P, McDowell G, McDonald E, Nakoneczny L, Sherman M (2016) Community-based adaptation research in the Canadian Arctic. Wiley Interdiscip Rev Clim Change 7:175–191. https://doi.org/10.1002/wcc.376
Frick-Trzebitzky F (2017) Crafting adaptive capacity: institutional bricolage in adaptation to urban flooding in Greater Accra. Water Alternatives 10:625–647
Frick-Trzebitzky F, Bruns A (2019) Disparities in the implementation gap: adaptation to flood risk in the Densu Delta, Accra, Ghana. J Environ Planning Policy Manage 21:577–592. https://doi.org/10.1080/1523908X.2017.1343136
Glago FJ (2019) Household disaster awareness and preparedness: a case study of flood hazards in Asamankese in the West Akim Municipality of Ghana. Jamba (potchefstroom, South Africa) 11:789. https://doi.org/10.4102/jamba.v11i1.789
Grabs W, Tyagi AC, Hyodo M (2007) Integrated flood management. Water Sci Technol 56:97–103. https://doi.org/10.2166/wst.2007.541
Güneralp B, Güneralp İ, Liu Y (2015) Changing global patterns of urban exposure to flood and drought hazards. Glob Environ Chang 31:217–225. https://doi.org/10.1016/j.gloenvcha.2015.01.002
Hagenlocher M, Meza I, Anderson CC, Min A, Renaud FG, Walz Y, Siebert S, Sebesvari Z (2019) Drought vulnerability and risk assessments: state of the art, persistent gaps, and research agenda. Environ Res Lett 14:83002. https://doi.org/10.1088/1748-9326/ab225d
Hartmann T, Albrecht J (2014) From flood protection to flood risk management: condition-based and performance-based regulations in German water law. J Environ Law 26:243–268. https://doi.org/10.1093/jel/equ015
Hetcheli F (2013) Risques pluviométriques et nouvelles orientations des agriculteurs du canton de Togblékopé (basse vallée de Zio) au Togo. Journal De La Recherche Scientifique De L’université De Lomé, Série B 15:135–149
Holmes EA, O’Connor RC, Perry VH, Tracey I, Wessely S, Arseneault L, Ballard C, Christensen H, Cohen Silver R, Everall I, Ford T, John A, Kabir T, King K, Madan I, Michie S, Przybylski AK, Shafran R, Sweeney A, Worthman CM, Yardley L, Cowan K, Cope C, Hotopf M, Bullmore E (2020) Multidisciplinary research priorities for the COVID-19 pandemic: a call for action for mental health science. The Lancet Psychiat 7:547–560. https://doi.org/10.1016/S2215-0366(20)30168-1
Ibitoye MO, Komolafe AA, Adegboyega AS, Adebola AO, Oladeji OD (2019) Analysis of vulnerable urban properties within river Ala floodplain in Akure, Southwestern Nigeria. Spatial Information Research. https://doi.org/10.1007/s41324-019-00298-6
IMF (2020) Policy responses to Covid-19. https://www.imf.org/en/Topics/imf-and-covid19/Policy-Responses-to-COVID-19. Accessed 10 Jun 2020
Kablan AKM, Dongo K, Fokou G, Coulibaly M (2019) Assessing population perception and socioeconomic impact related to flood episodes in urban Côte d’Ivoire. Int J Biol Chem Sci 13:2210. https://doi.org/10.4314/ijbcs.v13i4.26
Kamara JK, Akombi BJ, Agho K, Renzaho AMN (2018) Resilience to climate-induced disasters and its overall relationship to well-being in Southern Africa: a mixed-methods systematic review. Int J Environ Res Public Health 15. https://doi.org/10.3390/ijerph15112375
Kielland A (2016) The role of risk perception in child mobility decisions in West Africa, empirical evidence from Benin. World Dev 83:312–324. https://doi.org/10.1016/j.worlddev.2016.01.008
Komi K, Amisigo B, Diekkrüger B (2016) Integrated flood risk assessment of rural communities in the Oti River Basin. West Africa Hydrology 3:42. https://doi.org/10.3390/hydrology3040042
Lesnikowski AC, Ford JD, Berrang-Ford L, Barrera M, Heymann J (2015) How are we adapting to climate change? A global assessment. Mitig Adapt Strat Glob Change 20:277–293. https://doi.org/10.1007/s11027-013-9491-x
Lokonon BOK (2016) Urban households’ attitude towards flood risk, and waste disposal: evidence from Cotonou. Int J Dis Risk Reduction 19:29–35. https://doi.org/10.1016/j.ijdrr.2016.08.015
Ludy J, Kondolf GM (2012) Flood risk perception in lands “protected” by 100-year levees. Nat Hazards 61:829–842. https://doi.org/10.1007/s11069-011-0072-6
Mahe G, Lienou G, Descroix L, Bamba F, Paturel JE, Laraque A, Meddi M, Habaieb H, Adeaga O, Dieulin C, Chahnez Kotti F, Khomsi K (2013) The rivers of Africa: witness of climate change and human impact on the environment. Hydrol Process 27:2105–2114. https://doi.org/10.1002/hyp.9813
Markantonis V, Farinosi F, Dondeynaz C, Ameztoy I, Pastori M, Marletta L, Ali A, Carmona Moreno C (2018) Assessing floods and droughts in the Mékrou River basin (West Africa): a combined household survey and climatic trends analysis approach. Nat Hazard 18:1279–1296. https://doi.org/10.5194/nhess-18-1279-2018
Mbow C, Diop A, Diaw AT, Niang CI (2008) Urban sprawl development and flooding at Yeumbeul suburb (Dakar-Senegal). Afr J Environ Sci Technol 2
Mengist W, Soromessa T, Legese G (2020) Method for conducting systematic literature review and meta-analysis for environmental science research. MethodsX 7:100777. https://doi.org/10.1016/j.mex.2019.100777
Milman A, Warner BP, Chapman DA, Short Gianotti AG (2018) Identifying and quantifying landowner perspectives on integrated flood risk management. J Flood Risk Manag 11:34–47. https://doi.org/10.1111/jfr3.12291
Ngwese NM, Saito O, Sato A, Agyeman Boafo Y, Jasaw G (2018) Traditional and local knowledge practices for disaster risk reduction in Northern Ghana. Sustainability 10:825. https://doi.org/10.3390/su10030825
Nicola M, Alsafi Z, Sohrabi C, Kerwan A, Al-Jabir A, Iosifidis C, Agha M, Agha R (2020) The socio-economic implications of the coronavirus pandemic (COVID-19): a review. Int J Surg (London, England) 78:185–193. https://doi.org/10.1016/j.ijsu.2020.04.018
Nkwunonwo UC, Whitworth M, Baily B (2016) Review article: A review and critical analysis of the efforts towards urban flood risk management in the Lagos region of Nigeria. Nat Hazards Earth Syst Sci 16:349–369. https://doi.org/10.5194/nhess-16-349-2016
Nordbeck R, Steurer R, Löschner L (2019) The future orientation of Austria’s flood policies: from flood control to anticipatory flood risk management. J Environ Planning Manage 62:1864–1885. https://doi.org/10.1080/09640568.2018.1515731
Ntajal J, Lamptey BL, Mahamadou IB, Nyarko BK (2017) Flood disaster risk mapping in the Lower Mono River Basin in Togo, West Africa. Int J Dis Risk Reduction 23:93–103. https://doi.org/10.1016/j.ijdrr.2017.03.015
Odemerho FO (2015) Building climate change resilience through bottom-up adaptation to flood risk in Warri, Nigeria. Environ Urban 27:139–160. https://doi.org/10.1177/0956247814558194
Oladokun VO, Proverbs D (2016) Flood risk management in Nigeria: a review of the challenges and opportunities. Int J SAFE 6:485–497. https://doi.org/10.2495/SAFE-V6-N3-485-497
Olanrewaju CC, Chitakira M, Olanrewaju OA, Louw E (2019) Impacts of flood disasters in Nigeria: a critical evaluation of health implications and management. Jamba (potchefstroom, South Africa) 11:557. https://doi.org/10.4102/jamba.v11i1.557
Olokesusi F, Olorunfemi FB, Onwuemele A, Oke MO (2015) Awareness of and responses to the 2011 flood warnings among vulnerable communities in Lagos, Nigeria. In: Werlen B (ed) Global sustainability. Springer International Publishing, Cham, pp 203–223
Onu B, Price T, Surendran SS, Timbiri A (2013) Peoples’ perception on the effects of flood in the riverine areas of Ogbia Local Government Area of Bayelsa State, Nigeria. Knowl Manag 12:21–44
Osayomi T, Oladosu OS (2016) “Expect more floods in 2013”: an analysis of flood preparedness in the flood prone city of Ibadan, Nigeria. Afr J Sustainab Dev 6
Osman A, Nyarko BK, Mariwah S (2016) Vulnerability and risk levels of communities within Ankobra estuary of Ghana. Int J Dis Risk Reduction 19:133–144. https://doi.org/10.1016/j.ijdrr.2016.08.016
Ottah GA (2017) Impact of Radio Kogi’s flood disaster awareness campaign on residents of Ibaji Local Government Area of Kogi State, Nigeria. Int J Arts Human 6:80. https://doi.org/10.4314/ijah.v6i3.7
Ouikotan RB, van der Kwast J, Mynett A, Afouda A (eds) (2017) Gaps and challenges of flood risk management in West African coastal cities
Owen G (2020) What makes climate change adaptation effective? A systematic review of the literature. Glob Environ Chang 62:102071. https://doi.org/10.1016/j.gloenvcha.2020.102071
Owusu Twum K, Abubakari M (2019) Cities and floods: a pragmatic insight into the determinants of households’ coping strategies to floods in informal Accra, Ghana. Jamba (potchefstroom, South Africa) 11:608. https://doi.org/10.4102/jamba.v11i1.608
Oyekale AS, Oladele OI, Mukela F (2013) Impacts of flooding on coastal fishing folks and risk adaptation behaviours in Epe, Lagos State. Afr J Agric Res 8:3392–3405. https://doi.org/10.5897/AJAR12.730
Oyerinde GT, Lawin EA, Odofin AJ (2017) Farmers’ responses to changing hydrological trends in the Niger Basin parts of Benin. Hydrology 4:52. https://doi.org/10.3390/hydrology4040052
Page MJ, McKenzie JE, Bossuyt PM, Boutron I, Hoffmann TC, Mulrow CD, Shamseer L, Tetzlaff JM, Akl EA, Brennan SE, Chou R, Glanville J, Grimshaw JM, Hróbjartsson A, Lalu MM, Li T, Loder EW, Mayo-Wilson E, McDonald S, McGuinness LA, Stewart LA, Thomas J, Tricco AC, Welch VA, Whiting P, Moher D (2021) The PRISMA 2020 statement: an updated guideline for reporting systematic reviews. BMJ 372:n71. https://doi.org/10.1136/bmj.n71
Plate EJ (2002) Flood risk and flood management. J Hydrol 267:2–11
Roos MM, Hartmann TT, Spit TT, Johann GG (2017) Constructing risks – internalisation of flood risks in the flood risk management plan. Environ Sci Policy 74:23–29. https://doi.org/10.1016/j.envsci.2017.04.007
Saidu I (2009) An analysis of Loko flood disaster resettlement scheme, in Song Local Government Area of Adamawa State, Nigeria. J Environ 4:19–27
Sayers P, Li Y, Galloway G, Penning-Rowsell E, Shen F, Wen K, Chen Y, Le Quesne T (2013) Flood risk management: a strategic approach. UNESCO, Paris
Schaer C (2015) Condemned to live with one’s feet in water? Int J Clim Chang Strat Manag 7:534–551. https://doi.org/10.1108/IJCCSM-03-2014-0038
Schaer C, Hanonou EK (2017) The real governance of disaster risk management in peri-urban Senegal. Prog Dev Stud 17:38–53. https://doi.org/10.1177/1464993416674301
Schlef KE, Kaboré L, Karambiri H, Yang YE, Brown CM (2018) Relating perceptions of flood risk and coping ability to mitigation behavior in West Africa: case study of Burkina Faso. Environ Sci Policy 89:254–265. https://doi.org/10.1016/j.envsci.2018.07.013
Serpantié G, Dorée A, Fusillier J-L, Moity-Maizi P, Lidon B, Douanio M, Sawadogo A, Bossa AY, Hounkpè J (2019) Nouveaux risques dans les bas-fonds des terroirs soudaniens. Une étude de cas au Burkina Faso. Cah. Agric. 28:19. https://doi.org/10.1051/cagri/2019020
Shaffril HAM, Krauss SE, Samsuddin SF (2018) A systematic review on Asian’s farmers’ adaptation practices towards climate change. Sci Total Environ 644:683–695. https://doi.org/10.1016/j.scitotenv.2018.06.349
Siddaway AP, Wood AM, Hedges LV (2019) How to do a systematic review: a best practice guide for conducting and reporting narrative reviews, meta-analyses, and meta-syntheses. Annu Rev Psychol 70:747–770. https://doi.org/10.1146/annurev-psych-010418-102803
Thomas F, Knüppe K (2016) From flood protection to flood risk management: insights from the Rhine River in North Rhine-Westphalia, Germany. Water Resour Manage 30:2785–2800. https://doi.org/10.1007/s11269-016-1323-9
Tiepolo M, Rosso M, Massazza G, Belcore E, Issa S, Braccio S (2019) Flood assessment for risk-informed planning along the Sirba River. Niger Sustainability 11:4003. https://doi.org/10.3390/su11154003
UN (1989) International decade for natural disaster reduction. Resolutions adopted on the reports of the Second Committee. https://undocs.org/A/RES/44/236. Accessed 09 May 2020
UN (2005) Report of the World Conference on Disaster Reduction Kobe, Hyogo, Japan, 18–22 January 2005
UN (2015) Sendai framework for disaster risk reduction 2015 - 2030
UN OCHA (2007) West Africa - floods. https://reliefweb.int/sites/reliefweb.int/files/resources/FDBC0DD4783141E385257378004811DF-ocha_FL_afr071017.pdf. Accessed 25 Sep 2020
UN OCHA (2009) West Africa - flood affected population - June to September 2009. https://reliefweb.int/sites/reliefweb.int/files/styles/report-large/public/resources-pdf-previews/15744-14D93E78C3482C2F8525764200666310-map.png?itok=prnIuu-q. Accessed 25 Sep 2020
UN OCHA (2010) West Africa - flood impact profile. http://www.un-spider.org/sites/default/files/images/Dieye_Fig.2.gif. Accessed 25 Sep 2020
UN OCHA (2012) West and Central Africa: floods situation (as of 15 Oct 2012). https://reliefweb.int/sites/reliefweb.int/files/resources/map_3086.pdf. Accessed 25 Sep 2020
UN OCHA (2016) West Africa: impact of the floods. https://www.humanitarianresponse.info/sites/www.humanitarianresponse.info/files/documents/files/wca_a4_l_impact_of_floods_20160822.pdf. Accessed 25 Sep 2020
UNDRR (2020a) Residual risk. https://www.undrr.org/terminology/residual-risk. Accessed 26 Mar 2020
UNDRR (2020b) Risk transfer. https://www.undrr.org/terminology/risk-transfer. Accessed 10 Jul 2020
VERBI (2021) What is MAXQDA? https://www.maxqda.com/what-is-maxqda. Accessed 04 Jan 2021
Vissin EW, Hedible S, Amoussou E, Totin HS, Odoulami L, Etene C, Boko M, Blivi A (2016) Variabilité climatique et hydrologique dans la Basse Vallée de l’Oumémé à Bonou. Journal De La Recherche Scientifique De L’université De Lomé, Série B 18:69–81
Vizy EK, Cook KH (2012) Mid-twenty-first-century changes in extreme events over northern and tropical Africa. J Clim 25:5748–5767. https://doi.org/10.1175/JCLI-D-11-00693.1
Wahab B, Falola O (2017) The consequences and policy implications of urban encroachment into flood-risk areas: the case of Ibadan. Environ Hazards 16:1–20. https://doi.org/10.1080/17477891.2016.1211505
Wellens K, Terpstra T, de Maeyer P (2013) Perception and communication of flood risks: a systematic review of empirical research. Risk Anal 33:24–49. https://doi.org/10.1111/j.1539-6924.2012.01844.x
WMO (2009) Integrated flood management. Concept Paper. WMO-No.1047
Young HR, Cornforth RJ, Gaye AT, Boyd E (2019) Event attribution science in adaptation decision-making: the context of extreme rainfall in urban Senegal. Climate Dev 11:812–824. https://doi.org/10.1080/17565529.2019.1571401
Acknowledgements
The authors would like to kindly thank Emmanuel Lobe Ekamby and Vincent Moseti Nyabera for their support in the coding process of the article. Finally, the authors highly appreciate the helpful assistance of Michael Zissener, Sabrina Zwick, Princess Faith Donani, Alvaro Rojas-Ferreira, Florian Waldschmidt, Eike Behre, and David Daou in the screening process of articles.
Funding
This study was funded by the German Federal Ministry for Education and Research (BMBF) through the CLIMAFRI project (grant number 01LZ1710A-E) as well as the Munich Climate Insurance Initiative (MCII).
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Wagner, S., Souvignet, M., Walz, Y. et al. When does risk become residual? A systematic review of research on flood risk management in West Africa. Reg Environ Change 21, 84 (2021). https://doi.org/10.1007/s10113-021-01826-7
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DOI: https://doi.org/10.1007/s10113-021-01826-7