Flood is the flow of an excess of water that submerges land usually not covered by water. Floods are the most frequent disasters worldwide and they mostly affect people who have a low social and economic status as they tend to live in the flood-prone areas of the cities (Sodhi and Tang, 2013) (see figure 1). In June 2012, there were 17.4 million victims caused by the flood that affected China. Additionally, this country was affected by another flood in April (13.1 million victims) and two storms in August (9.8 million victims), contributing to a worldwide total of 44.6 million flood victims (EM-DAT, 2013). In figure 2 it can be observed that hydrological disasters (including floods) are responsible for the greatest number of people affected worldwide by natural disasters between the years 1900 to 2012. Natural disasters are considered random events due to its complexity and the need for several other incidents to occur simultaneously. If the actual trend continuous, more natural disasters such as floods will continue to happen. It is thus important to highlight that floods and storms are responsible for more than 55% of all natural disasters (EM-DAT, 2013). Furthermore, Palmer and Raïsänen (2002) specify that climate change will affect the probability of atypical seasons of high intensity rainfall in the next hundred years in such a way that it will be five times the current probability. Mexico, through its history, has been immersed in several meteorological phenomena, which marked and forced the population to enhance hydrological and hydraulic techniques to cope with floods. In fact, since the era of Tenochtitlan, its inhabitants experienced the frequent increment in height of lakes and rivers which provoked floods and forced them to build hydraulic structures as magnificent as the ones made by other developed cultures of that era (Gonzalez et al., 2012).

Figure 1.

Number of natural disasters reported for the period 1900-2012 (EM-DAT, 2013).

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Figure 2.

Reported number of people affected by natural disasters for the period 1900-2012 (EM-DAT, 2013).

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Mexico is affected annually by an average of 8 hurricanes on the Atlantic coast and at least two of them go inland while the Pacific Ocean coast is struck annually by an average of 13 hurricanes and at least 4 of them reach land and cause severe damage (Bitrán, 2001). To demonstrate the significance of damage caused by floods the following events are accurate examples: a) the flood generated by one of the most important tropical depression of the last 40 years in the country, occurred on October 1999 in the Tehuantepec Isthmus region and it was responsible for more than 260 human casualties and huge damage across 81 municipalities (Bitran, 2001), b) the State of Tabasco, in 2007, was affected by an extraordinary precipitation in the middle watershed of the Grijalva river which caused floods in more than 70% of its territory with water levels up to 4 meters in urban areas (Bitran, 2001), and c) in September 2013 Mexico’s Pacific and Gulf coasts were both flooded simultaneously by deadly hurricanes (Ingrid and Manuel) causing at least 23 deaths and more than 1,5 U$ billion of economic losses in the Pacific coast and 169 casualties and more than 4,2 U$ billions in damage in the Mexican Gulf coast (AONbenfield, 2013). Moreover, it is worth to stress that the previous simultaneous occurrence of two hurricanes in Mexico was held in 1958 (NASA, 2013). Figure 3 depicts Ingrid and Manuel hurricanes affecting both Mexican coasts (NASA, 2013).

Figure 3.

View of Manuel and Ingrid hurricanes affecting both Pacific and Gulf of Mexico coasts (NASA, 2013).

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Mexican authorities are continuously working on emergency plans and hydro-meteorological alert systems, but up until now, in the presence of an extreme flood, the major set of activities to help people affected is the Plan DNIII used to evacuate and rescue the population involved. However that plan is only applied once the event had occurred and is not designed specifically for flooding events. Therefore, it is necessary to count with an early flood warning system and evacuation plan that includes its logistics and supply chain support. As a result, this paper aims to analyze the relationship between flood risk assessment and the humanitarian logistics tasks concerned with these kinds of events in order to identify the main gaps that remain unaddressed in the Mexican emergency plans, which could presents itself as a great opportunity for research and a very good way to contribute to the effort to protect and ensure the society’s wellbeing.

Despite the fact that the number of floods has been increasing exponentially since 1900, there is very little research information in humanitarian logistics and its supply chain to deal with floods (Sodhi and Tang, 2013).

Humanitarian logistics could be defined as the set of activities of planning, implementing, and controlling the flow and storage of goods and materials in an efficient and cost-effective manner; as well as its related information, from point of origin to point of consumption for the purpose of alleviating the impact on vulnerable people (Thomas and Kopczak, 2005).

Humanitarian logistics differs fundamentally from commercial supply chains. The ultimate goal of commercial supply chains (Beamon and Balcik, 2008) is to deliver the right supplies in the right quantities to the right location at the right time, while the humanitarian aid chains objective is to provide humanitarian support in the form of medicine, food, shelter and water, and other supplies to the area affected by a large scale emergency.

The cycle for disaster management is often described as a process with four stages: 1) Mitigation, 2) Preparedness, 3) Response, and 4) Reconstruction. Flood logistics oversees mainly the preparedness, response and reconstruction phases.

For the purpose of this article, emphasis is made on the preparedness and response phases for the flood. The preparedness phase refers to several operations that should occur during the period before disaster strikes, unlike the response phase which deals with various operations that are simultaneously implemented just after a flood occurs. The preparedness phase is crucial and it consists in the physical network design, the information and communications technology systems, and the building of bases for institutional collaboration in order to ensure people know evacuation options, location of pre-positioned emergency response supplies, and shelter’s capacity to respond to disasters. In the response phase, coordination and collaboration among all the players involved in the humanitarian flood emergency deserves particular attention (Cozzolino et al., 2012).

Moreover, at this stage activities are primarily focused on saving lives and preventing or mitigating further damage. Here the humanitarian operations rely mostly on logistics because they consider the distribution of food, medical supplies and other necessities on which human lives depend on, and thus the importance of how quickly the logistics tasks are performed.

In the literature about disaster logistics, several authors highlight as a key issue the “last mile relief distribution” concept which involves the ultimate connector of humanitarian activities with the victims. This concept refers to the supply of relief items from the local distribution centers to the people affected by the natural disaster (Balcik et al., 2008).

Several supply chain performance measures have been proposed for different perspectives, depending on the type of supply chain ((Moore, 2000; Cedillo-Campos et al. (2013); Beamon and Balcik (2008) and Santarelli et al. (2013)). For example, the performance measurement of Commercial supply chains are more related to financial metrics, since they are indicators of market-need satisfaction and an organization’s ability to operate efficiently in cost and responsiveness (Kanter and Summers, 1987). For nonprofit supply chains, performance measurement is more related to intangible aspects such as alleviate human suffering and reduce human fatalities. For example, Santarelli et al. (2013) evaluate the performance of humanitarian supply chains, considering five categories and for each of them several key performance indicators (KPIs), for quantitative and qualitative, financial and no-financial. Han et al. (2007) proposed as measures of effectiveness (MOE) for an effective evacuation plan: evacuation time, cumulative exposure, and temporal/spatial risk factors. The equity of the evacuation plan is considered by Gaytán et al. (2013) who consider as MOE maximum distribution time of the supplies to shelters, total cost of the plan, and maximum evacuation time. These measures are used to define critical decision including shelters to be opened, population to be transported to each shelter, transportation modes, distribution centers to be opened, and number of vehicles required to distribute humanitarian aid from distribution centers to shelters. The performance of humanitarian logistics effort is also related to the last mile distribution from distribution center to beneficiaries. Huang et al. (2012) study the impact of the efficacy and equity of the distribution on the number and type of service vehicles, and structure of vehicles routes.

Villahermosa, the capital of the state of Tabasco, is located 904 km from Mexico City and is situated at an average of 10 m AMSL where the flow of three important rivers converges: the Grijalva River, the De la Sierra River and the Usumacinta River. Its geographical situation contributes to the propensity of flood risk. In fact The National Risk Atlas classifies this municipality as one with high vulnerability (CENAPRED, 2012). During the flood event that took place during 2007, the floods covered near 70% of the state, and the water level rose up to cover 80% of the city of Villahermosa. Estimated affected people were around 196,682 (SEGOB, 2008).

A GIS was built to include road and altitude maps, street network and infrastructure in order to locate possible shelters and distribution centers. Combining the GIS and developing hydrological and hydraulic analysis, simulated flooding maps were constructed for different flooding times for the conditions of the 2010 scenario. The corresponding map for a 2 m flooding scenario, at the lowest point of the watershed, is shown in figure 7. Once the flooding zone and affected population are known, the information gathered is fed to a multi-objective optimization model (Mejía et al., 2012) that considers equity of distribution aid, evacuation time, and evacuation costs as criteria. Pareto front for the three criteria is constructed with a heuristic algorithm developed, which is based on the SSPMO procedure (Molina et al., 2007). The Pareto front is submitted to the decision makers. Each point of Pareto front corresponds to the most convenient number of shelters, distribution centers, evacuation points, and vehicles required to evacuate the affected population.

Figure 7.

Flooded area of Villahermosa, Tabasco Mexico under a 2 m flooding scenario at the lowest point of the watershed (Mejia et al. (2012)).

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Floods are more predictable, or can be simulated with an acceptable degree of accuracy (unlike other kind of natural disasters such as earthquakes) in terms of timing, magnitude and location. Hence, nowadays with the available knowledge and technology there is an opportunity for a much better preparedness, response, and mitigation against this natural phenomena.

Therefore it is important to create the database needed for forecasting floods and also to make contributions to strengthening a multidisciplinary and multi-sectorial teamwork, which will be responsible for finding practical solutions against flood disasters in the country. However, to optimize the logistic performance it is required that all the relationships among the stakeholders are managed under an integrated approach and an efficient coordination for a good performance.

Humanitarian logistics is a very important research field that requires attention in order to develop tools and decision support systems that when used they facilitate the decision making process, and in practice help to save human lives and avoid significant negative economic impact for the stakeholders involved in a flood. Another gap that remains unaddressed is the development of metrics for all phases of a disaster cycle in order to monitor and improve all processes involved.

In this analysis the main logistical decisions and the factors which affect these decisions for the last mile relief distribution were synthesized stressing the need to tackle all these as a whole integrated process. Moreover, it was identified that there is a need for a multidisciplinary and multi-stakeholder participation to guarantee the emergency response services are prepared against floods. And finally, it should be understood that a flood hazard mitigation situation needs to shift from only a disaster reactive response system to a more preparedness based system on flood risk assessment, and to an improved humanitarian logistics and its supply chain programs which must include an effective flood early warning system.