Collation of best practices for preparedness: lessons from disasters in Pakistan and Japan

3.1 Background

On the morning of 8 October 2005, an earthquake with a Richter Scale magnitude of 7.6 struck 95 km Northeast of Pakistan’s capital, Islamabad, killing at least 73.000 people and leaving around 3 million people in need of shelter (Asian Development Bank, 2005). The size of the area hit by the earthquake is compared to the Belgium land area (United Nations System in Pakistan and Government of the Islamic Republic of Pakistan, 2006). The people were facing a high chance of a second disaster – the cold, harsh Himalayan winter, exposing people to cold and starvation (Cosgrave and Herson, 2006). The humanitarian logistics and supply chain played significant roles; without good organisation, more lives would have been threatened.

Following its independence in 1947, Pakistan has focused mainly on managing flood risks. However, typical to the country’s east floods impacted agricultural and economic growth and affected the more populated areas of the country (Mustafa and Wescoat, 2009).

In the 1950s, following other countries’ examples, five-year national planning cycles were designed, mainly focusing on economic growth and industrial development. However, macroeconomic growth was the focus of national planning, neglecting national emergency preparedness and essential services provision strategies in response to disasters and hazards (Cheema et al., 2016). National planning should overlook emergency preparedness and critical services (Talapatra et al., 2019). Increasingly, Pakistan improved the social indicators in their eight consecutive five-year plans from 1993 to 1998. However, the focus was barely on response and relief following a natural disaster, and no plans were considered for regular prevention or preparedness for hazards (Cheema et al., 2016; Tatham et al., 2016).

Appendix 4 summarises the established plans that revolve around technical solutions to emergencies, focus on the river and canal systems, with little-to-no considerations for potential casualties or communication risks and social vulnerability assessment (Cheema et al., 2016)

The Pakistani Government had little preparedness for any emergency (Khan and Ashori, 2016). Up to the 2005 earthquake, different institutions were carrying out the response to natural disasters, mainly on an ad hoc basis (Cochrane, 2008). The Damage Need Assessment states that even though Pakistan is prone to different natural disasters, it still carries an ad hoc approach to disaster risk management, with the response and relief phase overshadowing ex-ante mitigation processes (Asian Development Bank, 2005).

Many different federal and local organisations were supposed to act in disaster response and relief. However, they needed to clearly define roles at different relief management phases and a clear structure for who was responsible for what steps in the process. This led to disorganised workflow and inefficient control systems, wherein institutions played overlapping roles in various relief management stages (United Nations System, 2005).

No authority carried the primary responsibility, depriving coherent policy-making to understand better and predict hazards and risks, promoting safety culture and providing adequate resources (Cheema et al., 2016). In addition, regulatory and legislation gaps enhanced the inherent institutional weaknesses creating further difficulties for improvement and allowing vulnerabilities to persist (Deen, 2015). Facing a lack of central support, the affected communities increased political activity to push for improvement (Miles and Huberman, 1994).

Before the 2005 earthquake, Pakistan faced many challenges in fulfilling the population’s health, education and poverty reduction needs. Furthermore, Pakistan’s emergency management did not have the capacity to carry out necessary infrastructure and policy changes. Therefore, finding sufficient emergency planning resources was challenging (Cheema et al., 2016). In addition, the geographical difficulties with access to affected areas, the paucity of necessary aid supplies and the lack of financial support significantly hindered the relief operations (da Costa et al., 2014; Cosgrave and Nam, 2007).

3.2 Pakistan’s response to the disaster

The earthquake struck Pakistan’s Northwest Frontier Province and Pakistan-Administered Jammu and Kashmir, where 98% of the killed 75.000 population resided (Cosgrave and Herson, 2006). Following the earthquake, it was quickly recognised that a large-scale relief response was required. Consequently, the Federal Relief Commission (FRC), reporting directly to the Prime Minister, was established and headed by an army general (Cosgrave and Herson, 2006; Cochrane, 2008).

The FRC had two branches: a military branch responsible for the rescue, and a civil branch, that addressed the issues between departments and agencies. Moreover, all rehabilitation effort agencies had to go through the FRC (da Costa et al., 2014). However, the military played a central role, being the initiators of rescue operations, accompanied by many volunteers from Pakistan (Reis, 2018; United Nations System in Pakistan and Government of the Islamic Republic of Pakistan, 2006). Therefore, despite a civilian president, a general assumption was that the military ran the country (United Nations System in Pakistan and Government of the Islamic Republic of Pakistan, 2006).

The military engagement was unique in capability and availability (Cosgrave and Herson, 2006; Rahman et al., 2010). Their active role early following the earthquake, familiarity with national geography and, most importantly, the availability of operational equipment (helicopters, trucks and excavators) made the rescue easier (Reis, 2018). This is not surprising – Pakistan possesses the seventh-largest military force globally (Cosgrave and Herson, 2006). Similarly, in previous natural disasters (mainly floods) in Pakistan, the armed forces influenced disaster response and relief more significantly than any other government bodies (Meredith, 1998). Even though only 10% of the armed forces were involved, the remaining 90% being challenging to mobilise and support, they provided the core of rescue operation assets (Reis, 2018).

Following the earthquake, the Pakistan Government created two more bodies: The first one – Earthquake Reconstruction and Rehabilitation Authority (ERRA) –was created in 16 days to plan, coordinate, regulate and monitor the 20,000 square kilometres area affected by the earthquake. The second body – National Disaster Management Authority – was established in December to cover all natural disasters in the country (Watt et al., 2009).

Consequent to the earthquake, bridges collapsed, and many landslides interrupted roads and covered them with sizable rocks. Due to significant road damage and mountainous terrain, the affected remote sites were often exclusively accessible by helicopters (Cosgrave and Nam, 2007). This was the case for many mountainous villages that were hard to reach otherwise (Cosgrave and Herson, 2006). Military helicopters were mainly used, but due to high demand and limited time, more helicopters were needed than the military could provide (Asian Development Bank, 2005).

The European Commission Humanitarian Office (ECHO) supplied additional helicopters with significantly (up to ten times) larger capacity. Furthermore, the ECHO supported the Atlas Logistics project, which provided overall on-land logistic support systems for humanitarian organisations. With ECHO’s help, the most affected geographical areas requiring immediate assistance were easier to identify (Asian Development Bank, 2005). Nevertheless, acknowledging the alarming situation and realising that Pakistan alone could not handle the aftermath of the earthquake, President Pervez Musharraf requested urgent international help (Alexander, 2021).

The United Nations readily responded, although the consequences of the earthquake far extended their logistical and human resources. Therefore, NATO was consulted for additional assistance. Despite operating in Pakistan until October 2006, NATO acknowledges it as a significant challenge, as the affected area covered considerable distances (Reis, 2018; North Atlantic Treaty Orgasnization, NATO Handbook, Public Diplomacy Division, 2006; Jochems, 2006).

Notwithstanding the extraordinary efforts of the UN and other international organisations, Pakistan’s army played the most prominent role, demonstrating a perfect example of military-civil cooperation in the disaster aftermath. Additionally, non-governmental support was offered from private sectors and civil societies to small self-help groups, helping with donations and business services. As a result, over US$1.4bn was donated/granted from bilateral, multilateral and private donors. The combination of the different circumstances in the earthquake aftermath made the relief response one of the most complex and time-sensitive relief operations in human history (United Nations System in Pakistan and Government of the Islamic Republic of Pakistan, 2006).

3.3 Phases of evolution in Pakistan case

4.1 Background

Geographically, Japan is one of the most disaster-exposed countries globally. Strikingly, 20% of the world’s earthquakes with six and above magnitude occur in Japan. Additionally, 7% of the world’s active volcanos are in Japan (Nazarov, 2011).

On 11 March 2011, at 14:46 local time, the northeast coast of Japan was struck by a 9.0 magnitude earthquake, with a hypocentre 32 km below sea level, triggering one of the most significant tsunamis in human history. The latter spread along 600 km of the Tohoku region’s eastern coastline, with 38 meters wave height and covering 4–5km inland (Fraser et al., 2013; Esteban et al., 2015; Davis et al., 2012; Japanese Red Cross Society, 2013; Naoi et al., 2012). The event was described as a megadisaster, impacting over 560 square kilometres of Japan, killing 15,882 people and leaving 2,668 missings (Ishigaki et al., 2013; Parmar et al., 2017). Furthermore, over 20 countries along the pacific shores released warnings about possible tsunami outreach (Norio et al., 2011). As a result, a Japanese island was moved around 3.6 meters to the east, and the country’s west coast descended by about 60 cm (Norio et al., 2011).

Earthquakes and major landslides at ocean depths often trigger tsunamis (Nazarov, 2011). However, not only was Japan hit by a massive earthquake followed by a colossal tsunami. Nevertheless, the events further triggered a nuclear accident in the Fukushima power plant, reaching level 7 on the International Nuclear and Radiological Event Scale, comparable to the 1986 Chornobyl nuclear disaster. The events, described as the world’s second-largest nuclear accident, produced a power supply failure and disrupted supply chains worldwide (Davis et al., 2012; Japanese Red Cross Society, 2013; World Bank, 2012; Umeda, 2011).

Japan ensured constant community awareness of natural disaster possibilities, which is why the national and local governments supported communities’ engagement in disaster risk management, defining their roles and commitments over local institutions (World Bank, 2012). For example, based on past disasters, the Tohoku region locals marked tsunami water heights with stones, aiming to warn their residents to avoid building houses below defined levels. Slowly, however, the attention to these warnings faded (Naoi et al., 2012). Despite the annual evacuation drills, most participants were the elderly and children, few large disasters occurred over the years, and the public’s awareness decreased over time (Ranghieri and Ishiwatari, 2014). However, Tohoku locals remained adequately prepared thanks to their excellent disaster preparedness education: many locals had disaster preparedness kits loaded with food, water, first-aid supplies, radios and batteries (Greer, 2012).

Japanese communities possess remarkable mutual social obligation and cooperation skills concerning disasters, warranting increased public participation and high efficacy when disaster strikes (Paton et al., 2010). Furthermore, the Japanese time-tested traditional collectivism and resilience contributed to recovery and reconstruction in the aftermath of the disaster (Goulding et al., 2018). Therefore, it is essential to interactively interconnect the different government agencies and local communities in their efforts at accurate risk estimation to address disaster vulnerability (World Bank, 2012).

Japan is a highly developed country with advanced industry, economy and society, and unlike its developing counterparts, it affords to build disaster prediction systems and prepares necessary strategies (Paton et al., 2010). Rather than focusing on personnel and organisational development, employee education, organisational changes or attempting to alter their current disaster response methodology, the country instead focuses disaster management on structural solutions, such as developing new technologies and spending 7% of their annual budget on structural mitigation solutions (Greer, 2012). Before the 2011 earthquake, Japan had established high-technology systems issuing warnings of upcoming tsunamis via satellite communications and numerous monitoring stations facilitated by real-time transponders (Ranghieri and Ishiwatari, 2014).

An outstanding emergency response system has been noted in Japan, whereby every city follows an established emergency evacuation plan, with predefined refuge areas (primarily schools and city parks) to which people self-evacuate in disaster cases (Parmar et al., 2017; Yamada, 2007).

Additionally, directions to evacuation facilities were strategically placed on electricity poles and along roadsides. Planned evacuation routes were adopted to reduce evacuation times significantly, and over 70,000 designated tsunami evacuation areas were engineered on high ground or inland, far enough from the coast to shield from floods (Ranghieri and Ishiwatari, 2014; Fraser et al., 2013).

With its extended natural disaster history, Japan focuses its relief system on advanced technology development, annual emergency drills and on-the-job training. Emergency drills are mainly organised on the anniversaries of past sizable disasters (Ranghieri and Ishiwatari, 2014; Greer, 2012). According to the World Bank, many lives were saved, and mortality was minimised thanks to local community participation in emergency preparedness, using learned survival knowledge, effective decision-making and risk management (World Bank, 2012; Paton et al., 2010).

The “Tsunami, ten-den-ko” is the Tohoku people’s mindset, asserting that each person is responsible for their individual, timely evacuation. As a result, valuable time is saved based on mutual trust, as parents no longer hurry to pick up their children from school, costing their own lives (Ishigaki et al., 2013).

Japan took many Tsunami impact reduction countermeasures (Esteban et al., 2015). For example, multiple buildings in multiple locations were built in line with the Tsunami Vertical Building Evacuation strategies – constructing towers or buildings above the highest water levels within tsunami-prone areas (Fraser et al., 2013). Furthermore, considering the frequency of tsunamis, the Tohoku region invested approximately US$10bn in covering 300 km of coastal land with defence structures and breakwaters, according to national government technical standards and guidelines (Ranghieri and Ishiwatari, 2014). As a result, the Tohoku region can be seen as a top tsunami-prepared region globally, with seriously taken emergency preparedness and high disaster awareness (Esteban et al., 2015).

Nevertheless, Japan had yet to take advantage of a significant opportunity regarding its disaster preparedness. A combined earthquake prediction algorithm (M8-MSc), using a standard protocol to determine with at least a 70% success rate the possibility of earthquakes with > 8.0 magnitude, announced a forecast in 2001, almost 10 years before the 2011 Tohoku earthquake (Davis et al., 2012). Disregarding the forecast, Japan did not consider additional preparations. The Japanese experts were surprised by the Tohoku Earthquake, despite the M8-MSc forecast, as it failed to communicate the information to the earthquake prediction community. The miscommunication resulted in a missed opportunity to use vital time and information towards preparing for a large-scale disaster (Davis et al., 2012). Instead, Japan used the experience to improve its disaster management system. The focus shifted to improving emergency response policies and regulations and allocating roles and responsibilities locally and nationally (World Bank, 2012).

Adopted in 1961, the Disaster Countermeasures Basis (JDCB.), the act covers disaster planning, preparedness, emergency response and recovery phase measures and requires financial requirements. Additionally, it assumes three-level disaster management councils (Nazarov, 2011; Greer, 2012).

As illustrated in Figure 2, the Central Disaster Management Council represents the highest national level, followed by the Local Disaster Management and Municipal Disaster Councils at the prefectural levels (Nazarov, 2011). The national government is responsible for the overall emergency management strategy, coordination, funds provision and government budget adoption. In contrast, the local government coordinates the administrative and operational levels of diverse functions, such as providing adequate education, exercising emergency and safety drills and issuing warnings of upcoming disasters (Ranghieri and Ishiwatari, 2014).

The national government supervises the emergency response phase coordination processes and supplies local governments with critical information about the disaster. In exchange, the local government informs the national government about the extent of the damage (Nazarov, 2011). Figure 3 illustrates the organisation of disaster response mechanisms in Japan. Every local government (communities, villages, cities) is responsible for its local disaster plan. The national government becomes involved only when local governments are overwhelmed and unable to act accordingly. Highlighting responsibility on the lower levels, escalated only if capabilities of greater coordination are required (Greer, 2012).

Despite Japan’s general disaster preparedness, at the time of the Great Tohoku Disaster, a myriad of systems failed, and valuable time was lost. The aggregate of the earthquake, the tsunami and the nuclear power accident were unprecedented (Umeda, 2011).

4.2 Japan’s response to the disaster

Although the 3-min-long earthquake was one of the strongest ever recorded and the fourth largest in history, there were few casualties exclusively caused by the earthquake, thanks to the precise and strict government-adopted building codes (1923), issuing quake-resistant buildings (Naoi et al., 2012; Ishigaki et al., 2013; World Bank, 2012).

Additionally, to address the frequent tsunamis, the Tohoku region invested approximately US$10bn, shielding 300 km of coastal land with defence structures and breakwaters (Ranghieri and Ishiwatari, 2014). However, the 2011 Tohoku Tsunami was beyond expectations, collapsing more than 190 of the 300 km of coastal defences (World Bank, 2012). The 6–7 m tall waves following the massive earthquake far surpassed the predicted tsunami heights to be halted by the coastal defence (Holguín-Veras et al., 2014). Despite the exceeding heights, some Tohoku areas were successfully shielded by the coastal defences (Ranghieri and Ishiwatari, 2014). The coastal defences and heights across the Japanese east coast are visualised in Figure 4. Design heights in the upper country are influenced by historical data, while lower country designs lean on storm predictions. Even though the tsunami collapsed more than half of the barriers, it lost strength when reaching inland (World Bank, 2012). Local community preparedness played an important role, with the unexpectedly sizeable tsunami overpowering the coastal defence (Ranghieri and Ishiwatari, 2014; Holguín-Veras et al., 2014). Regularly partaking in emergency drills, the locals were well-prepared and responded quickly upon warning. Many lives were saved thanks to safe evacuation literacy (Ranghieri and Ishiwatari, 2014) exclusively.

Due to the earthquake detection system’s warning 30 s before its occurrence, 19 Japanese bullet trains were notified. Furthermore, the cutting-edge automatic system terminated trains’ electricity supplies, allowing trains driving at their maximum 270 km/h velocity to brake seconds before the earthquake, thereby saving thousands of passengers (Ranghieri and Ishiwatari, 2014; World Bank, 2012; Greer, 2012).

The installed seismic intensity meters and seismographs all over Japan issued warnings about the upcoming earthquake to railway operators, schools, factories, people’s cell phones and other general operators about 30 s before the earthquake. Despite the relatively short warning time for a 9.0 magnitude earthquake, there was enough time for hospital staff to halt medical procedures, for students to hide under desks at schools and universities and for bullet trains to pull brakes (Greer, 2012). Moreover, over 80% of the people believed that the early warnings helped them to survive the incoming disaster (Ranghieri and Ishiwatari, 2014; Rahman et al., 2021).

After partaking in numerous emergency drills, the residents were familiar with existing evacuation routes, allowing them to move quickly to higher grounds (Holguín-Veras et al., 2014). For example, about 230 people living near the East Sendai Expressway survived by rushing to the expressway as the tsunami approached. The expressway was approximately 4 km from the coast and 7–10 meters above sea level, successfully providing an evacuation route (Ranghieri and Ishiwatari, 2014).

Despite the relatively successful emergency preparedness, Japan did not anticipate a strong earthquake to be further superimposed by a tsunami, which is why local governments had difficulties responding to the situation. However, the national agencies were quick to approximate ends (Ranghieri and Ishiwatari, 2014). Furthermore, the national government financially supported the local governments based on a decision made two days following the disaster and authorised by the Act on Special Financial Aid of the Disaster Response Basic Law (Umeda, 2011).

Not to waste further time, the Japanese Government established a Reconstruction Agency shortly after the Tohoku disaster (Japanese Red Cross Society, 2013). Furthermore, just 1 h into the earthquake, the prime minister, supported by the Disaster Response Basic Law, entrenched the Emergency Disaster Response Headquarters to coordinate and oversee the execution of national and local government measures (Umeda, 2011).

The government immediately issued 540 aircraft, 60 vessels and 107,000 Japan Self Defense Forces (JSDF) police teams, as well as firefighters and emergency medical personnel, who rescued 90.000 victims, constituting approximately 70% of the rescues (Ranghieri and Ishiwatari, 2014; Umeda, 2011). In addition, the Japan Coast Guard (J.C.G.) took immediate action after the earthquake to partake in multiple emergency response activities, rescuing 360 victims and retrieving 302 bodies (Nazarov, 2011). Moreover, using helicopters and planes, the Ministry of Land, Infrastructure, Transportation and Tourism (MLITT) was able to inspect the affected roads and critical infrastructures and further donated approximately 2,000 closed-circuit television cameras (Holguín-Veras et al., 2014).

However, the coordination between national organisations, civil society, local governments, international assistance and volunteers could have been more functional, leading to confusion and duplication in relief efforts and multiple emergency shelters in the same affected areas (Ranghieri and Ishiwatari, 2014). In addition, a significant problem was the fuel shortage. Another problem occurred with the interruption of telecommunications, compromising real-time information exchange between stakeholders (World Bank, 2012). Nevertheless, the JSDF and non-governmental organisations coordinated the emergency food allocation to the shelters (Ranghieri and Ishiwatari, 2014).

In the Emergency Relief Phase, the Japanese Red Cross Society (JRCS) handed out relief goods to the affected locals, which consisted of blankets, emergency kits and sleeping sets, together with medical and mental help. Additionally, JRCS set up operation centres across the region (Japanese Red Cross Society, 2013). The emergency kits, loaded with the required goods (food, water, medicine, blankets and other necessities), were provided by the Japanese Government (Umeda, 2011).

Following the earthquake, the majority hurried to the provided public shelters, but there was a growing need for shelter alternatives (Tatsuki, 2012; Rahman et al., 2014). Resultantly, approximately 2,500 evacuation shelters were organised in the affected areas, with even more facilities located outside the region (World Bank, 2012). Additionally, more than 400,000 people were taking shelter in public facilities (schools, hotels) or hosted by friends and relatives outside the region (Japanese Red Cross Society, 2013). Moreover, approximately 5,500 people successfully took shelter in the designated Tsunami Vertical Evacuation Buildings (Fraser et al., 2013).

Before the disaster, workshops and engagements were organised, with local participation, to raise awareness of the vertical evacuation strategy (Fraser et al., 2013). The service stations, parking and rest areas along highways were also furnished into rescue operation bases, accommodated with toilets and running electricity (Ranghieri and Ishiwatari, 2014). Although many municipalities had storages loaded with necessary equipment and emergency/disaster preparedness kits, most were damaged or gone (Japanese Red Cross Society, 2013).

For emergency scenarios, a three-day food supply was stored at the Tohoku University Hospital. However, the supply barely sufficed for the patients, leaving the hospital staff without food and having to request a resupply from other hospitals (Parmar et al., 2017).

The exchange of information on events needed more real-time synchronisation. Nevertheless, the government collected information through social media and the internet, among other means, and the communication and information delivery were exceptionally well, ensuring that locals had realistic expectations for emergency relief (World Bank, 2012).

Thanks to the timely response of MLITT, the roads were cleared in less than seven days, almost all ports were functional again in only four days, and most of the water supply was running within thirty days. In contrast, the electricity was back much earlier, in less than a week (World Bank, 2012).

Initially, medical needs were given the highest priority, owing to reliance on local governments to provide food, water and sanitation. However, the latter was unable to act as expected due to the disaster’s significant impact, leaving many shelters short of essential supplies (Parmar et al., 2017).

The fixed-line and mobile telephone infrastructures sustained severe damage, severely impaired communication systems and leading to incongruencies in patient transport and transfer between hospitals and the JSDF (Ranghieri and Ishiwatari, 2014; Parmar et al., 2017). Social media and FM radio were essential in communicating information on areas to receive relief goods and general safety measures (Ranghieri and Ishiwatari, 2014).

Even though a nuclear disaster followed the earthquake, the nuclear plants were effectively protected from earthquakes, explaining why the nuclear reactors stopped operating immediately after the earthquake. Several UN agencies, like the World Health Organisation and the International Atomic Energy Agency, took action in response to the nuclear disaster (Norio et al., 2011). Japan requested international help as rescue teams from across Australia, New Zealand, South Korea, the UK and the USA responded. More countries provided their willingness to help than initially requested, compiling donations of over 1,300 tons of relief goods in the first two weeks (Norio et al., 2011). Emergency relief was offered from 163 countries and 43 international organisations (World Bank, 2012). Japan welcomed aid and workers from other countries to help with emergency relief (Greer, 2012). The USA alone provided approximately 16,000 military personnel for relief operations (Ranghieri and Ishiwatari, 2014). Kuwait donated $520m worth of crude oil (Japanese Red Cross Society, 2013).

To support the living of the affected Japanese people, numerous new laws were legislated. Financial grants were issued to victims who lost family members, were injured or disabled or whose houses sustained severe damage. The government also provided loans for treating injuries, house repairs and reconstruction. Furthermore, measures were taken to reduce taxes for victims. Unemployment benefits were issued to people with affected workplaces (Umeda, 2011). The recovery was estimated at 10 years, and approximately $250bn were allocated within its first half, leading to The World Bank’s rough estimate of the overall sustained damage being $235bn (Umeda, 2011; Park et al., 2013).

Even though Japan is considered one of the most disaster-prepared countries, it still suffered heavily from the Tohoku earthquake. Having preparedness to mitigate an earthquake or a tsunami without significant consequences, it could not have anticipated the tsunami and the nuclear catastrophe to follow the earthquake (Greer, 2012).

4.3 Evaluation of the emergency management in Japan in 2011

5.1 Pakistan

The I indicator – emergency planning for disaster response – suggested that Pakistan mainly responded to the emergency on an ad-hoc basis (Cochrane, 2008). No plans were devised prior to 2005 [38]. Therefore, some authors would suggest the first indicator be scaled at (1) minimal to non-existent (Gilissen et al., 2016).

The II and III indicators – arrangements for institutional learning and requirements of exercising emergency arrangements – suggested that only a limited number of persons (schoolteachers) were trained in emergency preparedness, and Pakistan did not have effective institutional disaster management (Cheema et al., 2016). These indicators would be scaled as (2) emerging.

The IV indicator – distribution within and between emergency actors – suggested that there were cooperation issues between participants and that different institutions were carrying out different tasks on an ad hoc basis, thereby similarly scaling at (1) minimal to non-existent.

The V indicator – community preparedness – suggests no local community involvement in emergency management and scales at (1) minimal to non-existent (Cheema et al., 2016).

The VI indicator – Provision of resources – points to Pakistan’s armed forces providing most of the required resources, albeit requesting additional help and support, scaling as (3) moderate (Reis, 2018; da Costa et al., 2014).

The VII indicator can also be scaled as (3) moderate, considering the sizable donations from other countries and international organisations and the numerous community organisations formed to support recovery (International Federation of Red Cross and Red Crescent Societies, Final Report, 2012; Terhune, 2006).

Overall, Pakistan scored 1.8 on average, between (1) minimal-to-absent and (2) emerging emergency planning.

5.2 Japan

Japan undertook different emergency planning measures for disaster response and integrated an emergency evacuation plan – The Disaster Risk Management – harnessing community involvement. In addition, the annual disaster preparedness education and emergency drills, distribution of responsibilities across three levels (national, prefecture and local) and support of the JDCB Act helped with preparations. Accordingly, the emergency disaster response planning – the I indicator – is scaled at (5) outstanding (Nazarov, 2011; Gilissen et al., 2016; Yamada, 2007).

Next, the II and III indicators revealed the local’s participation in annual emergency drills and engagement in Disaster Risk Management. Considering many people had ready-to-go emergency kits lying at home, the indicators are scaled at (4) significant (Ranghieri and Ishiwatari, 2014; World Bank, 2012; Greer, 2012).

Based on the JDCB Act, there was a clear division across the national, prefecture and local levels regarding the distribution of responsibilities – the IV indicator. Although the Reconstruction Agency and the Emergency Disaster Response headquarters were set up shortly after the disaster, the JCG, SDF, the JRCS, the MLITT and many other international stakeholders took part in the overall relief, albeit with poorly-functional coordination, thereby scaling the indicator at (1) minimal (Nazarov, 2011; Ranghieri and Ishiwatari, 2014; Japanese Red Cross Society, 2013; Norio et al., 2011; Umeda, 2011; Holguín-Veras et al., 2014).

The V indicator is scaled as (5) outstanding, given that community awareness of constant dangers from natural disasters was addressed correctly, emergency drills were held annually and emergency evacuation plans could be found in every city. Moreover, by partaking in emergency drills, the locals were aware of evacuation routes and the specific actions to be taken and possessed emergency kits prepared at homes (Nazarov, 2011; Ranghieri and Ishiwatari, 2014; World Bank, 2012; Greer, 2012; Yamada, 2007; Holguín-Veras et al., 2014).

The VI indicator of resources provision is scaled as (4) significant, as the national government spent approximately 7% of the annual budget on mitigation solutions. Additionally, the government issued numerous aircraft, vessels and the JSDF, together with the police, firefighters and medical teams. Furthermore, support was offered by the JCG, the MLITT and numerous foreign countries and international organisations (Nazarov, 2011; Norio et al., 2011; Greer, 2012).

The recovery-based activity arrangements – the VII indicator – is scaled as (5) outstanding, revealing how the national government supported the victims through financial grants, loans and tax reliefs, helping to reconstruct houses and promoting employment. Furthermore, the JDCB Act covered the recovery phase of disaster aftermath (Japanese Red Cross Society, 2013).

Japan’s Emergency Management indicators averaged (4), suggesting significant emergency planning efforts.