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Countries | Mauritius

WHO / UNFCCC Climate & Health Profile 2021

National Context

Country Background

Mauritius is an island state located in the Indian Ocean in Southern Africa. The climate is tropical, consisting of dry winters and humid summers. Mauritius’ terrain consists of a central plateau surrounded by mountains, with the main island almost completely surrounded by coral reefs (1). Whilst absolute poverty is low in Mauritius, income inequality is an issue which could hinder socio-economic development (2).

Mauritius is considered a particularly vulnerable nation to the impacts of climate change (3,4). These impacts include: rising temperatures, altered precipitation patterns, sea level rise, coastal erosion, and increased extreme weather events. Such changes present health risks to the population of Mauritius, including increased risk of vector-borne diseases, noncommunicable diseases, food insecurity and the destruction of marine habitats, with associated negative effects for human health (4).

Climate change adaptation and mitigation are top priorities of the Mauritius Government’s Programme of 2015–2019, and include legislation such as the National Disaster Risk Reduction and Management Act (2016) and the National Climate Change Adaptation Policy Framework (2012) (4). Health sector adaptation is also recognized as a top adaptation priority in Mauritius’ Nationally Determined Contribution (NDC) to the UNFCC, to enable the country to cope with its growing population and additional climate-related health burdens (5).

Climate Hazards Relevant for Health

Climate Hazard Projections for Mauritius

Country-specific projections are outlined up to the year 2100 for climate hazards under a ‘business as usual’ high emissions scenario compared to projections under a ‘two-degree’ scenario with rapidly decreasing global emissions (see Figures 1–5). The climate model projections given below present climate hazards under a high emissions scenario, Representative Concentration Pathway 8.5 (RCP8.5 – in orange) and a low emissions scenario (RCP2.6 – in green). 1 1Model projections are from CMIP5 for RCP8.5 (high emissions) and RCP2.6 (low emissions). Model anomalies are added to the historical mean and smoothed.

The text describes the projected changes averaged across about 20 global climate models (thick line). The figures 2 2Analysis by the Climatic Research Unit, University of East Anglia, 2018. also show each model individually as well as the 90% model range (shaded) as a measure of uncertainty and the annual and smoothed observed record (in blue).3 3Observed historical record of mean temperature is from CRU-TSv3.26 and total precipitation is from GPCC. Observed historical records of extremes are from JRA55 for temperature and from GPCC-FDD for precipitation. In the following text the present-day baseline refers to the 30-year average for 1981–2010 and the end-of-century refers to the 30-year average for 2071–2100.

Modelling uncertainties associated with the relatively coarse spatial scale of the models compared with that of small island States are not explicitly represented. There are also issues associated with the availability and representativeness of observed data for such locations.

FIGURE 1: Mean annual temperature, 1900–2100

Under a high emissions scenario, the mean annual temperature is projected to rise by about 2.8°C on average by the end-of-century (i.e. 2071–2100 compared with 1981–2010). If emissions decrease rapidly, the temperature rise is limited to about 0.8°C. 

FIGURE 2: Total annual precipitation, 1900–2100

Total annual precipitation is projected to remain almost unchanged on average under a high emissions scenario, although the uncertainty range is large (-22% to +18%). If emissions decrease rapidly, there is little projected change on average, with an uncertainty range of -9% to +9%.

FIGURE 3: Percentage of hot days (‘heat stress’), 1900–2100

The percentage of hot days4 4A ‘hot day’ (‘hot night’) is a day when maximum (minimum) temperature exceeds the 90th percentile threshold for that time of the year.   is projected to increase substantially from about 15% of all observed days on average in 1981–2010 (10% in 1961–1990). Under a high emissions scenario, almost 100% of days on average are defined as ‘hot’ by the end-of-century. If emissions decrease rapidly, about 65% of days on average are ‘hot’. Note that the models tend to overestimate the observed increase in hot days (by about 4% on average for 1981–2010). Similar increases are seen in hot nights (not shown). 

FIGURE 4: Contribution to total annual rainfall from very wet days (‘extreme rainfall’ and ‘flood risk’), 1900–2100

Under a high emissions scenario, the proportion of total annual rainfall from very wet days5 5The proportion (%) of annual rainfall totals that falls during very wet days, defined as days that are at least as wet as the historically 5% wettest of all days (about 32% for 1981–2010) could increase a little by the end-of-century (to about 35% of days on average with an uncertainty range of about 12% to 57%), with less change if emissions decrease rapidly. Total annual rainfall shows little projected change (see Figure 2).

FIGURE 5: Standardized Precipitation Index (‘drought’), 1900–2100

The Standardized Precipitation Index (SPI) is a widely used drought index which expresses rainfall deficits/excesses over timescales ranging from 1 to 36 months (here 12 months, i.e. SPI12).6 6SPI is unitless but can be used to categorize different severities of drought (wet): above +2.0 extremely wet; +2.0 to +1.5 severely wet; +1.5 to +1.0 moderately wet; +1.0 to +0.5 slightly wet; +0.5 to -0.5 near normal conditions; -0.5 to -1.0 slight drought; -1.0 to -1.5 moderate drought; -1.5 to -2.0 severe drought; below -2.0 extreme drought. It shows how at the same time extremely dry and extremely wet conditions, relative to the average local conditions, change in frequency and/or intensity. 

SPI12 values show little projected change from an average of about -0.4, indicating little change on average in the frequency and/or intensity of wet episodes and drought events. Year-to-year variability remains large with both wet and dry episodes of varying intensity continuing to occur into the future.

Tropical cyclones

It is anticipated that the total number of tropical cyclones may decrease towards the end of the century. However, it is likely that human-induced warming will make cyclones more intense (an increase in wind speed of 2–11% for a mid-range scenario (i.e. RCP4.5 which lies between RCP2.6 and RCP8.5 – shown on pages 4–5) or about 5% for 2ºC global warming). Projections suggest that the most intense events (category 4 and 5) will become more frequent (although these projections are particularly sensitive to the spatial resolution of the models). It is also likely that average precipitation rates within 100 km of the storm centre will increase – by a maximum of about 10% per degree of warming. Such increases in rainfall rate would be exacerbated if tropical cyclone translation speeds continue to slow (6–13)..7 7Information and understanding about tropical cyclones (including hurricane and typhoons) from observations, theory and climate models have improved in the past few years. It is difficult to make robust projections for specific ocean basins or for changes in storm tracks. Presented here is a synthesis of the expected changes at the global scale.

Sea level rise

Sea level rise is one of the most significant threats to low-lying areas on small islands and atolls. Research indicates that rates of global mean sea level rise are almost certainly accelerating as a result of climate change. The relatively long response times to global warming mean that sea level will continue to rise for a considerable time after any reduction in emissions. The continuing rise in sea level means that higher storm surge levels can be expected regardless of any other changes in the characteristics of storm surges. 

Potential impacts of sea level rise include:

  • Coastal erosion
  • Ecosystem disruption
  • Higher storm surges
  • Population displacement
  • Water contamination and disruption
  • Mental health

Health Impacts of Climate Change

National Response

Health System Capacity and Adaptation: Monitoring Progress

The following section measures progress in the health sector in responding to climate threats based on country reported data collected in the 2021 WHO Health and Climate Change Country Survey (21).

Governance And Leadership

National Planning for Health and Climate Change

Question questioncategory question Answer
Has a national health and climate change strategy or plan been developed ? NO
Are the health co-benefits of climate change mitigation action considered in the strategy/plan? N/A
Level of implementation of the strategy/plan? N/A
Portion of estimated costs to implement the strategy/plan covered in the health budget N/A
Are health adaptation priorities identified in the strategy/plan? N/A
Notes
Table Legend: Yes (√) / No (X) / Unknown/Not applicable (N/A).
Definition: In this context, a national strategy or plan is a broad term that includes national health and climate strategies as well as the health component of national adaptation plans (H-NAPs).

Intersectoral Collaboration to Address Climate Change

Is there an agreement in place between the ministry of health and this sector which defines specific roles and responsibilities in relation to links between health and climate change policy?

Question questioncategory question Answer
Is there an agreement in place between the ministry of health and this sector which defines specific roles and responsibilities in relation to links between health and climate change policy? Transportation NO
Is there an agreement in place between the ministry of health and this sector which defines specific roles and responsibilities in relation to links between health and climate change policy? Electricity generation NO
Is there an agreement in place between the ministry of health and this sector which defines specific roles and responsibilities in relation to links between health and climate change policy? Household energy NO
Is there an agreement in place between the ministry of health and this sector which defines specific roles and responsibilities in relation to links between health and climate change policy? Agriculture NO
Is there an agreement in place between the ministry of health and this sector which defines specific roles and responsibilities in relation to links between health and climate change policy? Social services YES
Is there an agreement in place between the ministry of health and this sector which defines specific roles and responsibilities in relation to links between health and climate change policy? Water, Sanitation & Waste-water management YES
Notes
Table Legend: Yes (√) / No (X) / Unknown/Not applicable (N/A)
Yes = Specific roles and responsibilities between the national health authority and the sector indicated are defined in the agreement.

Vulnerability and Adaptation Assessments for Health

Question questioncategory question Answer
Has an assessment of health vulnerability and impacts of climate change been conducted at a national level? NO
→ Level of influence of the assessment findings on policy prioritization to address the health risks of climate change N/A
→ Level of influence of the assessment findings on human and financial resource allocation to address the health risks of climate change N/A
Notes
Table Legend:
Question 1: Yes (√) / No (X) / Unknown/Not applicable (N/A)
Questions 2 and 3: None, Minimal, Somewhat, Strong

Climate-sensitive diseases and health outcomes qid Health surveillance system is in place (a) Health surveillance system includes meteorological information (b)
Thermal stress (e.g. heat waves) 22111 NO NO
Vector-borne diseases 22121 YES YES
Foodborne diseases 22131 YES YES
Waterborne diseases 22141 YES YES
Nutrition (e.g. malnutrition associated with extreme-climatic events) 22151 NO
Injuries (e.g. physical injuries or drowning in extreme weather events) 22161 Unknown Unknown
Mental health and well-being 22171 NO NO
Airborne and respiratory diseases 22181 YES
Notes
Table Legend: Yes (√) / No (X) / Unknown/Not applicable (N/A)
(a) A positive response indicates that the health surveillance system is in place, it will identify changing health risks or impacts AND it will trigger early action.
(b) Meteorological information refers to either short-term weather information, seasonal climate information OR long-term climate information

Climate hazard qid Health early warning system (HEWS) in place? Health sector response plan in place? Health sector response plan includes meteorological information?
Heat waves 23111 NO Unknown NO
Storms (e.g. hurricanes, monsoons, typhoons) 23131 YES YES YES
Flooding 23141 YES YES YES
Drought 23161 NO NO NO
Air quality (e.g. particulate matter, ozone levels) 23171
Notes
Table Legend: Yes (√) / No (X) / Unknown/Not applicable (N/A)

Human Resource Capacity

Question questioncategory question Answer
Is there a national curriculum developed to train health personnel on the health impacts of climate change? NO
Does your human resource capacity as measured through the International Health Regulations Monitoring Framework (IHR) adequately consider the human resource requirements to respond to climate-related events? NO
Notes
Table Legend: Yes (√) / No (X) / Unknown/Not applicable (N/A)

Health Care Facilities, Infrastructure and Technology

Question questioncategory question Answer
Has there been a national assessment of the climate resilience of health infrastructure and technology?
Have measures been taken to increase the climate resilience of health infrastructure and technology?
Is there a national initiative/programme in place to promote the use of low-carbon, energy-efficient, sustainable technologies in the health sector?
Notes:
Table Legend: Yes (√) / No (X) / Unknown/Not applicable (N/A)

Finance

Question questioncategory question Answer
Is your government currently accessing international funds to support climate change and health work? NO
Notes:
Table Legend: Yes (√) / No (X) / Unknown/Not applicable (N/A)

Funding Challenges

Greatest challenges faced in accessing international climate funds

Question questioncategory question Answer
Greatest challenges faced in accessing international climate funds Lack of information on the opportunities
Greatest challenges faced in accessing international climate funds Lack of country eligibility
Greatest challenges faced in accessing international climate funds Lack of connection by health actors to climate change processes
Greatest challenges faced in accessing international climate funds Lack of capacity to prepare country proposals
Greatest challenges faced in accessing international climate funds Lack of success in submitted applications
Greatest challenges faced in accessing international climate funds None (no challenges/challenges were minimal)
Greatest challenges faced in accessing international climate funds Not applicable
Greatest challenges faced in accessing international climate funds Other (please specify)
Notes:
Table Legend: Yes (√) / No (X) / Unknown/Not applicable (N/A)

Opportunities for Action

Develop and Implement a Climate Change and Health Strategic Action Plan for Mauritius

Develop a national health and climate change plan. Its full implementation will be supported by ensuring that adaptation priorities are specified; health co-benefits from mitigation and adaptation measures are considered; necessary budget requirements are allocated; and regular monitoring and review of progress.

Conduct a Health Vulnerability, Impacts and Adaptation Assessment

Conduct a national assessment of climate change impacts, vulnerability and adaptation for health. Ensure that results of the assessment are used for policy prioritization and the allocation of human and financial resources in the health sector.

Address Barriers to Accessing International Climate Change Finance to Support Health Adaptation

No international funding is currently being accessed to aid with health and climate change initiatives. Additional funding would help to further the implementation of policies and to strengthen health system resilience to climate change.

Build Climate-resilient and Environmentally Sustainable Health Care Facilities

Measures can be taken to prevent the potentially devastating impacts of climate change on health service provision, including: conducting hazard assessments, climate-informed planning and costing, strengthening structural safety, contingency planning for essential systems (electricity, heating, cooling, ventilation, water supply, sanitation services, waste management and communications). A commitment towards low-emission, sustainable practices to improve system stability, promote a healing environment and to mitigate climate change impacts can also be taken.

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