The forest sector in Ukraine has the potential to more than double its contribution to the national economy by increasing timber harvests and forest products in line with modern sustainable forest management practice. To this end, PROFOR provided analytical input to a forest sector reform process to introduce measures that: set harvesting levels in accordance with actual forest growth rates; reduce the level of "sanitary cutting" with a corresponding increase in final, regeneration and thinning volumes; and capture carbon trade finance to support reconstruction of forests in abandoned or poorly productive agricultural lands.

A Forest Sector Note, published in March 2006, described the status of Ukraine's forest sector and opportunities for development.

The forest sector in Ukraine has the potential to more than double its contribution to the national economy by increasing timber harvests and forest products in line with modern sustainable forest management practice. To this end, PROFOR provided analytical input to a forest sector reform process to introduce measures that: set harvesting levels in accordance with actual forest growth rates; reduce the level of "sanitary cutting" with a corresponding increase in final, regeneration and thinning volumes; and capture carbon trade finance to support reconstruction of forests in abandoned or poorly productive agricultural lands.

A Forest Sector Note, published in March 2006, described the status of Ukraine's forest sector and opportunities for development.

PROGRAM SUMMARY

The development objective of this project is to improve the understanding of forest-water interactions in the Congo Basin across World Bank project teams, client countries and climate scientists in Africa, and to strategize potential application to development programs and policies in the region. The analysis seeks to use emerging data and research to identify links between forest loss and degradation and water resources in the Congo Basin in the context of climate variability, covering impacts both locally and from a regional hydrologic cycle perspective.

CHALLENGE

The Congo Basin represents roughly 70% of Africa’s forest cover and is the second largest contiguous tropical forest in the world after the Amazon Basin. The Congo Basin provides many ecosystem services (carbon and non-carbon) but the forests are under pressure from economic activity such as logging, agriculture, energy, transport, and mining, and satellite-based data show that annual rates of deforestation have doubled since 1990 (World Bank 2013). Climate change is predicted to impact the Congo Basin significantly: since the 1950's, the region has experienced a 1°C increase in mean annual temperature (Niang et al. 2014; Fuller et al. 2018); by the 2080's, climate models suggest temperatures will increase 3 to 5°C and precipitation will decrease by 40% (Fotso-Nguemo 2016).

Understanding the impacts of forest loss within the Congo Basin and regionally is limited due to limited information on the linkages between forest loss and environmental services in the Congo Basin, particularly of the role of the forest in generating rainfall both locally and regionally. While much of the research related to the impact of tropical forests on rainfall and temperature has been undertaken in the Amazon, the few studies that have been conducted in the Congo Basin indicate that the region is a major source (17%) of moisture for West Africa (Cadet and Nnolli; Gong and Eltahir). One study estimates that the rain forests of West Africa may account for 30-40% of the annual rainfall in the Ethiopian highlands (Ellison 2018). Others suggest that the main source of rainfall in the Congo Basin is evaporation from the Great Lakes and that the Congo forest basin in turn generates much of the rainfall not only in the Congo basin (75-95%) (Brinkman 1983 in Job 1994) but also in the Sahel (van der Ent et al. 2010). At the same time, the drying trend in the Basin suggested by some scientific papers (Zhou et al. 2014) may impact this “water pump” service it provides. Such impacts are well described for the Amazon, where scientists have warned of an “Amazon dieback” or “savanization” of the Amazon (Vergara and Scholz 2011).

APPROACH

PROGRAM SUMMARY

The development objective of this project is to improve the understanding of forest-water interactions in the Congo Basin across World Bank project teams, client countries and climate scientists in Africa, and to strategize potential application to development programs and policies in the region. The analysis seeks to use emerging data and research to identify links between forest loss and degradation and water resources in the Congo Basin in the context of climate variability, covering impacts both locally and from a regional hydrologic cycle perspective.

CHALLENGE

The Congo Basin represents roughly 70% of Africa’s forest cover and is the second largest contiguous tropical forest in the world after the Amazon Basin. The Congo Basin provides many ecosystem services (carbon and non-carbon) but the forests are under pressure from economic activity such as logging, agriculture, energy, transport, and mining, and satellite-based data show that annual rates of deforestation have doubled since 1990 (World Bank 2013). Climate change is predicted to impact the Congo Basin significantly: since the 1950's, the region has experienced a 1°C increase in mean annual temperature (Niang et al. 2014; Fuller et al. 2018); by the 2080's, climate models suggest temperatures will increase 3 to 5°C and precipitation will decrease by 40% (Fotso-Nguemo 2016).

Understanding the impacts of forest loss within the Congo Basin and regionally is limited due to limited information on the linkages between forest loss and environmental services in the Congo Basin, particularly of the role of the forest in generating rainfall both locally and regionally. While much of the research related to the impact of tropical forests on rainfall and temperature has been undertaken in the Amazon, the few studies that have been conducted in the Congo Basin indicate that the region is a major source (17%) of moisture for West Africa (Cadet and Nnolli; Gong and Eltahir). One study estimates that the rain forests of West Africa may account for 30-40% of the annual rainfall in the Ethiopian highlands (Ellison 2018). Others suggest that the main source of rainfall in the Congo Basin is evaporation from the Great Lakes and that the Congo forest basin in turn generates much of the rainfall not only in the Congo basin (75-95%) (Brinkman 1983 in Job 1994) but also in the Sahel (van der Ent et al. 2010). At the same time, the drying trend in the Basin suggested by some scientific papers (Zhou et al. 2014) may impact this “water pump” service it provides. Such impacts are well described for the Amazon, where scientists have warned of an “Amazon dieback” or “savanization” of the Amazon (Vergara and Scholz 2011).

APPROACH

PROGRAM SUMMARY

The development objective of this project is to improve the understanding of forest-water interactions in the Congo Basin across World Bank project teams, client countries and climate scientists in Africa, and to strategize potential application to development programs and policies in the region. The analysis seeks to use emerging data and research to identify links between forest loss and degradation and water resources in the Congo Basin in the context of climate variability, covering impacts both locally and from a regional hydrologic cycle perspective.

CHALLENGE

The Congo Basin represents roughly 70% of Africa’s forest cover and is the second largest contiguous tropical forest in the world after the Amazon Basin. The Congo Basin provides many ecosystem services (carbon and non-carbon) but the forests are under pressure from economic activity such as logging, agriculture, energy, transport, and mining, and satellite-based data show that annual rates of deforestation have doubled since 1990 (World Bank 2013). Climate change is predicted to impact the Congo Basin significantly: since the 1950's, the region has experienced a 1°C increase in mean annual temperature (Niang et al. 2014; Fuller et al. 2018); by the 2080's, climate models suggest temperatures will increase 3 to 5°C and precipitation will decrease by 40% (Fotso-Nguemo 2016).

Understanding the impacts of forest loss within the Congo Basin and regionally is limited due to limited information on the linkages between forest loss and environmental services in the Congo Basin, particularly of the role of the forest in generating rainfall both locally and regionally. While much of the research related to the impact of tropical forests on rainfall and temperature has been undertaken in the Amazon, the few studies that have been conducted in the Congo Basin indicate that the region is a major source (17%) of moisture for West Africa (Cadet and Nnolli; Gong and Eltahir). One study estimates that the rain forests of West Africa may account for 30-40% of the annual rainfall in the Ethiopian highlands (Ellison 2018). Others suggest that the main source of rainfall in the Congo Basin is evaporation from the Great Lakes and that the Congo forest basin in turn generates much of the rainfall not only in the Congo basin (75-95%) (Brinkman 1983 in Job 1994) but also in the Sahel (van der Ent et al. 2010). At the same time, the drying trend in the Basin suggested by some scientific papers (Zhou et al. 2014) may impact this “water pump” service it provides. Such impacts are well described for the Amazon, where scientists have warned of an “Amazon dieback” or “savanization” of the Amazon (Vergara and Scholz 2011).

APPROACH

PROGRAM SUMMARY

The development objective of this project is to improve the understanding of forest-water interactions in the Congo Basin across World Bank project teams, client countries and climate scientists in Africa, and to strategize potential application to development programs and policies in the region. The analysis seeks to use emerging data and research to identify links between forest loss and degradation and water resources in the Congo Basin in the context of climate variability, covering impacts both locally and from a regional hydrologic cycle perspective.

CHALLENGE

The Congo Basin represents roughly 70% of Africa’s forest cover and is the second largest contiguous tropical forest in the world after the Amazon Basin. The Congo Basin provides many ecosystem services (carbon and non-carbon) but the forests are under pressure from economic activity such as logging, agriculture, energy, transport, and mining, and satellite-based data show that annual rates of deforestation have doubled since 1990 (World Bank 2013). Climate change is predicted to impact the Congo Basin significantly: since the 1950's, the region has experienced a 1°C increase in mean annual temperature (Niang et al. 2014; Fuller et al. 2018); by the 2080's, climate models suggest temperatures will increase 3 to 5°C and precipitation will decrease by 40% (Fotso-Nguemo 2016).

Understanding the impacts of forest loss within the Congo Basin and regionally is limited due to limited information on the linkages between forest loss and environmental services in the Congo Basin, particularly of the role of the forest in generating rainfall both locally and regionally. While much of the research related to the impact of tropical forests on rainfall and temperature has been undertaken in the Amazon, the few studies that have been conducted in the Congo Basin indicate that the region is a major source (17%) of moisture for West Africa (Cadet and Nnolli; Gong and Eltahir). One study estimates that the rain forests of West Africa may account for 30-40% of the annual rainfall in the Ethiopian highlands (Ellison 2018). Others suggest that the main source of rainfall in the Congo Basin is evaporation from the Great Lakes and that the Congo forest basin in turn generates much of the rainfall not only in the Congo basin (75-95%) (Brinkman 1983 in Job 1994) but also in the Sahel (van der Ent et al. 2010). At the same time, the drying trend in the Basin suggested by some scientific papers (Zhou et al. 2014) may impact this “water pump” service it provides. Such impacts are well described for the Amazon, where scientists have warned of an “Amazon dieback” or “savanization” of the Amazon (Vergara and Scholz 2011).

APPROACH

PROGRAM SUMMARY

The development objective of this project is to improve the understanding of forest-water interactions in the Congo Basin across World Bank project teams, client countries and climate scientists in Africa, and to strategize potential application to development programs and policies in the region. The analysis seeks to use emerging data and research to identify links between forest loss and degradation and water resources in the Congo Basin in the context of climate variability, covering impacts both locally and from a regional hydrologic cycle perspective.

CHALLENGE

The Congo Basin represents roughly 70% of Africa’s forest cover and is the second largest contiguous tropical forest in the world after the Amazon Basin. The Congo Basin provides many ecosystem services (carbon and non-carbon) but the forests are under pressure from economic activity such as logging, agriculture, energy, transport, and mining, and satellite-based data show that annual rates of deforestation have doubled since 1990 (World Bank 2013). Climate change is predicted to impact the Congo Basin significantly: since the 1950's, the region has experienced a 1°C increase in mean annual temperature (Niang et al. 2014; Fuller et al. 2018); by the 2080's, climate models suggest temperatures will increase 3 to 5°C and precipitation will decrease by 40% (Fotso-Nguemo 2016).

Understanding the impacts of forest loss within the Congo Basin and regionally is limited due to limited information on the linkages between forest loss and environmental services in the Congo Basin, particularly of the role of the forest in generating rainfall both locally and regionally. While much of the research related to the impact of tropical forests on rainfall and temperature has been undertaken in the Amazon, the few studies that have been conducted in the Congo Basin indicate that the region is a major source (17%) of moisture for West Africa (Cadet and Nnolli; Gong and Eltahir). One study estimates that the rain forests of West Africa may account for 30-40% of the annual rainfall in the Ethiopian highlands (Ellison 2018). Others suggest that the main source of rainfall in the Congo Basin is evaporation from the Great Lakes and that the Congo forest basin in turn generates much of the rainfall not only in the Congo basin (75-95%) (Brinkman 1983 in Job 1994) but also in the Sahel (van der Ent et al. 2010). At the same time, the drying trend in the Basin suggested by some scientific papers (Zhou et al. 2014) may impact this “water pump” service it provides. Such impacts are well described for the Amazon, where scientists have warned of an “Amazon dieback” or “savanization” of the Amazon (Vergara and Scholz 2011).

APPROACH

PROGRAM SUMMARY

The development objective of this project is to improve the understanding of forest-water interactions in the Congo Basin across World Bank project teams, client countries and climate scientists in Africa, and to strategize potential application to development programs and policies in the region. The analysis seeks to use emerging data and research to identify links between forest loss and degradation and water resources in the Congo Basin in the context of climate variability, covering impacts both locally and from a regional hydrologic cycle perspective.

CHALLENGE

The Congo Basin represents roughly 70% of Africa’s forest cover and is the second largest contiguous tropical forest in the world after the Amazon Basin. The Congo Basin provides many ecosystem services (carbon and non-carbon) but the forests are under pressure from economic activity such as logging, agriculture, energy, transport, and mining, and satellite-based data show that annual rates of deforestation have doubled since 1990 (World Bank 2013). Climate change is predicted to impact the Congo Basin significantly: since the 1950's, the region has experienced a 1°C increase in mean annual temperature (Niang et al. 2014; Fuller et al. 2018); by the 2080's, climate models suggest temperatures will increase 3 to 5°C and precipitation will decrease by 40% (Fotso-Nguemo 2016).

Understanding the impacts of forest loss within the Congo Basin and regionally is limited due to limited information on the linkages between forest loss and environmental services in the Congo Basin, particularly of the role of the forest in generating rainfall both locally and regionally. While much of the research related to the impact of tropical forests on rainfall and temperature has been undertaken in the Amazon, the few studies that have been conducted in the Congo Basin indicate that the region is a major source (17%) of moisture for West Africa (Cadet and Nnolli; Gong and Eltahir). One study estimates that the rain forests of West Africa may account for 30-40% of the annual rainfall in the Ethiopian highlands (Ellison 2018). Others suggest that the main source of rainfall in the Congo Basin is evaporation from the Great Lakes and that the Congo forest basin in turn generates much of the rainfall not only in the Congo basin (75-95%) (Brinkman 1983 in Job 1994) but also in the Sahel (van der Ent et al. 2010). At the same time, the drying trend in the Basin suggested by some scientific papers (Zhou et al. 2014) may impact this “water pump” service it provides. Such impacts are well described for the Amazon, where scientists have warned of an “Amazon dieback” or “savanization” of the Amazon (Vergara and Scholz 2011).

APPROACH

PROGRAM SUMMARY

The development objective of this project is to improve the understanding of forest-water interactions in the Congo Basin across World Bank project teams, client countries and climate scientists in Africa, and to strategize potential application to development programs and policies in the region. The analysis seeks to use emerging data and research to identify links between forest loss and degradation and water resources in the Congo Basin in the context of climate variability, covering impacts both locally and from a regional hydrologic cycle perspective.

CHALLENGE

The Congo Basin represents roughly 70% of Africa’s forest cover and is the second largest contiguous tropical forest in the world after the Amazon Basin. The Congo Basin provides many ecosystem services (carbon and non-carbon) but the forests are under pressure from economic activity such as logging, agriculture, energy, transport, and mining, and satellite-based data show that annual rates of deforestation have doubled since 1990 (World Bank 2013). Climate change is predicted to impact the Congo Basin significantly: since the 1950's, the region has experienced a 1°C increase in mean annual temperature (Niang et al. 2014; Fuller et al. 2018); by the 2080's, climate models suggest temperatures will increase 3 to 5°C and precipitation will decrease by 40% (Fotso-Nguemo 2016).

Understanding the impacts of forest loss within the Congo Basin and regionally is limited due to limited information on the linkages between forest loss and environmental services in the Congo Basin, particularly of the role of the forest in generating rainfall both locally and regionally. While much of the research related to the impact of tropical forests on rainfall and temperature has been undertaken in the Amazon, the few studies that have been conducted in the Congo Basin indicate that the region is a major source (17%) of moisture for West Africa (Cadet and Nnolli; Gong and Eltahir). One study estimates that the rain forests of West Africa may account for 30-40% of the annual rainfall in the Ethiopian highlands (Ellison 2018). Others suggest that the main source of rainfall in the Congo Basin is evaporation from the Great Lakes and that the Congo forest basin in turn generates much of the rainfall not only in the Congo basin (75-95%) (Brinkman 1983 in Job 1994) but also in the Sahel (van der Ent et al. 2010). At the same time, the drying trend in the Basin suggested by some scientific papers (Zhou et al. 2014) may impact this “water pump” service it provides. Such impacts are well described for the Amazon, where scientists have warned of an “Amazon dieback” or “savanization” of the Amazon (Vergara and Scholz 2011).

APPROACH

Program Summary

The development objective of this activity is to increase knowledge and awareness about the impacts of forest fires in a changing climate and identify effective response strategies and actions to build the resilience of forests and communities.

Challenge

Forest fires degrade forest ecosystems and impair on their capacity to serve global development and poverty reduction objectives. Substantial and rapid shifts are projected for future fire activity across vast portions of the globe, including tropical and subtropical regions. Projections suggest that wildfires will become so frequent within this century that it will reach a “new normal.” Therefore, it is important to develop a better understanding of the interactions between climate change and forest fires in terms of their scale and intensity and identify forest management options for increased resilience. This activity aims to contribute toward filling this knowledge gap by taking stock of the state of knowledge on the key issues. Several studies have already been conducted by PROFOR and other teams at the Bank to highlight the importance of preventing and managing forest fires. This activity will build on the previous work and deepen the understanding of these impacts and the type and scale of investments required to tackle this challenge.

Approach

As the main activity, a Global Expert Workshop on Forest Fires and Climate Change would be held at the International Union of Forest Research Organizations (IUFRO) headquarters in June 2018 in Vienna, Austria. The expert workshop would be co-hosted by IUFRO and PROFOR. It would bring together leading scientific experts; government representatives from key countries in East Asia, Africa, and Latin America; and representatives from World Bank global practices and regional units.

The expert workshop would discuss (i) the spectrum of forest fire types and their contributions to global greenhouse gas emissions; (ii) future climate change scenarios and implications for forest fire as well as related environmental, social, and economic impacts and vulnerabilities; and (iii) options for adaptation with particular emphasis on forest landscape restoration as a forest-smart solution for increasing resilience in the face of climate change. The expert workshop would also be informed of relevant findings of the Global Forest Expert Panel (GFEP) scientific assessment on forests and water, coordinated by IUFRO on behalf of the Collaborative Partnership on Forests.

The expert workshop would result in an issue paper that comprised all the information presented during the workshop, including the main findings and conclusions, as well as a set of key messages for decision makers. The expert workshop would also identify limitations in current knowledge and outline potential future activities.

Results

This project has been completed.  The Global Expert Workshop on Forest Fires and Climate Change was conducted July 2-4 in Vienna, Austria. The three-day workshop brought together 32 scientists and governmental experts from around the globe and World Bank representatives to discuss the complex forest fire–climate change–restoration nexus.

The Occasional Paper 32 - Global Fire Challenges in a Warming World, Summary Note of a Global Expert Workshop on Fire and Climate Change, affirmed that the warming climate contributes significantly to the increase in the frequency and intensity of uncontrolled forest fires, thereby further degrading forest ecosystems and impairing their capacity to produce the forest goods and services that play an important part in global development and poverty reduction objectives. Climate change, particularly hotter and drier seasons, combined with environmental and demographic changes are exceeding traditional fire management approaches’ capacity to cope and are economically unsustainable.

The expert group concluded that fire and climate-related weather changes are strongly linked, leading to more severe fire events, and that there is a need to prepare for a “new normal” in which fires will occur outside the traditional fire seasons and risk zones, including agricultural areas. Government strategies will need to take on a different approach to effectively manage forest landscapes because this trend will only get worse.

The solution lies increasingly in more holistic land management and governance approaches including more active investments in fire prevention measures, fire-smart economic land uses, better informed and connected fire information and early warning systems, and community-based education, training, and mitigation activities in addition to traditional suppression measures.

Where tropical forests or peatlands already suffered substantial alterations, the workshop concluded that there is a need to think beyond those solutions. Restoration of ecological functions of degraded forests and peatlands, investment in fire-free perennial economic solutions in risk areas and strategic economic land uses will need to be an integral part of interventions.

Some of the presentations at the workshop, include knowledge that has informed, is informing, and will continue to inform policies, projects/ programs and data gathering/information/modelling globally.