Greenhouse gas observation network design for Africa

Nickless, Alecia; Scholes, Robert J.; Vermeulen, Alex; Beck, Johannes; López-Ballesteros, Ana; Ardö, Jonas; Karstens, Ute; Rigby, Matthew; Kasurinen, Ville; Pantazatou, Karolina; Jorch, Veronika; Kutsch, Werner L.

doi:10.1080/16000889.2020.1824486

Cited by 13 publications

(10 citation statements)

References 79 publications

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“…Thus, the SEACRIFOG consortium ran optimization algorithms coupled to top-down inversion techniques to identify the best locations for new observations, such that they reduced the uncertainty in the GHG budget of Africa by the greatest amount (Fig. 3, Nickless et al 2020). In order to minimise the costs, various technologies that meet the required standards were considered for each of the essential variables (López-Ballesteros et al 2018Beck et al 2019).…”

Section: Which Observations Should Be Made Where and What Are The Costs?mentioning

confidence: 99%

“…The analysis considered each of the three major GHGs separately and provided a solution which optimised across all three gases. The largest amount of uncertainty in the total African GHG budget was due to biogenic GHG emissions, and therefore sites were located near the regions of greatest biogenic activity (Nickless et al 2020), predominantly tropical rainforest, subtropical and tropical dry forest and grass savanna biomes. The regions/countries which were most frequently included in the network design under various configurations included Angola, the Congo basin and Botswana.…”

Section: Which Observations Should Be Made Where and What Are The Costs?mentioning

confidence: 99%

“…This emphasizes the need for an integrated network to reach higher levels of uncertainty reduction. It would include atmospheric measurements sites, such as proposed in the network design study by Nickless et al (2020), as well as satellite observations, and ecosystem measurements of GHG fluxes which can improve models predicting biogenic GHG fluxes in African ecosystems. Furthermore, it is important to note that some of the tropical African stations that were used in the study are already active.…”

Section: Which Observations Should Be Made Where and What Are The Costs?mentioning

confidence: 99%

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Opportunities for an African greenhouse gas observation system

et al. 2021

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Global population projections foresee the biggest increase to occur in Africa with most of the available uncultivated land to ensure food security remaining on the continent. Simultaneously, greenhouse gas emissions are expected to rise due to ongoing land use change, industrialisation, and transport amongst other reasons with Africa becoming a major emitter of greenhouse gases globally. However, distinct knowledge on greenhouse gas emissions sources and sinks as well as their variability remains largely unknown caused by its vast size and diversity and an according lack of observations across the continent. Thus, an environmental research infrastructure—as being setup in other regions—is more needed than ever. Here, we present the results of a design study that developed a blueprint for establishing such an environmental research infrastructure in Africa. The blueprint comprises an inventory of already existing observations, the spatial disaggregation of locations that will enable to reduce the uncertainty in climate forcing’s in Africa and globally as well as an overall estimated cost for such an endeavour of about 550 M€ over the next 30 years. We further highlight the importance of the development of an e-infrastructure, the necessity for capacity development and the inclusion of all stakeholders to ensure African ownership.

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Section: Which Observations Should Be Made Where and What Are The Costs?mentioning

confidence: 99%

Section: Which Observations Should Be Made Where and What Are The Costs?mentioning

confidence: 99%

Section: Which Observations Should Be Made Where and What Are The Costs?mentioning

confidence: 99%

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Opportunities for an African greenhouse gas observation system

et al. 2021

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“…A simple parameter measured in a place (e.g., CO2 concentration, decomposition of organic matter) may not be useful to understand complexity of GHG dynamics. However, if the parameter can be measured in different places at the same time the potential of the data in term of contribution to scientific advance can be far beyond a simple parameter itself (Nickless et al, 2020;Morawska et al, 2018;Chandler et al, 2017;Keuskamp et al, 2013). The integration on multiple measurements can also fill the gap of each approach and also can create synergies.…”

Section: ) Networking Based Researchmentioning

confidence: 99%

Reviews and syntheses: Enhancing research and monitoring of land-to-atmosphere greenhouse gases exchange in developing countries

Kim

Bond‐Lamberty

Ryu

et al. 2021

Preprint

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Abstract. Greenhouse gas (GHG) research has traditionally required data collection and analysis using advanced and often expensive instruments, complex and proprietary software, and skilled technicians. Partly as a result, relatively little GHG research has been conducted in resource-constrained developing countries and a critical data gap exists in these regions. At the same time, these are the same countries and regions in which climate-change impacts will likely be strongest, and in which major science uncertainties are centered, given the importance of dryland and tropical systems to the global carbon cycle and climate. Increasingly, scientific communities have adopted appropriate technology and approach (AT&A) for GHG research, including low-cost and low-technology instruments, open source software and data, and participatory and networking-based research approaches. Adopting AT&A can mean acquiring data with fewer technical constraints and lower economic burden, and is thus a strategy for enhancing GHG research in developing countries. However, AT&A can be characterized by higher uncertainties; these can often be mitigated by carefully designing experimental set-up, providing clear protocols for data collection, and monitoring and validating the quality of obtained data. For implementing this approach in GHG research of developing countries, first, it is necessary to recognize the scientific and moral importance of AT&A. At the same time, new AT&A techniques should be identified and further developed. Finally, these processes should be promoted through training local staff and encouraged for wide use and further innovation in developing countries.

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“…4). As already said, low-cost technology can see the issue of low accuracy and precision (Arzoumanian et al, 2019;Marley et al, 2019) and it can be partially solved by increasing sampling replication and frequency combining them with participatory and networking based research approaches (Peltier, 2021;Riddick al., 2020;Nickless et al, 2020;Morawska et al, 2018). Beside these technical aspects, through the integration, local actors take on expanded roles within the 350 projects (e.g.…”

Section: Figure 4: Major Components Of Appropriate Technology and Approach (Atanda) And Its Benefits For Enhancing Carbon And Greenhouse mentioning

confidence: 99%

Ideas and Perspectives: Enhancing research and monitoring of carbon pools and land-to-atmosphere greenhouse gases exchange in developing countries

Kim

Bond‐Lamberty

Ryu

et al. 2021

Preprint

View full text Add to dashboard Cite

Abstract. Carbon (C) and greenhouse gas (GHG) research has traditionally required data collection and analysis using advanced and often expensive instruments, complex and proprietary software, and skilled technicians. Partly as a result, relatively little C and GHG research has been conducted in resource-constrained developing countries. At the same time, these are the same countries and regions in which climate-change impacts will likely be strongest, and in which major science uncertainties are centred, given the importance of dryland and tropical systems to the global C cycle. Increasingly, scientific communities have adopted appropriate technology and approach (AT&A) for C and GHG research, which focuses on low-cost and low-technology instruments, open source software and data, and participatory and networking-based research approaches. Adopting AT&A can mean acquiring data with fewer technical constraints and lower economic burden and is thus a strategy for enhancing C and GHG research in developing countries. However, AT&A can be characterized by higher uncertainties; these can often be mitigated by carefully designing experiments, providing clear protocols for data collection, and monitoring and validating the quality of obtained data. For implementing this approach in developing countries, it is first necessary to recognize the scientific and moral importance of AT&A. At the same time, new AT&A techniques should be identified and further developed. All these processes should be promoted in collaboration with local researchers and through training local staff and encouraged for wide use and further innovation in developing countries.

show abstract

Greenhouse gas observation network design for Africa

Cited by 13 publications

References 79 publications

Opportunities for an African greenhouse gas observation system

Opportunities for an African greenhouse gas observation system

Reviews and syntheses: Enhancing research and monitoring of land-to-atmosphere greenhouse gases exchange in developing countries

Ideas and Perspectives: Enhancing research and monitoring of carbon pools and land-to-atmosphere greenhouse gases exchange in developing countries

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