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dc.contributor.authorSummerauer, L.
dc.contributor.authorBaumann, P.
dc.contributor.authorRamirez-Lopez, L.
dc.contributor.authorBarthel, M.
dc.contributor.authorBauters, M.
dc.contributor.authorBukombe, B.
dc.contributor.authorReichenbach, M.
dc.contributor.authorBoeckx, P.
dc.contributor.authorKearsley, E.
dc.contributor.authorVan Oost, K.
dc.contributor.authorVanlauwe, B.
dc.contributor.authorChiragaga, D.
dc.contributor.authorHeri-Kazi, A.
dc.contributor.authorMoonen, P.
dc.contributor.authorSila, A.
dc.contributor.authorShepherd, K.
dc.contributor.authorMujinya, B.B.
dc.contributor.authorVan Ranst, E.
dc.contributor.authorBaert, G.
dc.contributor.authorDoetterl, S.
dc.contributor.authorSix, J.
dc.date.accessioned2021-11-26T09:58:02Z
dc.date.available2021-11-26T09:58:02Z
dc.date.issued2021
dc.identifier.citationSummerauer, L., Baumann, P., Ramirez-Lopez, L., Barthel, M., Bauters, M., Bukombe, B., ... & Six, J. (2021). The central African soil spectral library: a new soil infrared repository and a geographical prediction analysis. Soil, 7(2), 693-715.
dc.identifier.issn2073-4395
dc.identifier.urihttps://hdl.handle.net/20.500.12478/7285
dc.description.abstractInformation on soil properties is crucial for soil preservation, the improvement of food security, and the provision of ecosystem services. In particular, for the African continent, spatially explicit information on soils and their ability to sustain these services is still scarce. To address data gaps, infrared spectroscopy has achieved great success as a cost-effective solution to quantify soil properties in recent decades. Here, we present a mid-infrared soil spectral library (SSL) for central Africa (CSSL) that can predict key soil properties, allowing for future soil estimates with a minimal need for expensive and time-consuming wet chemistry. Currently, our CSSL contains over 1800 soil samples from 10 distinct geoclimatic regions throughout the Congo Basin and along the Albertine Rift. For the analysis, we selected six regions from the CSSL, for which we built predictive models for total carbon (TC) and total nitrogen (TN) using an existing continental SSL (African Soil Information Service, AfSIS SSL; n=1902) that does not include central African soils. Using memory-based learning (MBL), we explored three different strategies at decreasing degrees of geographic extrapolation, using models built with (1) the AfSIS SSL only, (2) AfSIS SSL combined with the five remaining central African regions, and (3) a combination of AfSIS SSL, the remaining five regions, and selected samples from the target region (spiking). For this last strategy we introduce a method for spiking MBL models. We found that when using the AfSIS SSL only to predict the six central African regions, the root mean square error of the predictions (RMSEpred) was between 3.85–8.74 and 0.40–1.66 g kg−1 for TC and TN, respectively. The ratio of performance to the interquartile distance (RPIQpred) ranged between 0.96–3.95 for TC and 0.59–2.86 for TN. While the effect of the second strategy compared to the first strategy was mixed, the third strategy, spiking with samples from the target regions, could clearly reduce the RMSEpred to 3.19–7.32 g kg−1 for TC and 0.24–0.89 g kg−1 for TN. RPIQpred values were increased to ranges of 1.43–5.48 and 1.62–4.45 for TC and TN, respectively. In general, predicted TC and TN for soils of each of the six regions were accurate; the effect of spiking and avoiding geographical extrapolation was noticeably large. We conclude that our CSSL adds valuable soil diversity that can improve predictions for the Congo Basin region compared to using the continental AfSIS SSL alone; thus, analyses of other soils in central Africa will be able to profit from a more diverse spectral feature space. Given these promising results, the library comprises an important tool to facilitate economical soil analyses and predict soil properties in an understudied yet critical region of Africa. Our SSL is openly available for application and for enlargement with more spectral and reference data to further improve soil diagnostic accuracy and cost-effectiveness.
dc.description.sponsorshipETH Zurich
dc.format.extent693-715
dc.language.isoen
dc.subjectSoil Properties
dc.subjectFood Security
dc.subjectSoil Analysis
dc.subjectSpectral Analysis
dc.titleThe central African soil spectral library: a new soil infrared repository and a geographical prediction analysis
dc.typeJournal Article
cg.contributor.crpMaize
cg.contributor.crpRoots, Tubers and Bananas
cg.contributor.affiliationETH Zurich
cg.contributor.affiliationBUCHI Labortechnik AG, Switzerland
cg.contributor.affiliationGhent University
cg.contributor.affiliationUniversity of Augsburg
cg.contributor.affiliationEarth and Life Institute, Belgium
cg.contributor.affiliationInternational Institute of Tropical Agriculture
cg.contributor.affiliationKatholieke Universiteit, Leuven
cg.contributor.affiliationWorld Agroforestry Centre
cg.contributor.affiliationUniversity of Lubumbashi
cg.coverage.regionAfrica
cg.coverage.regionCentral Africa
cg.coverage.regionEast Africa
cg.coverage.countryDemocratic Republic of the Congo
cg.coverage.countryRwanda
cg.coverage.countryUganda
cg.coverage.hubCentral Africa Hub
cg.researchthemeNatural Resource Management
cg.identifier.bibtexciteidSUMMERAUER:2021
cg.isijournalISI Journal
cg.authorship.typesCGIAR and developing country institute
cg.iitasubjectFood Security
cg.iitasubjectNatural Resource Management
cg.iitasubjectSoil Fertility
cg.iitasubjectSoil Information
cg.journalSoil
cg.notesOpen Access Journal; Published online: 26 Oct 2021
cg.accessibilitystatusOpen Access
cg.reviewstatusPeer Review
cg.usagerightslicenseCreative Commons Attribution 4.0 (CC BY 0.0)
cg.targetaudienceScientists
cg.identifier.doihttps://dx.doi.org/10.5194/soil-7-693-2021
cg.iitaauthor.identifierbernard vanlauwe: 0000-0001-6016-6027
cg.futureupdate.requiredNo
cg.identifier.issue2
cg.identifier.volume7


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