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181	Produção e qualidade de fitomassa em diferentes estádios de culturas solteiras e consorciadas de guandu-anão, sorgo e milheto / Production and quality of the phytomass in different stages of single crops and consortium of pegeon pea, sorghum and mllet Calvo, Cássio Loureiro 10 December 2007 (has links) Made available in DSpace on 2016-07-18T17:51:15Z (GMT). No. of bitstreams: 1 Dissertacao Cassio.pdf: 89555 bytes, checksum: 2cb8164cead8de20efdda98a794b73c4 (MD5) Previous issue date: 2007-12-10 / Objected with this work to evalue the vegetable matter production, the accumulation of N and relation C/N of phytomass in different stages of single crops and consortiums of pigeon pea (Cajanus cajan), sorghum (Sorghum bicolor) and millet (Pennisetum glaucum). The experimental was conducted in a Experimental Farm of Unoeste, at Presidente Prudente-SP, during March and June, 2006. It was used the randomized experimental design in blocks, in the factorial scheme, with the followings treatments: sorghum monoculture, pigeon pea and millet, and consortium of sorghum + pigeon pea, millet + pigeon pea and millet + sorghum, with stages of collection at 30, 60 e 90 days after seeding. The millet was more expressive in the initial grouth velocity, so that species in consortium were dominated, and it produced more phytomass in the intercropping than in the monocultures. The best period to handle consortiums of millet + pigeon pea and sorghum + pigeon pea were at 60 and 90 days after seeding in off-season time, respectively. The consortium sorghum + pigeon pea submitted better balance in composition to straw, because there was more timing between growth velocity of both species. The monoculture of grass submitted straw with relation C/N more elevated than in the intercropping millet + pigeon pea and sorghum + pigeon pea. / A consorciação de plantas de cobertura tem sido preconizada com o propósito de conciliar a proteção do solo e favorecer a oferta de nutrientes em sistemas de rotação de culturas. Objetivou-se com este trabalho avaliar a produtividade de matéria vegetal, o acúmulo de N e a relação C/N de fitomassas em diferentes estádios de culturas solteiras e consorciadas de guandu-anão (Cajanus cajan), sorgo (Sorghum bicolor) e milheto (Pennisetum glaucum). O experimento foi realizado na Fazenda Experimental da Unoeste, em Presidente Prudente-SP, durante março e junho de 2006. Utilizou-se o delineamento experimental em blocos aos acaso, no esquema fatorial, com os seguintes tratamentos: monocultivos de sorgo, guandu-anão e milheto, e consórcios de sorgo + guandu-anão, milheto + guandu-anão e milheto + sorgo, com épocas de coleta aos 30, 60 e 90 dias após a semeadura. O milheto foi muito expressivo na velocidade de crescimento inicial, de tal forma que as espécies em consórcio ficaram dominadas, produzindo mais fitomassa nas culturas intercaladas do que em monocultivo. As melhores épocas para o manejo das culturas consorciadas de milheto + guandu-anão e sorgo + guandu-anão foram aos 60 e 90 dias após a semeadura no ambiente safrinha, respectivamente. A consorciação sorgo + guandu-anão apresentou maior equilíbrio na composição da palhada, pois houve mais sincronismo entre as velocidades de crescimento de ambas as espécies. Os monocultivos de gramíneas apresentaram palhadas com relações C/N mais elevadas do que nos consórcios milheto + guandu-anão e sorgo + guandu-anão. Plantas de Cobertura Relação C/N Nitrogênio Sistema Plantio Direto Cover crops Relation C/N Nitrogen No-tillage system CNPQ::CIENCIAS AGRARIAS::AGRONOMIA
182	Integrating Cover Crop Mixtures and No-Till for Sustainable Sweet Corn Production in the Northeast Fine, Julie S 09 July 2018 (has links) Fall-planted forage radish (Raphanus sativus L. longipinnatus) cover crops have shown successful weed suppression and recycling of fall-captured nutrients. This research evaluated the nutrient cycling and weed suppressive benefits of forage radish cover crop mixtures to develop an integrated system for no-till sweet corn (Zea mays L. var rugosa) production that improves crop yield and soil health. Treatments included forage radish (FR), oats (Avena sativa L.) and forage radish (OFR), a mixture of peas (Pisum sativum subsp arvense L.), oats and forage radish (POFR), and no cover crop control (NCC). Subplots were assigned to nitrogen fertilizer treatments to evaluate N sufficiency and timing: 0 kg N ha-1 as the control, 28 kg N ha-1 at side-dress, and 56 kg N ha-1 with application split between planting and side-dress. Results indicated that POFR and OFR provided improved N cycling and sweet corn yield compared with FR and NCC. Early season N from decomposing cover crop residue was sufficient to eliminate the need for N fertilizer at sweet corn planting, thereby reducing input costs and risks of environmental pollution. cover crops no-till sweet corn nitrogen cycling yield winter-killed weeds Agricultural Economics Agricultural Science Agriculture Agronomy and Crop Sciences Weed Science
183	Introduzione di sistemi agricoli conservativi per migliorare la qualità del suolo e sostenere la produzione di alimenti / INTRODUCING CONSERVATION AGRO-ECOSYSTEMS TO ENHANCE SOIL QUALITY AND SUSTAIN FOOD PRODUCTION BOSELLI, ROBERTA 03 April 2020 (has links) L’introduzione di agro-ecosistemi conservativi viene indicata come strategia per aumentare il sequestro del carbonio organico nel suolo (SOC) e migliorarne la fertilità. La continua applicazione di concimi organici, come il compost e il sovescio, favorisce il sequestro di SOC (+ 1.3 ÷ 2.5 Mg C ha-1 anno-1) e l'accumulo di azoto totale del suolo (STN) (+ ~ 1 Mg N ha-1 anno-1). Tuttavia, quando le fertilizzazioni organiche vengono interrotte, il SOC diminuisce rapidamente. Negli agro-ecosistemi intensivi, il no till (NT) garantisce rese comparabili a quelle dei sistemi convenzionali (CT) immediatamente dopo la transizione. Il NT aumenta la sostanza organica (SOM) e il STN principalmente nei primi 5 cm di terreno, sebbene la cover crop di segale assicuri l'accumulo di SOM fino a 30 cm di profondità (+ 30% rispetto alla CT). Il NT e la minima lavorazione (MT) portano ad un aumento del SOC e del STN nei primi 30 cm di suolo, rispetto al CT. Gran parte di tale aumento è dovuto ai macroaggregati, all'interno dei quali, i pool di C e N associati ai microaggregati (mM) rappresentano tra il 41 e il 65% del contenuto totale di C e N nei sistemi NT e MT. / The introduction of conservation agro-ecosystems has been suggested for increasing soil organic carbon (SOC) sequestration and enhancing soil fertility. Continuous organic fertilization such as compost distribution and cover crops incorporation promotes SOC sequestration (+1.3÷2.5 Mg C ha-1 yr-1) and soil total nitrogen (STN) accumulation (+~1 Mg N ha-1 yr-1). However, when the organic fertilization is stopped, SOC rapidly decreases. In intensive agro-ecosystems, no till (NT) can ensure yields comparable to conventional tillage (CT) immediately after transition. The major contribution of NT to soil organic matter (SOM) and STN increase is detected in the top 5 cm of soil, although the cultivation of rye as cover crop ensures SOM accumulation down to 30 cm depth (+30% than CT). No till and minimum tillage (MT) may increase SOC and STN levels in the 0-30 cm soil layer, both as concentration and as mass, compared with CT. Most of such a SOC and STN increase is due to C- and N-rich macroaggregates. Within macroaggregates, microaggregates (mM) are of primary importance for soil organic matter stabilization since C and N pools associated to mM account for between 41 and 65% of total C and N content in the NT and MT systems. AGR/02: AGRONOMIA E COLTIVAZIONI ERBACEE
184	OPTIMIZING COVER CROP ROTATIONS FOR WATER, NITROGEN AND WEED MANAGEMENT Sciarresi, Cintia Soledad 01 January 2019 (has links) Winter cover crops grown in rotation with grain crops can be an efficient integrated pest management tool (IPM). However, cover crop biomass production and thus successful provisioning of ecosystem services depend on a timely planting and cover crop establishment after harvest of a cash crop in the fall. One potential management adaptation is the use of short-season soybeans to advance cover crop planting date in the fall. Cover crops planted earlier in the fall may provide a greater percentage of ground cover early in the season because of higher biomass accumulation that may improve weed suppression. However, adapting to short-season soybeans could have a yield penalty compared to full-season soybeans. In addition, it is unclear if further increasing cover crop growing season and biomass production under environmental conditions in Kentucky could limit nitrogen and water availability for the next cash crop. This thesis combines the use of field trials and a crop simulation model to address the research questions posed. In Chapter 1, field trials evaluating yield and harvest date of soybean maturity group (MG) cultivars from 0 to 4 in 13 site-years across KY, NE, and OH, were used to calibrate and evaluate the DSSAT crop modeling software (v 4.7). The subsequent modeling analysis showed that planting shorter soybean maturity groups (MG) would advance date of harvest maturity (R8) by 6.6 to 11 days per unit decrease in MG for May planting or by 1 to 7.3 days for July planting. The earliest MG cultivar that maximized yield ranged from MG 0 to 3 depending on the location, allowing a winter-killed cover crop to accumulate between 257 to 270 growing degree days (GDD) before the first freeze occurrence when soybean was planted in May, and between 280 to 296 GDD when soybean was planted in July. Winter-hardy cover crops could accumulate 701 to 802 GDD following soybean planted in May and 329 to 416 GDD after soybean planted in July. In Chapter 2, a two-year field trial was conducted at Lexington, KY to evaluate the effect of a soybean – cover crop rotation with soybean cultivars MG 1, 2, 3 or 4 on cover crop biomass and canopy cover, and on weed biomass in the fall and the following spring. Results showed that having cover crops was an efficient management strategy to reduce weed biomass in the fall and spring compared to no cover treatment. Planting cover crops earlier in the fall after a short-season soybean increased cover crop biomass production and percentage of ground cover in the fall, but not the following spring. Planting cover crop earlier after a short-season soybean did not improve weed suppression in the fall or spring compared to a fallow control with full-season soybean. Having a fall herbicide application improved weed control when there was a high pressure of winter annual weeds. By the spring, delaying cover crop termination increased cover crop biomass but also did weed biomass. In Chapter 3, a soybean – cover crop – corn rotation was simulated to evaluate the effect of different soybean MG and cover crop termination, as well as year to year variability on water and nitrogen availability for the next corn crop in Lexington, KY. Simulations showed that when cover crops were terminated early, they did not reduced soil available water at corn planting. However, introducing a non-legume cover crop reduced total inorganic nitrogen content in the soil profile by 21 to 34 kg ha-1 implying 15 to 30 kg ha-1 less in corn nitrogen uptake. Cover crop management that was able to maintain similar available water values than fallow treatment while minimizing nitrogen uptake differences was cover crops planted after soybean MG 4 with an early termination. However, the best management strategies that will maximize ecosystem services from cover crops as well as cash crop productivity may need to be tailored to each environment, soil type, irrigation management, and must consider year-to-year variability. model calibration DSSAT soybean maturity group cover crops weed control nitrogen balance water balance corn. Agricultural Science Agronomy and Crop Sciences Plant Sciences Weed Science
185	COVER CROPPING FOR SUSTAINABLE CO-PRODUCTION OF BIOENERGY, FOOD, FEED (BFF) AND ENHANCEMENT OF ECOSYSTEM SERVICES (ES) Brodrick L Deno (9867779) 18 December 2020 (has links) Increasing food, feed, fiber, biofuel production on decreasing amounts of arable land while simultaneously enhancing ecosystem services is challenging. Strategic inclusion of winter rye (<i>Secale cereale</i>) for biomass, silage, grain and Kura clover (<i>Trifolium ambiguum</i>) living mulch into existing Midwestern cropping systems may offer alternative economic income for farmers without displacing or reducing yields of primary crops. Research was conducted at the Purdue Water Quality Field Station (WQFS) where net balances of water, carbon, nitrogen, and radiation can be measured, and greenhouse gas (GHG) emissions are monitored. The agronomic performance of a corn-soybean rotation and continuous corn (controls) were compared to novel systems that included the use of rye cover cropping and Kura clover co-cropping. Rye was harvested for biomass/silage at heading immediately followed by corn or soybean planting. Continuous corn receiving 69 kg N ha<sup>-1 </sup>was planted into an establishment of Kura clover sod. Controls included these same systems without the rye or clover. GHG samples were taken via the static chamber method and tile-drained water sub-samples were collected, analyzed for nitrate, and load losses calculated. Biomass composition was determined and used to calculate herbage theoretical ethanol (EtOH) yields. Cereal rye did not significantly decrease corn or soybean grain yield. Averaged across years, Kura clover significantly depressed corn grain yields by nearly 70%. Kura clover significantly reduced flow-weighted tile drainage nitrate (NO<sub>3</sub><sup>-</sup>) concentrations, however cereal rye did not. Reductions in flow-weighted tile drainage nitrate (NO<sub>3</sub><sup>-</sup>) concentrations were found to largely occur during Quarter two (April, May, June). Cover crops did not significantly reduce annual tile drained NO<sub>3</sub><sup>-</sup> load losses in most cases, however, they did significantly reduce annual N<sub>2</sub>O emissions. Cumulative annual CH<sub>4</sub> emissions were not significantly altered. Annual CO<sub>2</sub>emissions were higher after the introduction of Kura clover and not significantly altered following the introduction of cereal rye. Averaged across years, theoretical ethanol yields in the Kura clover system produced 2,752 L EtOH ha<sup>-1</sup>, whereas EtOH production in cereal rye systems ranged from 3,245 to 4,210 L EtOH ha<sup>-1</sup>. Theoretical ethanol yields of continuous corn and rotational controls ranged from 2,982 to 3505 L EtOH ha<sup>-1</sup> for these same systems without the cereal rye of Kura clover. These data suggest that a multipurpose approach to cover crop inclusion can provide both environmental and economic advantages worthy of consideration. Agronomy Kura Clover Cereal Rye Ethanol Water Quality Greenhouse Gas Emissions Environment Cover Crops Perennial Living Mulch Sustainable Intensification Ecosystem Services Agronomy Nutrient Load Loss
186	Etude du fonctionnement d'associations entre le bananier et une couverture vivante ; évaluation des potentialités et stratégies d'utilisation de plantes de service pour contrôler les adventices / Study of the functioning of an intercropped living cover and a banana crop; evaluation of the ability and the strategy of use of cover crops to control weeds Achard, Raphaël 02 December 2016 (has links) L’objectif de cette thèse est de proposer une démarche pour identifier des plantes de service (Pds) utilisables en couverture vivante pour contrôler les adventices en bananeraie. Nous avons d’abord quantifié les effets de compétition réciproque entre le bananier et une couverture contrôlée par fauchage pour Brachiaria decumbens et Cynodon dactylon. Ces couverts ont eu des effets dépressifs sur la nutrition azotée du bananier et la productivité en premier cycle, le second cycle n’étant pas affecté. Dans un deuxième temps nous avons caractérisé au champ, en plantes isolées, la croissance en biomasse de huit légumineuses candidates sous différentes intensités lumineuses. En conditions lumineuses non limitantes, chaque espèce répondait à une dynamique exponentielle, définie par la biomasse 14 jours après semis et le taux de croissance relative (RGR). En conditions d’ombrage limitant, le RGR est réduit et le rapport surface foliaire sur biomasse aérienne croît. Ces réponses permettent de définir quatre stratégies d’adaptation à l’ombrage et d’identifier les Pds adaptées sous bananeraie. Pour trois de ces espèces, sur la base de la réponse de l’efficience photosynthétique, nous proposons un modèle de croissance en fonction de la ressource lumineuse. En peuplement, en présence d’adventices, aucune espèce évaluée n’a pu contrôler les grandes graminées, Stylosanthes guianensis et Centrosema pascuorum ont cependant réduit la biomasse des autres adventices de 60%. En bananeraie, les deux espèces évaluées ont exercé un contrôle sur les adventices mais ont réduit la productivité du premier cycle. Pour autant, ces résultats sont encourageants pour l’utilisation de Pds en bananeraie à des fins de contrôle des adventices. / The objective of this PhD thesis was to provide an approach to identify suitable cover crops (Pds) for weed control use in banana plantations. Firstly, we quantified the reciprocal effects between the banana crop and a grass cover controlled by mowing, for Brachiaria decumbens or Cynodon dactylon. These cover crops have had similar depressive effects on the nitrogen nutrition and on the productivity of the first cycle, but not afterward during the second cycle. Second step, we carried out a field characterization of eight legume cover crops, on isolated plants, under a range of light intensity. In non-limited light growth conditions, the biomass growth corresponded to an exponential dynamic, mathematically defined for each species by the biomass 14 days after sowing, and the relative growth rate (RGR). When affected by the shade, the RGR was reduced and the ratio between Leaf area and aerial plant biomass increased. We defined four adaptive strategies of the cover crops to the shade, what constitute criteria guidelines for cover crop use in banana cropping systems. For three of these species, on the basis of the response of the radiation use efficiency, we are proposing a plant growth model without any limiting factor other than light resource. In stands with the presence of weeds, neither of this cover crops was able to control the tall gramineous, but Stylosanthes guianensis and Centrosema pascuorum reduced the biomass of other weeds by 60%. Finally, in banana plantations, the two evaluated species provided a control of the weeds but reduced the productivity of the first cycle. Our results are comforting for the use of cover crops in banana plantation as a mean for weed control. Adventices Plante de service Bananiers Compétition Traits morphologiques Associations culturale Interception lumineuse Weeds Cover crops Banana Competition Morphological traits Intercropping Light interception 632.5
187	Effect of cover crops, grazing and tillage practices on soil microbial community composition, function, and soil health in east central Mississippi soybean production system. Sinha, Namita 09 August 2022 (has links) Integrating crop and livestock is being considered to improve soil health by carbon sequestration. A two-year study (2019-2021) at CPBES in Newton, MS was aimed to evaluate soil microbial diversity in the warm, humid regions, specifically southeastern USA. Amplicons targeting bacterial 16S rRNA genes and fungal ITS2 regions were sequenced. Taxonomic assignment and microbial diversity characterization were performed using QIIME2®. Soil fungal diversity showed significant differences (alpha diversity, p = 0.031 in yr. 2020 and beta diversity, p = 0.037 in yr. 2021). Canonical Correspondence Analysis (CCA) and Mantel test showed significant influence on fungal diversity due to carbon (rm = 0.2581, p = 0.022), nitrogen (rm = 0.2921, p = 0.0165) in yr. 2021, and on bacterial diversity due to EE-GRSP (rm = 0.22, p = 0.02) in yr. 2020. Long term study of ICLS can help us better understand the shift in microbiome to improve crop production sustainably. Cover crops Grazing Tillage 16SrRNA ITS2 region Illumina Miseq paired end sequencing QIIME Amplicon sequencing Soil Characterization Soil Health Agronomy and Crop Sciences Biodiversity Bioinformatics Plant Sciences
188	Cover crops and irrigation impacts on corn and soybean production in the Mid-Southern USA Russell, Dillon Aaron 13 May 2022 (has links) (PDF) Reducing groundwater withdrawals from the Mississippi River Valley Alluvial Aquifer is imperative to sustain future irrigated cropping systems in the mid-southern USA. This research was conducted to determine the impacts of cover crops and irrigation sensor thresholds on corn (Zea mays L.) and soybean (Glycine max L.) production, water productivity, irrigation water use efficiency, and soil physical properties in the Mississippi Delta. The cover crop treatments included cereal rye (Secale cereale L.), hairy vetch (Vicia villosa R.), wheat (Triticum aestivum L.)-radish (Raphanus sativus L.)-turnip (Brassica rapa L.) mix, and no cover crop. The irrigation thresholds included -40 kPa, -90 kPa, and no irrigation. In 2020, cover crops and irrigation thresholds showed minimal impacts on most of the measured parameters but showed improvements as the study progressed. After two years, it was determined that long-term evaluations are needed to make a recommendation to producers in the mid-southern USA. Cover crops Irrigation threshold Irrigation water use efficiency Mississippi Delta Soil physical properties Water productivity Agronomy and Crop Sciences Water Resource Management
189	Alternative practices for optimising soil quality and crop protection for macadamia orchards, Limpopo Province, South Africa. Steyn, Jakobus Nicolaas 30 September 2019 (has links) Department of Ecology and Resource Management / PhDENV / The main aim of the research was to contribute means for converting conventional, high-input production systems to more sustainable ecological systems, thereby improving the sustainability of macadamia production and ultimately contributing to food security. This was achieved by a) investigating the potential use of cover crops and compost to enhance soil quality in macadamia orchards and b) investigating the potential use of use of cover crops and orchard heterogeneity to control stinkbug pests that target macadamia crops. Field experiments were conducted in three phases: phase one tested the potential of six cover crops for crop protection (as trap crops) and simultaneously for soil restoration or fertility enhancement purposes in macadamia orchards. Phase two repeated the trials of phase one (both soil restoration and trap crops) but with modifications to both categories. Soil restoration treatments were conducted with trees which were growing in what appeared to be healthy soils, and then repeated with trees in the same orchard where the topsoil had been degraded (totally removed) by agricultural operations. The third phase repeated the trap crop trials only, but this time on three different study areas (all commercial farms) with the single cover crop which performed the best as a trap crop during phase two. Trials were modified from the first to the last phase to overcome practical implementation problems encountered along the way and to adapt to local conditions experienced in the commercial macadamia farming systems which served as research sites. Diversity of natural orchard vegetation was enhanced in phase three to improve conditions for natural predators as part of the trap crop treatments in the last phase and cover crops were finally first composted and then returned to the root zones of the macadamia trees as part of the soil quality enhancement treatments in the second phase. The results from the trap crop trials shows a significant effect of trap crops combined with increased orchard diversity in reducing unsound kernel percentages caused by stinkbug pests and demonstrate that trap crops combined with an increase in orchard diversity could be utilized in macadamia orchards as a more sustainable alternative to inorganic pesticides against the stinkbug complex. The most notable changes in the soil that took place with soil quality enhancement treatments were the significant increases in soil phosphorous content and pH which resulted not in an improvement in soil quality in terms of these two indicators but revealed an important issue about the use of compost containing animal manure originating from dairies or feedlots. In summary however, it was clear that although not all the soil quality indicators that were employed to assess changes in the soil with compost treatments improved significantly, a holistic consideration of all indicators portrays an overall improvement which was particularly significant in the degraded soil plots where the topsoil had been removed by prior agricultural activities. / NRF Cover crops Trap crops Ecological sustainability Soil quality Crop protection Habitat Heterogeneity Compost Macadamia 634.50968257 Macadamia nut -- South Africa -- Limpopo Nuts -- South Africa -- Limpopo Cover crops -- South Africa -- Limpopo Compost -- South Africa -- Limpopo
190	The use of cover crops to increase yield and reduce pest pressure in a commercial avocado orchard at Levubu, Limpopo Province Nengovhela, Ndoweni Mary 13 August 2020 (has links) MENVSC / Department of Ecology and Resource Management / The study investigated the impact of cover crops (Medicago sativa, Lotus corniculatus, Trifolium pratense, Melilotus alba and Phacelia tanacetifolia), bare soil and natural ground cover on pest and beneficial arthropods, soil health, crop yield, pest damage and weed suppression in avocado orchards. The trial plots were sited within established commercial avocado orchards with trees of similar cultivar (‘Hass’), soil-type and age, located in Levubu, Limpopo, South Africa. Mixtures of cover crops were planted in the alleys of avocado orchards and the effects were compared to that of a control (other half of the orchard). Mechanical clearing of vegetation in half of the alleys of different avocado orchards were compared to the other half that was left undisturbed. Data were collected during the flowering and fruit set stages of the avocado trees in the months of September - November 2019. Results revealed that there was higher abundance and diversity of flowering plants in the orchard alleys of the cover crop treatment compared to the control comprising of natural vegetation. Cover crops had a significantly positive effect on the soil health of the orchard but little or no effect on beneficial arthropods within the orchard nor any positive effect on the pests of avocados. However, the number of thrips scouted on the fruit were significantly less where cover crops were established. Avocado scale infection rates were also significantly lower where cover crops were established. There were significantly less arthropods, and specifically pests, pollinators and herbivores where the topsoil was removed mechanically. The yield resulting from the orchard half where cover crops were established were significantly higher. More research still needs to be done about the use, management and impact of cover cropping on not only commercial avocado orchards but on other fruit crops. This study shows good evidence for the benefits for using cover crops and the negative effects in having no vegetation cover in the orchards. / NRF Avocado Cover crops Biodiversity Pests Pollinators Predators 631.4520968257 Cover crops -- South Africa -- Limpopo Catch crops -- South Africa -- Limpopo Avocado -- South Africa -- Limpopo Lupines-- South Africa -- Limpopo

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