Your search keyword '"Solomon Ngoze"' showing total 4 results

1. Long-term soil quality degradation along a cultivation chronosequence in western Kenya

Author

Bianca N. Moebius-Clune, Solomon Ngoze, Johannes Lehmann, Robert R. Schindelbeck, Omololu J. Idowu, J.M. Kimetu, H. M. van Es, and James Kinyangi

Subjects

chemistry.chemical_classification, Ecology, Soil organic matter, Chronosequence, Soil quality, Soil structure, chemistry, Agronomy, Soil functions, Soil retrogression and degradation, Soil water, Environmental science, Animal Science and Zoology, Organic matter, Agronomy and Crop Science

Abstract

Loss of agroecosystem soil functions due to soil quality (SQ) degradation impacts Africa's agricultural viability and food security. Primary forest and farm fields deforested between 1930 and 2000 were sampled along a chronosequence on two parent materials in western Kenya. Two traditional long-term management systems were sampled: continuous low-input maize (Zea mays; Co), and kitchen garden (Ki) polyculture with organic inputs. Physical, biological, and chemical SQ indicators were measured. Degradation in Co followed exponential decay trends for most indicators (organic matter, active C, water-stable aggregates, available water capacity, electrical conductivity, CEC, pH, Ca, Mg and Zn), as well as for yield. Organic matter quality declined linearly, suggesting degradation will continue. For both parent materials and most indicators degradation of 25–93% below initial values resulted, but with ≤40% further drop below initial values and for more indicators under Co than Ki. P, Zn and possibly K accumulated over time under Ki. The extent of degradation was influenced by parent material. In conclusion, a basic accessible set of SQ indicators was successfully used to describe soil degradation dynamics under cultivation. Results suggest that regular organic inputs can significantly reduce degradation, especially of nutrient retention and soil structure, after forest conversion.

Published

2011

2. Nutrient constraints to tropical agroecosystem productivity in long-term degrading soils

Author

David Mbugua, Johannes Lehmann, Susan J. Riha, Louis V. Verchot, Alice N. Pell, Solomon Ngoze, and James Kinyangi

Subjects

Agroecosystem, Global and Planetary Change, Ecology, Chronosequence, Tropics, engineering.material, Biology, Nutrient, Agronomy, Soil retrogression and degradation, Soil water, engineering, Environmental Chemistry, Fertilizer, Soil fertility, General Environmental Science

Abstract

Soil degradation is one of the most serious threats to sustainable crop production in many tropical agroecosystems where extensification rather than intensification of agriculture has occurred. In the highlands of western Kenya, we investigated soil nitrogen (N) and phosphorus (P) constraints to maize productivity across a cultivation chronosequence in which land-use history ranged from recent conversion from primary forest to 100 years in continuous cropping. Nutrient treatments included a range of N and P fertilizer rates applied separately and in combination. Maize productivity without fertilizer was used as a proxy measure for indigenous soil fertility (ISF). Soil pools of mineral nitrogen, strongly bound P and plant-available P decreased by 82%, 31% and 36%, and P adsorption capacity increased by 51% after 100 years of continuous cultivation. For the long rainy season (LR), grain yield without fertilizer declined rapidly as cultivation age increased from 0 to 25 years and then gradually declined to a yield of 1.6Mgha � 1 , which was maintained as time under cultivation increased from 60 to 100 years. LR grain yield in the old conversions was only 24% of the average young conversion grain yield (6.4Mgha � 1 ). Application of either N or P alone significantly increased grain yield in both the LR and short rainy (SR) seasons, but only application of 120kgNha � 1 on the old conversion increased yield by 41Mgha � 1 . In both SR and LR, there was a greater average yield increment response to N and P when applied together (ranging from 1 to 3.8Mgha � 1 for the LR), with the greatest responses on the old conversions. The benefit‐cost ratio (BCR) for applying 120kgNha � 1 alone was o1 except on the old conversions, while BCRs were41 for applying 25kgPha � 1 alone at all levels of conversion for both seasons. Application of both N (120kgNha � 1 ) and P (25kgPha � 1 ) on the old conversions resulted in the greatest BCRs. This study clearly indicates that maize productivity responses to N and P fertilizer are significantly affected by the age of cultivation and its influence on ISF, but that loss of productivity can be restored rapidly when these limiting nutrients are applied. Management strategies should consider ISF and economic factors to determine optimal N and P input requirements for achieving and sustaining profitable crop production on degraded soils.

Published

2008

3. Long-term impacts of anthropogenic perturbations on dynamics and speciation of organic carbon in tropical forest and subtropical grassland ecosystems

Author

Johannes Lehmann, Wulf Amelung, Jan O. Skjemstad, Alice N. Pell, David Mbugua, James Kinyangi, Solomon Ngoze, Susan J. Riha, Lou Verchot, Ingo Lobe, Thorsten Schäfer, and Dawit Solomon

Subjects

Agroecosystem, Total organic carbon, chemistry.chemical_classification, Global and Planetary Change, Biogeochemical cycle, Ecology, Soil organic matter, Carbon sequestration, chemistry, Environmental chemistry, Soil water, Environmental Chemistry, Environmental science, Ecosystem, Organic matter, General Environmental Science

Abstract

Anthropogenic perturbations have profoundly modified the Earth’s biogeochemical cycles, the most prominent of these changes being manifested by global carbon (C) cycling. We investigated long-term effects of human-induced land-use and land-cover changes from native tropical forest (Kenya) and subtropical grassland (South Africa) ecosystems to agriculture on the dynamics and structural composition of soil organic C (SOC) using elemental analysis and integrated 13 C nuclear magnetic resonance (NMR), near-edge X-ray absorption fine structure (NEXAFS) and synchrotron-based Fourier transform infrared-attenuated total reflectance (Sr-FTIR-ATR) spectroscopy. Anthropogenic interventions led to the depletion of 76%, 86% and 67% of the total SOC; and 77%, 85% and 66% of the N concentrations from the surface soils of Nandi, Kakamega and the South African sites, respectively, over a period of up to 100 years. Significant proportions of the total SOC (46‐73%) and N (37‐73%) losses occurred during the first 4 years of conversion indicating that these forest- and grassland-derived soils contain large amounts of labile soil organic matter (SOM), potentially vulnerable to degradation upon human-induced land-use and land-cover changes. Anthropogenic perturbations altered not only the C sink capacity of these soils, but also the functional group composition and dynamics of SOC with time, rendering structural composition of the resultant organic matter in the agricultural soils to be considerably different from the SOM under natural forest and grassland ecosystems. These molecular level compositional changes were manifested: (i) by the continued degradation of O-alkyl and acetal-C structures found in carbohydrate and holocellulose biomolecules, some labile aliphatic-C functionalities, (ii) by side-chain oxidation of phenylpropane units of lignin and (iii) by the continued aromatization and aliphatization of the humic fractions possibly through selective accumulation of recalcitrant H and C substituted aryl-C and aliphatic-C components such as (poly)-methylene units, respectively. These changes appeared as early as the fourth year after transition, and their intensity increased with duration of cultivation until a new quasi-equilibrium of SOC was approached at about 20 years after conversion. However, subtle but persistent changes in molecular structures of the resultant SOM continued long after (up to 100 years) a steady state for SOC was approached. These molecular level changes in the inherent structural composition of SOC may exert considerable influence on biogeochemical cycling of C and bioavailability of essential nutrients present in association with SOM, and may significantly affect the sustainability of agriculture as well as potentials of the soils to sequester C in these tropical and subtropical highland agroecosystems.

Published

2007

4. Anthropogenic and climate influences on biogeochemical dynamics and molecular-level speciation of soil sulfur

Author

Johannes Lehmann, James Kinyangi, Alice N. Pell, Solomon Ngoze, Chris C. Du Preez, H. Henry Janzen, Susan J. Riha, Janice Theis, Ben Ellert, Wulf Amelung, Stephen Machado, and Dawit Solomon

Subjects

Biogeochemical cycle, geography, geography.geographical_feature_category, Time Factors, Ecology, Sulfur Compounds, Climate, Temperature, Biogeochemistry, Soil classification, Subtropics, Kenya, Grassland, Soil, South Africa, Soil water, North America, Temperate climate, Environmental science, Humans, Ecosystem, Oxidation-Reduction, Sulfur

Abstract

The soil environment is a primary component of the global biogeochemical sulfur (S) cycle, acting as a source and sink of various S species and mediating oxidation state changes. However, ecological significance of the various S forms and the impacts of human intervention and climate on the amount and structural composition of these compounds are still poorly understood. We investigated the long-term influences of anthropogenically mediated transitions from natural to managed ecosystems on molecular-level speciation, biogeochemical dynamics, and the apparent temperature sensitivity of S moieties in temperate, subtropical, and tropical environments with mean annual temperature (MAT) ranging from 5 degrees C to 21 degrees C, using elemental analysis and X-ray absorption near-edge structure (XANES) spectroscopy. Land-use and land-cover changes led to the depletion of total soil S in all three ecoregions over a period of up to 103 years. The largest decline occurred from tropical forest agroecosystems (67% Kakamega and 76% Nandi, Kenya), compared to losses from temperate (36% at Lethbridge, Canada, and 40% at Pendleton, USA) and subtropical (48% at South Africa) grassland agroecosystems. The total S losses correlated significantly with MAT. Anthropogenic interventions profoundly altered the molecular-level composition and resulted in an apparent shift in oxidation states of organic S from native ecosystems composed primarily of S moieties in intermediate and highly reduced oxidation states toward managed agroecosystems dominated by organic S rich in strongly oxidized functionalities. The most prominent change occurred in thiols and sulfides, the proportion of which decreased by 46% (Lethbridge) and 57% (Pendleton) in temperate agroecosystems, by 46% in subtropical agroecosystems, and by 79% (Nandi) and 81% (Kakamega) in tropical agroecosystems. The proportion of organic S directly linked to O increased by 81%, 168%, 40%, 92%, and 85%, respectively. Among the various organic S functionalities, thiols and sulfides seem to have higher apparent temperature sensitivity, and thus these organic S moieties may become prone to losses due to land-use changes, even from the cooler regions of the world if MAT of these regions rise in the future.

Published

2009