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THE INFLUENCE OF ENVIRONMENTAL FACTORS ON SPINELESS CACTUS PEAR (OPUNTIA SPP.) FRUIT YIELD IN LIMPOPO PROVINCE, SOUTH AFRICAPotgieter, Johannes Petrus 06 February 2009 (has links)
Limited information is available on the response of local cactus pear cultivars to
environmental factors that influence fruit yield. Eleven cultivars were evaluated in three
diverse agro-climatic areas over seven production seasons in the Limpopo Province to
assess their environmental adaptability. Significant differences between cultivars, areas
and production years for five fruit yield components were evident. A strong genotype by
environment interaction was observed, although some cultivar characteristics were
genetically controlled. The most suitable production area is the cool mid-altitude area of
Limpopo Province. Cultivars that can be recommended for fresh fruit production are:
âAlgerianâ, âAmerican Giantâ, âGymno Carpoâ, âMaltaâ, âMoradoâ, âNudosaâ and âZastronâ.
Fruit yield was significantly influenced by minimum temperature and plant macro
nutrients. Soil phosphorus levels above 20 mg kg-1 and applied nitrogen higher than 100
kg ha-1 year-1 had a positive effect on fruit yield. Soil pH did not influence the fruit yield of
the cultivars tested. None of the cultivars tested had a winter chilling requirement to
become fertile. Vegetative growth was stimulated by increased solar radiation. Cactus
pear plants can be considered to be fully mature from the fifth year onwards.
Environmental adaptability is related to species differences rather than plant
morphological differences. Plant growth habit changed markedly in different
environments. To obtain high fruit yields, it is important to match a cultivar with
prevailing environmental conditions of the area. Fruit yield in cactus pear is a function of
the number of fertile cladodes, the number of fruit set, the number of fruit left after
thinning and individual fruit mass. Research into orchard practices, in particular pruning,
and evaluation of the existing cactus pear germplasm should receive attention. As a
ânewâ cultivated fruit crop it offers real solutions towards mitigation of the effects of
drought in arid and semi-arid parts of Limpopo Province.
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VERFYNING EN VERBETERING VAN âN DONSIGE SKIMMEL WAARSKUWINGSMODEL VIR DIE WES-KAAPHaasbroek, Pieter Daniel 13 June 2007 (has links)
Downy Mildew (Plasmopara viticola) is known as one of the most important vineyard
diseases in the Western Cape, because it has the capability to develop and spread very
fast, and so cause large crop losses in certain years. In 1992 an Austrian researcher
developed the Metos automatic weather station and associated software, to predict the
occurrence of primary and secondary infection of downy mildew. This Metos weather
stationâs software was adapted for South African climatic conditions during 1995 and is
known as the Metos-2 model. The Metos-2 model however had some shortcomings that
needed to be improved. The most important of this was that the model was not sensitive
enough to accurately calculate infections, and furthermore it gives only a âYes/Noâ
warning of possible primary and/or secondary infections. The Metos-2 model makes use
of measured leaf wetness values from a leaf wetness sensor that is probably considered as
one of the most inaccurate meteorological sensors. During 1995 - 2005 the Metos-2
model has been thoroughly tested and used by the disease management division of ARC
Infruitec-Nietvoorbij, to warn the industry of possible downy mildew outbreaks. Results
over these years have shown that more sprays were needed within the preventative
spraying programs, as opposed to recommendations of the Metos-2 model, for the same
or even improved control of downy mildew. On the other hand the results of the Metos-2
model compared to the Metos model, gave similar warnings for both primary and
secondary infections. It is however very difficult to get clear similarities/differences
between what the Metos-2 model has calculated and what had really occurred in the
vineyards. This can be attributed mainly to the accumulation effect of downy mildew
infections. With the development of the Downy Mildew Early Warning Model (DSVWmodel),
two important changes were made, namely the leaf wetness was replaced with a
mathematical, non-linear regression and the Metos-2 modelâs âYes/Noâ warnings for
downy mildew infections were replaced with four classes of possible risks. The
calculated leaf wetness of the DSVW-model, that uses measured relative humidity and air
temperature as input values, had a significant coefficient of determination of 0.70,
compared with measured leaf wetness. The DSVW-modelâs four risk classes of possible
infections (primary and secondary) are as follows: zero infection (0 %), low infection (1 -
34 %), medium (35 - 74 %) and a high risk class (75 - 100 %). To test the DSVWmodelâs
accuracy and reliability, historical weather data (1998 - 2003) and measured
disease outbreak data in the Stellenbosch, Robertson and Paarl areas were used to run
both the Metos-2 and the DSVW-models. Primary as well as secondary infections were
predicted by the models. When the DSVW-model and the Metos-2 modelâs infection
warnings were correlated with disease outbreaks, of the two, the DSVW-model showed
consistently similar or better correlations with the measured disease outbreak data. The
DSVW-model also calculated on a regular basis more primary and secondary infections,
than the Metos-2 model, which at times did not warn of any downy mildew infections,
although outbreaks of downy mildew did occur soon after. Producers can use the new
DSVW-model with confidence, together with one or other prevention spray program, for
the control of downy mildew.
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QUANTIFYING RAINFALL-RUNOFF RELATIONSHIPS ON SELECTED BENCHMARK ECOTOPES IN ETHIOPIA: A PRIMARY STEP IN WATER HARVESTING RESEARCHWelderufael, Worku Atlabatchew 13 June 2007 (has links)
Large areas of cultivated land in Ethiopia frequently suffer from drought, causing low
crop yields and food insecurity. It was hypothesized that it may be possible to alleviate
this problem by employing infield rain water harvesting (IRWH). Three representative
semi-arid ecotopes in the Rift Valley were selected to test this hypothesis. They were the
Melkassa Hypo Calcic Regosol, The Dera Calcic Fluvic Regosol and the Mieso Hypo
Calcic Vertisol. The climate, topography and soils of the ecotopes were characterized in
detail.
Rainfall runoff studies were carried out over two rain seasons on replicated plots on these
ecotopes comparing two soil surface treatments. They were conventional tillage (CT),
simulating the initially fairly rough surface which results after normal tillage; and no
tillage (NT), simulating the flat crusted surface expected on the runoff strip of the IRWH
system. Rainfall amounts, rainfall intensity at one minute intervals, and runoff, were
measured for each storm during the two rain seasons on each ecotope. The results were
used to calibrate and validate the Morin & Cluff runoff model in order to enhance the
extrapolation capability of the study results to other similar ecotopes.
The study yielded the following useful results.
· The rainfall pattern on all the ecotopes was characterized by occasional storms with
fairly high amounts and high intensities (Pi) which greatly exceeded the final
infiltration rates of the soil, causing a high proportion of the rain (P) to runoff (R), i.e.
producing a high R/P ratio. For the NT treatment final overall R/P values for the two
seasons on the Melkassa, Dera and Mieso ecotopes were 0.45, 0.52 and 0.32,
respectively. These high values indicate that IRWH should produce a significant
increase in yield due to its ability to reduce R to zero while concentrating the runoff
in the basin area and increasing the water available for transpiration and therefore
increasing yield.
· Because of the textural and mineralogical properties of the topsoils, particularly the
two Regosols soils; they disperse and form crusts easily when impacted by high intensity rain. The result was that after cultivation at the start of the rain season the
surface of the CT treatment soon became very similar to that of the NT treatment.
Accordingly no significant difference was found between the runoff from the NT and
CT plots on the Melkassa Regosol and Dera Regosol. There was, however, a
significant difference in this respect on the Mieso Vertisol with a more stable surface.
· Runoff prediction in all the ecotopes were well done by the M & C model.
· Two separate strategies were developed to estimate the maize yield increase that
could be expected on the Melkassa Regosol by employing IRWH. From the nearby
Melkassa Research Station it was possible to obtain maize yields for 15 seasons
(1989-2003). These were used together with climate data, the CROPWAT model, and
the runoff measurements, to estimate the benefit of IRWH. The two strategies
produced yield increase estimates of 33% and 40% compared to CT.
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INFLUENCE OF LONG-TERM WHEAT RESIDUE MANAGEMENT ON SOME FERTILITY INDICATORS OF AN AVALON SOIL AT BETHLEHEM.Kotze, Elmarie 05 July 2005 (has links)
No abstract available.
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THE EFFECT OF NITROGEN, PHOSPHORUS AND POTASSIUM FERTILISATION ON THE GROWTH, YIELD AND QUALITY OF LACHENALIA.Engelbrecht, G M 05 July 2005 (has links)
Very little is known about the response of Lachenalia to fertilisation when cultivated in
soil. The objective of this study was therefore to quantify the effect of fertilisation on the
growth, yield and quality of Lachenalia in both the nursery and pot plant phases. In order
to achieve this two pot trials for the nursery phase and one pot trial for the pot plant phase
were conducted in the glasshouse.
For the first trial in the nursery phase the combined effect of nine nitrogen levels and
three application times on the Lachenalia cultivars, Rupert and Ronina, were studied.
The nitrogen was applied at levels equivalent to 0, 30, 70, 120, 180, 250, 330, 420 or 520
kg N ha -1 . Three different nitrogen application times were used namely: one third with
planting and the rest 10 weeks after planting (T1); one third with planting and the other
two thirds after planting (T 2) or one quarter with planting and the other three quarters
after planting (T3). The leaf area of Ronina plants was larger than that of Rupert plants
irrespective of nitrogen levels and application times. However, Ronina bulbs were larger
and softer than Rupert bulbs. The nutrient (N, P, Ca and Mg) and carbohydrate (D-glucose,
sucrose and starch) content of Rupert bulbs were higher than that of Ronina
bulbs. Application of nitrogen had a positive influence on the leaf area, bulb fresh mass
and circumference of both cultivars. Bulb firmness was negatively influenced by
nitrogen application. The best results for most parameters were obtained when nitrogen
was applied in four equal applications.
In the second trial for the nursery phase the response of Rupert and Ronina to five
nitrogen (0, 70, 180, 330 or 520 kg N ha -1 ) and five phosphorus (0, 10, 30, 50 or 80 kg N
ha -1 ) or five potassium (0, 70, 180, 330 or 520 kg N ha -1 ) levels were studied. Neither the
interaction between nitrogen and phosphorus levels nor the interaction between nitrogen
and potassium levels had a large influenced on the growth and development of
Lachenalia. Results obta ined in this trial with respect to the effect of nitrogen levels on
the different parameters mainly confirm with the results obtained with the first trial. In the trial for the pot plant phase the effect of seven nitrogen levels (0, 30, 70, 120, 180,
250, 330, 420 or 520 kg N ha -1 ) on Lachenalia grown from 7-8 cm bulbs, whereof the
fertilisation history in the nursery phase differed, was investigated. The fertilisation
history of the bulbs in the nursery phase consisted of three nitrogen levels (0, 70, 250 or
520 kg N ha -1 ) combined with two nitrogen application times (T1, T2 or T3 as described
earlier). The leaf area of Ronina plants was larger than that of Rupert plants. Nitrogen
applied in the nursery phase promoted the leaf area of both Rupert and Ronina.
Application of nitrogen in the nursery phase and in the pot plant phase increased the
number of inflorescence per plant and the number of florets per inflorescence. The
peduncle length increased with higher nitrogen levels in the nursery phase wherea s the
peduncle diameter increased with higher nitrogen levels in the pot plant phase.
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USING SEASONAL CLIMATE OUTLOOK TO ADVISE ON SORGHUM PRODUCTION IN THE CENTRAL RIFT VALLEY OF ETHIOPIADiga, Girma Mamo 30 July 2007 (has links)
Seasonal rainfall is an important source of water for rainfed farming in the semi-arid
regions of the world, where rainfall is marginal and variable. However, as rains are
unpredictable in terms of onset, amount and distribution, there is a need to
understand the variability and other basic rainfall features in order to use the
information in agricultural decision making. More specifically, combining the seasonal
rainfall prediction with crop water requirement and soil water information is the core
component to successful agriculture. The ultimate objective of this study was to
characterize and obtain a better understanding of the most important rainfall features
that form the basis for classifying the areas into homogenous rainfall zones and then
to develop a seasonal rainfall prediction model for the Central Rift Valley (CRV) of
Ethiopia.
The source data for the analyses was primarily obtained from the National
Meteorological Services Agency (NMSA) and partly from Melkassa Agricultural
Research Centre (MARC) and the web site of the International Research Institute for
Climate and Society (IRI). Rainfall variability and time series analyses were done using
INSTAT 2.51 and coded time method, respectively. Rainfall onset and March-April-
May (MAM) rainfall totals are the two most variable features both at Miesso and
Abomssa. For both stations, rainfall end date displays the least variability.
Rainfall onset date at Miesso ranges from the lower quartile (25 percentile) of DOY 61
to the upper quartile (75 percentile) of DOY 179 with a 42% coefficient of variation
(cv). At Miesso, the main rainy season terminates during the last days of September (DOY 272 - 274) once in four years and terminates before DOY 293 in three out of
four years. At Abomssa, the c.v for the lower quartile (DOY 61) to the upper quartile
(DOY 134) was found to be 40.5%. At both locations, planting earlier than 15 March
(DOY 75) only proves successful once in every four years. Further, at Miesso this
upper quartile statistic can extend up to the DOY 179, whereas at Abomssa planting
earlier than 15 April (DOY 134) is possible in three out of four years (75 percentile). At
Abomssa, rainfall terminates by DOY 286 and the end of October (DOY 305) for the 25
and 75 percentile points respectively. From the time series analyses, there was no
conclusive evidence for the existence of a trend for both Miesso and Abomssa,
information which is useful for long-term research and development planning, as well
as seasonal rainfall prediction for the study area.
The classification study for the spatial rainfall pattern resulted in four homogenous
rainfall zones that form distinct development and research units, using the FORTRAN-
90 based NAVORS2 program. The south facing Alem Tena-Langano zone has a better
rainfall pattern than drier zones and thus formed zone 1. The southern, southwestern
and southeastern area has formed the wet zone (zone 2), the northwestern to
northeastern facing part (Debre-Zeit-Nazerth-Dera) that receives a higher rainfall
amount than zone 1 has formed zone 3 and finally, the drier northeastern part
constituted zone 4. Twenty seven seasonal rainfall prediction models with varied
performance skills that can be used for the operational farming were developed for the
March-September monthly rainfall using the Climate Predictability Tool (CPT v.4.01)
from IRI. It was understood that with increased observing networks and data
availability, useful operational climate prediction could be achieved for a smaller
spatial unit and with a short lead-time.
The tempo-spatial water requirement satisfaction pattern analyses were conducted
using AGROMETSHELL v.1.0 of the FAO. Fourteen concurrent sorghum-growing
seasons that give a general picture of crop water requirement satisfaction were
mapped. The southern, southwestern and southeastern parts (zone 2) of the CRV
constitute the most favourable location for growing a range of sorghum maturity
groups. The northwestern and central (zone 3) parts constitute the next most suitable
zone. The wide northeastern drylands (zone 4) of the study area, except the pocket
area of Miesso-Assebot plain, does not warrant economic farming of sorghum under
rainfed conditions. From the growth stage-based Water Requirement Satisfaction Index (WRSI) analyses,
mid-season / flowering stage of the sorghum cultivars was found to be three times
more sensitive to changes in sorghum yields for both cultivars and experimental sites
as compared to the WRSI from the rest of growth stages. The results from the water
production function analyses (WPF) also indicated the potential of WRSI for prediction
of the long-term sorghum yields.
The cumulative density function (CDF) and stochastic dominance analyses for the
120-day grain sorghum cultivar grown at Miesso show the June planting to be the
most efficient set by first degree stochastic dominance (FSD), while May was found
efficient for Melkassa. The CDF for Arsi Negele shows April planting date to be the
best set. Therefore, these planting dates are to be preferred by farmers seeking âmoreâ
yield at the respective locations, regardless of their attitude towards risk.
The sensitivity analyses conducted using different levels of the seasonal rainfall
related input variable combinations (sorghum planting date, maturity date, number of
rainy days and WRSI) for Miesso, Melkassa and Arsi Negele provide useful
information. By keeping input variables other than WRSI at the most preferred level
(i.e. early planting date, extended maturity date, and greater number of rainy days)
and only changing WRSI from 100% to 75% resulted in a 49.7% yield reduction in
case of Miesso, 40.8% in case of Melkassa and 24.3% in case of Arsi Negele. Further,
when WRSI was reduced down to 50%, there was a total crop failure in the case of
Miesso and Melkassa, while the reduction was 48.6% for the Arsi Negele case. Similar
results were found when WRSI was varied across other input level combinations.
Visual Basic v.6.0 was used to write the algorithm for the decision support tool (DST)
relating sorghum planting dates in CRV, to which the name ABBABOKA 1.0 was
given. By using the rainfall prediction information from three different sources (the
new prediction model developed in chapter 3, NMSA and ICPAC), ABBABOKA
suggests the best possible planting alternatives for a given homogenous rainfall zone
and planting season. When decision making under this predictive information alone is
not sufficient, soil water parameters need to be consulted for more reliable decision
making. This simple and briefly constructed ABBABOKA is expected to provide a suite
of guidelines to the users. Certainly, this constitutes a significant departure from the
fixed âbest betâ recommendations I learned from research systems in the past. It is recommended that the time-space classification of agricultural areas into
homogeneous zones needs to be extended to the rest of the country together with the
tailored rainfall prediction information. Research needs to be geared towards crop
water requirements, climate risks and simulation modelling aspects. A network of
weather stations and soil database needs to be developed in order to promote the soilcrop-
climate research in Ethiopian agriculture. More importantly, the use of decision
support tools and the well-established models (like APSIM) need to be included in
agricultural research and development efforts.
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CAUSES AND IMPACT OF DESERTIFICATION IN THE BUTANA AREA OF SUDANElhag, Muna Mohamed 30 July 2007 (has links)
Desertification is one of the most serious environmental and socio-economic problems of
our time. Desertification describes circumstances of land degradation in arid, semi-arid
and dry sub-humid regions resulting from the climate variation and human activities. The
fundamental goal of this thesis was to monitor the extend and severity of the land
degradation and examine climate variability and change in the Butana area of northeastern
Sudan.
To explore the climate variability and climate change in terms of rainfall, temperature
and the aridity index for the period from 1941 to 2004, the monthly and annual time
series for four weather stations (El Gadaref, Halfa, Wad Medani and Shambat) across the
Butana area were analysed. The trend of the rainfall at Wad Medani and Shambat shows
significant decline, while that of Halfa and El Gadaref does not show a significant
decrease or increase. The Cumulative Rainfall Departure (CRD) was used to detect the
periods of abrupt changes in the rainfall series. A significant decrease in the annual
rainfall was observed at Shambat (p = 0.00135) and Wad Medani (p = 0.0005) from 1968
to 1987, there after the rainfall amount is close to the long-term mean. In El Gadaref there
was a decline in the annual rainfall from 1971 to 1974 (p = 0.35) but it was not
significant, with a recovery from 1975 to 1982 to a value higher than the long-term mean,
followed by another downward turn from 1983 to 1994. In Halfa there was a significant
decrease (p = 0.0304) from 1982 to 1993. The trends of maximum and minimum
temperature were examined for the summer (March-May), autumn (June-October) and
winter (November-February) seasons for the four weather stations. At Halfa and Shambat
the trend of maximum and minimum summer and winter temperature was increasing but not significant, while in Wad Medani there was a significant increase for summer and
winter minimum temperatures. El Gadaref station showed a significant increase in
maximum and minimum temperature (p = 0.00005, p = 0.00016) respectively. The
minimum autumn temperature for Halfa increased significantly, while this was the case
for both the minimum and maximum autumn temperature at Shambat and Wad Medani.
This significant increase in temperature, associated with autumn, is partly due to dry
conditions observed during the late 1960s.
The relationship between 8 km2 AVHRR/NDVI and rainfall data (1981-2003) was tested
in the Butana area. The relationship was strong between the peak NDVI (end of August
through the beginning of September) and cumulative July/August rainfall, but weak
relationships resulted when annual rainfall and cumulative NDVI were used. The
Departure Average Vegetation method showed that the area had a high percentage of
departure, reaching about 40% of the long-term average during the drought years and the
NDVI recovered during the following year if the rainfall was above average. There were
increased trends in NDVI in the study area during the period from 1992 to 2003, despite
some years during this period having higher departure although that departure was less
than for the period 1981-1991. To monitor the impact of human activities on land
degradation it is essential to remove the effects of rainfall on vegetation cover. Using the
Residual Trend Method the differences between the observed peak NDVI and the peak
NDVI predicted by the rainfall was calculated for each pixel. This method identified
degraded areas that exhibit negative trends in NDVI. The human impact is more clear in
the northern part.
Satellite imagery provides an opportunity to undertake routine natural resource
monitoring for mapping land degradation over a large area such as Butana over a long
time period. This facilitates efficient decision making for resource management. Five
classes of land use were achieved using unsupervised classification, whereafter an image
difference technique was applied for 1987-1996 and 1987-2000. This analysis showed
that the bare soil and eroded land increased by 3-7% while the vegetated area decreased
by 3-6%. Also when comparing the aerial photographs (1960s and 1980s) for Shareif Baraket, Kamlin and El Maseid with Landsat images (2000) severe degradation of the
vegetation cover was visible at all the three sites.
The Moving Standard Deviation Index (MSDI) is calculated by performing a 3Ã3 moving
standard deviation window across the band 3 Landsat images (1987, 2000). MSDI proved
to be a powerful indicator of landscape condition for the study area. The MSDI increased
considerably from 1987 to 2000, especially for Sufeiya, Sobagh and Banat areas, which
are referred to as severely degraded sites in the literature. The Bare Soil Index (BSI)
supports the finding from the MSDI. The BSI for the degraded sites Sufeiya, Sobagh and
Banat increased from 0-8 in 1987 to 32-40 in 2000. The image difference of the BSI
indicated that the index increased by about 14-43 over the 13 years.
A Microsoft Excel macro was used to write the algorithms for a decision support tool
relating the factors that trigger and propagate desertification in arid and semi-arid areas.
This was named âTashurâ. Rainfall, aridity index and NDVI were used to evaluate the
condition of the landscape. If these three parameters alone were not sufficient to make a
decision, then soil and human activity parameters need to be consulted for more reliable
decision making. This simple and concise decision support tool is expected to provide
guidelines to planners and decision makers.
Different ecosystems in the Butana area are subjected to various forms of site
degradation. The desertification has led to sand encroachment and to accelerated
development of dunes and also increased the water erosion in the northern part of the
area. The area has also been subjected to a vegetation cover transformation. Pastures have
deteriorated seriously in quality and quantity, but in many parts the degradation is still
reversible if land use and water point sites are organized.
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EFFECT OF TILLAGE SYSTEM, RESIDUE MANAGEMENT AND NITROGEN FERTILIZATION ON MAIZE PRODUCTION IN WESTERN ETHIOPIADilallessa, Tolessa Debele 30 July 2007 (has links)
The sustainability of maize production in western Ethiopia is in question despite of
favorable environmental conditions. A major reason for this phenomenon is severe soil
degradation in maize fields. This soil degradation manifested often in low soil N fertility
which inhibited maize yields. The situation is worsened by the financial inability of most
farmers to purchase N fertilizer for supplementation.
In these conditions two basic approaches can be followed to improve maize productivity in a
sustainable way. Firstly, integrated cropping practices can be developed for maize to make
better use of N from organic and inorganic sources. Secondly, maize genotypes can be
selected that are superior in the utilization of available N, either due to enhanced uptake
efficiency or because of more efficient use of the absorbed N. In this context, experiments
were conducted to determine the integrated effects of tillage system, residue management
and N fertilization on the productivity of maize, and to evaluate different maize genotypes
for N uptake and use efficiency.
The experiments on integrated cropping practices were done from 2000 to 2004 at five sites
viz. Bako, Shoboka, Tibe, Ijaji and Gudar in western Ethiopia. They were laid out in a
randomized complete block design with three replications. Three tillage systems (MTRR =
minimum tillage with residue retention, MTRV = minimum tillage with residue removal and
CT = conventional tillage) and three N levels (the recommended rate and 25% less and 25%
more than this rate) were combined in factorial arrangement. Every year yield response,
usage of applied N and changes of some soil properties were measured. In 2004 the same
experiments were used to monitor the fate of applied N in the soil-crop system. Labeled urea
was applied at the recommended rate to micro plots within the MTRR and CT plots for this
purpose. During the initial two years of the experiments, there was no significant difference in grain
yield between MTRR and MTRV and both were significantly superior to CT. However,
during the final two years of the experiments, there was no significant difference between
MTRV and CT and both were significantly inferior to MTRR. On average, the grain yield of
MTRR was 400 and 705 kg ha-1 higher than that of MTRV and CT, resulting in consequent
increases of 6.6 and 12.2%, respectively. The application of N increased the grain yield
regardless of tillage system. An application of 92 kg N ha-1 was significantly superior to 69
kg N ha-1, but on par with the 115 kg N ha-1 application. Hence, the recommended
fertilization rate of 92 kg N ha-1 for conventional tilled maize was also found adequate for
minimum tilled maize in western Ethiopia. This rate remained economically optimum with a
20% decrease in the maize price and a 20% increase in fertilizer cost.
The grain differences resulted from the tillage systems and concomitant residue management
were attributed to significant changes in some soil fertility parameters, especially in the
0-7.5 cm layer. After five years both indices of organic matter, viz. the organic C and total N
contents were significantly higher in the MTRR soils when the CT soils serve as reference.
Similarly, the extractable P and exchangeable K contents of the MTRR soils were also
higher than that of the CT soils. The only negative aspect of MTRR in comparison with CT
was a decline in soil pH.
A significantly higher grain N content was recorded with MTRR than with MTRV and CT.
The stover N content was not significantly affected by the three tillage systems. However,
grain, stover and total N uptake were consistently superior with MTRR compared to MTRV
and CT. The NAE, NRE and NPE of maize for the same tillage system were consistently
higher at the lower N level range of 69-92 kg ha-1 than at the higher N level range of 92-115
kg ha-1. At the lower N level range NAE and NRE were larger with CT than with the other
two tillage systems. Both indices were higher with MTRR than with the other two tillage
systems at the higher N level range. The NPE was not significantly affected by the tillage
systems. However, the trend at both N level ranges was higher with MTRR than with
MTRV and CT. The labeled urea study showed that the grain, stover and total biomass N derived from
fertilizer was consistently higher for CT than MTRR. Conversely, grain, stover and total
biomass N derived from soil was consistently higher with MTRR than CT. Therefore, the
fertilizer N recorded in the MTRR soils was higher with MTRR than CT and mainly
confined to the upper 45 cm. The fate of fertilizer N was in MTRR: 47% recovered by
maize, 17% remained in the soil and 36% unaccounted for and in CT: 54% recovered by
maize, 12% remained in the soil and 34% unaccounted for.
The experiments on genotype comparison for N uptake and use efficiency were also done at
Bako, Shoboka, Tibe, Ijaji and Gudar. In 2004 the response of five open-pollinated and five
hybrid genotypes were evaluated at six N levels from 0 to 230 kg ha-1 with 46 kg ha-1
intervals.
Only two out of the ten genotypes evaluated qualify as N use efficient. They were the openpollinated
Ecaval 1 and the hybrid CML373/CML202/CML384. These two CIMMYT
genotypes showed consistently higher NAE, NRE and NPE at low and high N applications
as required. This was not the case with the two local genotypes that were included, viz. the
open-pollinated Kulani and the hybrid BH 540. Based on the results that evolved from this study it is clear that:
1. Farmers should be encouraged to practice MTRR instead of CT since this change in
tillage system could improve the productivity of maize on Nitisols in western Ethiopia.
2. On these Nitisols the conversion from CT to MTRR need not coincide with an adaptation
in the recommended fertilization rate of 92 kg N ha-1.
3. The planting of N use efficient maize genotypes on Nitisols must be advocated to farmers,
especially those who can not afford proper fertilization. Aspects that need to be investigated in future are:
1. Quantification of N mineralization and immobilization in the Nitisols when subject to
MTRR and CT for maize production.
2. Losses of fertilizer N through volatilization, leaching and denitrification from the Nitisols
when subject to MTRR and CT for maize production.
3. Suitability of other soil types which are used for maize production in western Ethiopia for
MTRR instead of CT.
4. Performance of the N use efficient genotypes on other soil types which are used for maize
production in western Ethiopia.
5. Crop rotation with N fixing crops.
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EFFECT OF VARYING DEGREES OF WATER SATURATION ON REDOX CONDITIONS IN A YELLOW BROWN APEDAL B SOIL HORIZONJennings, Kimberly 05 September 2008 (has links)
Various studies have been conducted into redox potential (Eh), redox indicators and the
measured soil water contents in soil (Franzmeier et al., 1983; Schwertmann & Fanning,
1976; Veneman et al., 1976). Although a measure of success has come from these studies,
there are still vast knowledge gaps within this field.
The degree of water saturation where reduction in the soil is initiated cannot be determined
from literature, although it was approximated that 70% of water saturation (S0.7) was
sufficient to initiate reduction (Van Huyssteen et al., 2005). This value will vary for different
soil temperatures, varying bulk densities as well as soils with different organic matter
contents.
This study aimed to determine if it was possible to identify a degree of water saturation at
which reduction is initiated for a soil in a closed system. It also aimed to determine the
effect of bulk density on reduction. Reduction was defined by a decrease in pe (Eh) of a soil
and an increase in the soluble Fe2+ concentration. There were three key aims to the study:
to establish the relationship between the degree of water saturation (s) and the onset of
reduction; to establish the relationship between the degree of water saturation (s) and the
duration of reduction and to establish the effect of bulk density on the above-mentioned
processes.
A yellow brown apedal B horizon from an Avalon soil form (profile 234) in the Weatherley
catchment was used in this study. A soil core experiment was carried out to determine the
effect of degree and duration of water saturation on Eh, pH, Fe2+, Mn2+, Ca2+, Mg2+, K+, and
Na+. Soil cores were packed to a bulk density of 1.6 Mg m-3 and individually saturated to
S0.6 (60% of the pores saturated with water), S0.7 (70% of the pores saturated with water), S0.8
(80% of the pores saturated with water), and S0.9 (90% of the pores saturated with water).
Measurements were done in triplicate. The cores were sealed with a double layer of plastic
wrap and stored in a laboratory at 23°C until needed. Analysis started three days after initial
water saturation. A set of cores (four degrees of saturation with triplicates of each) was
analysed every 3.5 days for the first three months after which a set was analysed once a
week for the remaining month of analyses. The experiment was terminated after 121 days. The same soil and experimental setup was used for the bulk density experiment. The
experiment consisted of a set of three cores packed to an initial bulk density of 1.4, 1.6 and
1.8 Mg m-3. The cores were all saturated to S0.8, each packed in triplicate. The bulk density
experiment was terminated after 23 days.
There was a good correlation between an increase in degree of water saturation and pe
(R2 = 0.95); Mn2+ (R2 = 0.91) and Fe2+ (R2 = 0.92) concentrations. Eh, pH, Fe2+, Mn2+, Ca2+,
Mg2+, K+, and Na+ were significantly affected by duration of water saturation and all except
Ca2+ and K+ significantly affected by degree of water saturation. Fe2+ and Mn2+
accumulations and depletions (visible segregations or mottles) occurred within 12 months of
water saturation in a separate experiment where cores were packed to a bulk density of 1.6
Mg m-3 in a core saturated to S0.9. It was therefore evident that this soil with 0.22% organic
carbon and a bulk density of 1.6 Mg m-3 will produce morphological features due to
reduction within a year of water saturation at S0.9.
An experiment was set up with cores kept at a constant degree of water saturation (S0.8) with
varying bulk densities, namely 1.4, 1.6 and 1.8 Mg m-3. All the factors measured (Eh, pH,
Fe2+, Mn2+, Mg2+ and K+) except Ca2+ and Na+ were significantly affected by a variation in
bulk density. In another part of the experiment two different water temperatures were used
to saturated the cores, namely 23°C and 30°C respectively. It was determined that the
temperature difference of 7°C caused the cores to react significantly different to each other..
The higher water temperature caused the Eh to decrease more rapidly and therefore a
higher Fe2+ concentration occurred in these cores.
It was concluded that for this soil at 23°C, Fe3+ and to a certain extent Mn4+ will start to
become reduced at a pe of 6 at S0.78. These findings show that the first approximation of
Van Huyssteen et al. (2005) where S0.7 was found to be sufficient for reduction is very
similar for this soil.
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A THREE MONTH STREAM FLOW FORECAST FOR WATER MANAGEMENT IN THE UPPER OLIFANTS CATCHMENTPhahlane, Mmotong Obed 05 September 2008 (has links)
A Climate Predictability Tool was used to evaluate the relationship between sea-surface
temperatures and stream flow at different lead-times in the upper Olifants catchment in
Mpumalanga, South Africa. Four stream flow stations were selected from each of the subcatchments
of the upper Olifants, namely the Groot Olifants on the eastern side and the
Wilger on the western side of the catchment.
Canonical correlation analyses were used to make three month stream flow forecasts for
October-November-December (OND) and January-February-March (JFM) seasons.
Monthly global-scale SSTs were used to evaluate the effect of lead-times on correlations
between global Sea-Surface Temperatures (SSTs) and stream flow. Then the lead-times
with Pearsonâs correlation values greater than 0.50 were selected to be used for evaluating
possible origins of stream flow forecasting skill in the Equatorial Atlantic, Southern
Atlantic, Equatorial Indian and Pacific Oceans.
Although local climatic and hydrological characteristics were not considered in this study
good hit score skill from the Southern Atlantic Ocean was found at a short lead-time of
two months for both OND and JFM seasons. The equatorial Atlantic Ocean gave a good
hit skill score at longer lead-times of seven and eight months. The equatorial Indian Ocean
gave a higher Heidke score at a short lead-time of two months during OND and JFM
seasons in the Groot Olifants sub-catchment. The oceanic domains adjacent to the southern
African subcontinent gave a good Heidke score at a shorter lead-time as compared to the
equatorial Pacific Ocean. These forecasts could be used for planning water storage and
releases in dams that are down stream of these stream flow monitoring points.
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