Groundwater table depth at both sit

Groundwater table depth at both sites
At both sites in both years, water table depth decreased
as rainfall increased. The water table was deeper at both
sites in 2002 with lower rainfall than in 2001.

It was also deeper in the fringe than the other positions at both sites and years.

The shallowest water table depth attained at
Ibadan ranged from 0.15 to 0.40 m in 2001 and from 0.35
to 0.45 m in 2002, while at Alabata it ranged from 0.45 to
0.50 m in 2001 and from 0.51 to 0.58 m in 2002 below
the 0.6 m-high mound surface

Dry tuberous root yield
Improved cultivars had significantly higher root yields
than the landrace across toposequence positions at both
sites in both years.

However, TMS 91/02324 and TMS
91/02327 had similar but significantly higher yields than
TMS 4(2)1425.

Across cultivars in 2001, the highest yield
was obtained in valley bottom and the lowest in valley
fringe at Alabata, while in 2002 at Alabata and in both
years at Ibadan the highest yield was produced in the
fringe and the lowest in valley bottom.

This led to significant toposequence position × site, toposequence position × year, site × year and toposequence position × site × year interactions. Root yield was about 55% higher in 2001 than 2002 and 46% higher at Alabata than Ibadan.

Number of leaves
On average, the improved cultivars had higher number of
leaves than the landrace, with TMS 4(2)1425 producing
significantly more leaves than the other improved
cultivars in all toposequence positions at both sites in
both years.

Plants in the fringe recorded significantly
higher number of leaves than the other positions at both
sites in both years. In all cases plants in valley bottom
produced the lowest number of leaves.

Leaf number was
about 33% higher in 2001 than 2002. Site × year
interaction was significant because leaf number was higher at Alabata than Ibadan in 2001, but in 2002, it was
higher at Ibadan than Alabata .

Rate of leaf formation
The landrace, TMS 4(2)1425 and TMS 91/02324 had
similar rate of leaf formation, but the landrace and TMS
4(2)1425 formed leaves at faster rate than TMS 91/02327
across toposequence positions, sites and years. Rate of
leaf formation was higher at Ibadan (27%) than Alabata
and was also higher in 2001 than in 2002, but this was
more pronounced at Alabata (83%) than at Ibadan (24%).
Rate of leaf formation was affected by toposequence
position × site interaction as it was lowest in valley fringe
and highest in valley bottom at Alabata, while at Ibadan it
was highest in the fringe and lowest in valley bottom.
Toposequence position × year interaction was significant
due to the fact that rate of leaf formation in 2001 was
highest in valley bottom and lowest in valley fringe, but
the reverse was the case in 2002 .

Leaf area index
TMS 4(2)1425 had the highest leaf area index (LAI),
followed by TMS 91/02324 and TMS 91/02327, while
Isunikankiyan had the lowest LAI across toposequence
positions at both locations in both years. Plants in valley
fringe produced higher LAI than those in other positions,
with plants in valley intermediate and bottom registering
similar LAI at both sites and in both years. LAI was about
60% higher in 2001 than in 2002 and was 41% higher at
Alabata than Ibadan. Cultivar x site and cultivar x year
interactions were significant because at Alabata, TMS
91/02327 had lower LAI than the landrace but the reverse
was recorded at Ibadan. Similarly in 2001, TMS 4(2)1425
had larger LAI than TMS 91/02324 but in 2002 the
reverse was the case.

Canopy area
Generally, in each toposequence position at both sites in
both years, the three improved cultivars had significantly
larger canopy area than the landrace cultivar. Plants in
valley fringe had larger canopy area than the other
positions, with the other two positions producing similar
canopy area at both sites in both years. Canopy area was
about 40% higher in 2001 than in 2002 and about 34%
larger at Alabata than Ibadan. The interaction effects on
canopy area were not directional since cultivars changed
their rankings only slightly over toposequence positions,
sites and years .

Stay-green score
Stay-green score (SGS) of the landrace was significantly
higher than the other cultivars, with the improved cultivars
Lahai et al. 41
having similar SGS across toposequence positions at
both sites in both years. The lower the SGS the better
the stay green ability, indicating that SGS of the improved
cultivars was better than that of the landrace. Plants in
valley fringe had better SGS than those in valley bottom.
Also, SGS in 2001 was better than in 2002 at Alabata,
but the reverse was noted at Ibadan. Mean SGS at
Alabata was better than that at Ibadan. Toposequence
position × site × year interaction was noted. At Alabata, in
both years, the fringe had the lowest, while valley bottom
had the highest SGS. At Ibadan, in 2001, the fringe had
the lowest and valley bottom had the highest, but in 2002,
valley bottom had the lowest and the fringe had the
highest score .

Associations of canopy parameters with yield, water
table depth and weather variables
Number and rate of leaf formation, LAI and canopy area
correlated positively with yield at both sites. SGS related
negatively with yield at Alabata. At Ibadan, water table
depth had negative relationship with leaf number, rate of
leaf formation, LAI and canopy area, but positive
association with SGS, whereas at Alabata, SGS
correlated negatively with water table depth. Leaf
number, rate of leaf formation, LAI and canopy area
related positively with rainfall, minimum temperature and
relative humidity, but negatively with evaporation, solar
radiation and maximum temperature .