Research Article
Sequential Cropping Effects of Vegetable Cowpea on Cassava in Cassava-cowpea Intercrop, Umudike, Southeast Nigeria
Department of Agronomy, Michael Okpara University of Agriculture, Umudike, Nigeria
LiveDNA: 234.23273
Intercropping, which is a multiple type of cropping system enables component crops to interact and relate with available growth resources (solar radiation, soil nutrients, moisture, temperature and even space) following agronomic principles1-5. Hence, under the system, there is more efficient use of growth resources by component crops either from different rooting levels in the soil, aerial environment, difference in time of growth demand, or different nutrient requirements such as legumes that may use more atmospheric N2 compared to non-legumes that may use reduced soil nitrogen6-8. Also, it encourages a more efficient use and utilization of resources such as moisture, solar radiation and nutrients9,10 as well as reduces the negative effect of weeds, insect pests and diseases11-15. A wide range of previous studies on intercropping by Okpara et al.7, Ennin and Clegg16, Calvino and Monzon17, Bedoussac and Justes18, Hinsinger et al.19, as well as Neugschwandtner and Kaul20 indicated that the system positively impacts on improving not only crop yield and yield components but also yield quality of the component crops in the associated system by direct contact or complementarity or facilitation of growth resources within the cropping circuit for the overall benefits of the companion crops.
Cowpea is not only an important food and forage crop but a valuable commodity crop for farmers in the humid agro-ecological zone of Nigeria21-24. According to Udoh and Ndaeyo4, Ishyaku and Singh25 as well as Santalla et al.26, cowpea can be eaten in the form of dry seeds, green pods, green seeds and tender green leaves and it can also be fed to animals in the form of fodder and feed. Furthermore, the crop has high agronomic value in sustainable farming systems owning to its ability to fix atmospheric nitrogen in the soil, hence, plays a vital role in soil amendments21,27,28.
Cassava is one of the most dominant food security crops in West Africa, especially for some 500 million people residing in the Sub-Sahara region but currently assuming a new status as a major source of animal feed and industrial raw material for bio-energy21,29. Studies have shown that sustainable cassava production depend on the use of genotypes adapted to the environment30-32, the efficacy of the field crop management and its complementarity with other component crops in the mixes, especially legumes33-35. Cassava and vegetable cowpea mixes improve diets, soil fertility and enhance overall crop productivity. However, there is dearth information on intercropping cassava genotypes with contrasting morpho-types with prostrate cowpea (Vigna unguiculata Walp. ssp. Sesquipedalis) using sequential planting technique during the long gestation period of the cassava component crop. Therefore, this study was initiated purposely to assess the crop yield performance, productivity and nutritional status of the soil in cassava-vegetable cowpea intercrop as affected by sequential planting of cowpea in the mixes as a soil fertility booster and live mulch.
Site characteristics: Four cassava cultivars - vegetable cowpea and their respective sole crops were grown at National Root Crops Research Institute, Umudike (longitude 05°29N, Latitude 07°33 E, elevation 122 m.a.s.l.), Nigeria in 2015/2016 cropping season. Total annual rainfall and rain-days during the period of investigation was 2,069 mm and 123 days, respectively (Fig. 1a, b). The rainfall pattern is bimodal (April-July) and (September-November), while the minimum and maximum temperatures of the area were 23.2 and 31.7°C, respectively (Fig. 1). The soil of the experimental site belongs to the order ultisol and classified as Typic (Paleustalt)36. It had low humus content with top sandy texture. It was acidic.
Land preparation, treatment application and experimental design: The experimental field was under fallow for 2 years with vegetation cover which had Panicum maximum, Aspilia africana, Imperata cylindrica, Calopogonium mucunoid, Cyperus rotundus, Mimosa invisa Chromolaena odorata and Ipomoea involucrate. The experimental plots were slashed, ploughed, harrowed and one metre ridges made. The field layout was marked using tape, pegs and ropes. The plots measured 5 m in length and 5 m in width with one and two metre spacing between plots and blocks, respectively. The experiment was laid down in a randomized complete block design with three replicates.
Four cassava cultivars were used in the study. The two high cyanide (NR 8082 and TMS 30572) characterized by high and low branching orders, respectively and two low cyanide (TME 419 and TMS 0505) characterized by erect and high branching orders, respectively, were sourced from the Cassava programme, National Root Crops Research Institute, Umudike, Nigeria while a land race prostrate vegetable cowpea was purchased from a local farmer at Enugu, Nigeria. The nine treatments studied were: (1) monocrop NR 8082 (2) monocrop TMS 30572 (3) monocrop TME 419 (4) monocrop TMS 0505 (5) monocrop vegetable cowpea and their respective intercrops (6) NR 8082//vegetable cowpea (7) TMS 30572//vegetable cowpea (8) TME 419//vegetable cowpea (9) TMS 0505//vegetable cowpea. The sole crop plots of cassava and vegetable cowpea were established as controls and for the computation of land equivalent ratio and other productivity indices required in the system.
Fig. 1(a-b): | Mean monthly rainfall amount and rainfall days, as well as minimum and maximum air temperatures of the experimental site in 2014 and 2015 cropping seasons |
Source: Meteorological unit, National Root Crops Research, Institute, Umudike, Nigeria |
To reduce variability among cassava planting materials, 20 cm cuttings (with 4-6 nodes) were cut out from 80-100 cm of 12 months old stems.
The cuttings were planted slanting (45°) on the crest of the ridges, one meter apart. Three seeds of vegetable cowpea were planted at a spacing of 0.50×1.0 m per hole in May (early cropping season). Supplying missing stands of cassava and thinning of vegetable cowpea seedlings to two per stand to give a plant population of 10,000 and 40,000 plants ha1, respectively were done 14 days after emergence. In mono-cropped cowpea, three seeds that were later thinned to two were planted hole1 at 0.25×1.0 m to give a plant population of 80,000 plants ha1. The first vegetable cowpea was completely harvested four months after planting from all the corresponding cowpea plots and the second cowpea planting (sequential) was introduced immediately after the first crop was removed from the plots.
Plots comprised five rows of cassava to give 25 plants plot1 and vegetable cowpea had ten rows to give 100 plants plot1 in both sole and intercrop. The experimental area was hoe-weeded and the ridges remoulded at three weeks after planting to enable the crops establish properly and allow the quick growing vegetable cowpea to gain vigour and ramify the growing surface area.
Soil sampling and laboratory analysis: The soil samples from the experimental area were collected with the aid of auger from the top 25 cm of the soil from three blocks to have a composite sample, which was bulked and air-dried at room temperature of between 25 and 27°C for 14 days and crushed to pass through a 2 mm sieve. A sub-sample of the soil was collected and subjected to physico-chemical analysis using standard laboratory methods prior to experimentation (Table 1).
Table 1: | Physico-chemical properties of the top soil (0-25 cm) of the experimental site, Umudike, Nigeria in 2015 cropping season |
Source: Soil science laboratory, National root crops research institute, Umudike, Nigeria |
In a similar manner, auger soil samples were collected from three observational points at a depth of 0-25 cm in each of the 36 experimental plots immediately after total harvest of the component crops and used to determine some chemical properties of the soil. The soil samples were air-dried, crushed and sieved with a 2 mm sieve before they were subjected to laboratory analysis.
Growth parameters measured were plant height, number of leaves plant1, number of branches plant1, cassava canopy diameter, plant biomass and yield as well as some yield related parameters. At 12 weeks after planting (WAP), six plants each from the component crops located in the inner rows of the plots were selected, tagged and used for biological measurements.
The plant height (cassava) or vine length (vegetable cowpea) and canopy diameter of cassava were measured with the aid of a meter rule. The plant height was measured from the base of the plant to terminal bud while canopy diameter was determined by placing the metre rule across the diameter of the canopy foliage. The number of leaves plant1 was determined by visual counting of the number of leaves for each component crop. Plant bio-mass of the component crops was determined by recording the weight of whole plant shoots while root shoot ratio and harvest index were determined by calculation. At 12 months after planting, cassava yield parameters collected were root diameter, root length, weight of marketable roots plant1 and fresh root yield (Mt ha1).
At 16 weeks after planting, yield and yield components of vegetable cowpea recorded include number of pods plant1, weight of fresh pods plant1 and fresh pod yield (Mt ha1). The Pod weight plant1 was weighed with triple bean balance (Haus Model) while cowpea crop yields were obtained by harvesting the crops from the net area (4 m2) of each plot and extrapolated to hectare. Vegetable cowpea was harvested when pods were fully filled and matured but still green. The green pod yields in each plot were weighted and recorded.
The biological and economic productivity of the systems were determined by comparing productivity of a given area of intercropping with that of monocrops using functions for land equivalent ratio (LER) (the sum of the ratios of the yields of the intercrops to those of the monocrops) according to Mead and Willey43. The land equivalent coefficient (LEC) of the intercrops was determined as the products of partial LERs from the components crops44 while percentage land saved was determined using the formulae:
According to Willey45.
The gross monetary return ($ ha1) was obtained by multiplying the yield of the component crops with the current market price of the farm produce in the locality at time of harvest. The total cost of production ($ ha1), was calculated considering all operational expenses, beginning with land acquisition, machinery land preparation, purchasing of farm in-puts such as seeds, cuttings and fertilizer, planting, field maintenance to harvesting, initial processing and marketing of farm produce. The net return ($ ha1) was obtained by subtracting the total cost of production from the gross monetary return recorded from the systems and the benefit-cost ratio (BCR), the ratio of net return to total cost of production, was calculated.
Statistical analysis: The data were subjected to analysis of variance (ANOVA) separately for each crop using the General Linear Model of SAS software for randomized complete block design (RCBD)46. The cassava crop was subjected to two-way factorial analysis while the vegetable cowpea was subjected to one-way analysis of variance. Fixed effects were cropping systems and cassava cultivars while replications (blocks) were random effects. The statistical significance of a given factor at different levels of the other factor (simple main effect) was obtained using the least square means (LSMEANS). Mean separation was performed using Fishers least significant difference (F-LSD) at p<0.05 according to Obi47. The Pearsons multiple correlation analyses were carried out on agronomic characters of cassava and vegetable cowpea using PROC CORR of SAS46.
Two-way analysis of variance indicated that cropping system significantly (p<0.05) affected plant height and root diameter of cassava contrary to the other variables (Table 2) while significant variation among cassava genotypes was recorded in number of leaves plant1, plant biomass, harvest index, weight of marketable roots plant1 and fresh root yield of cassava. The interaction between cropping system and genotype indicated significant variation in number of leaves plant1, root/shoot ratio, weight of marketable roots plant1 and fresh root yield of cassava.
The factor interaction between cropping system and genotype (Table 3) indicated that TMS 98/0505 cassava genotype in the mixes had the highest number of leaves plant1, root/shoot ratio, weight of marketable roots plant1 and fresh root yield (Mt ha1) compared with other genotypes in both mono- and intercrop. In contrast, mono-cropped TME 419 cassava genotype had the smallest weight of marketable roots plant-1 and fresh root yield in both cropping systems.
One-way analysis of variance of cropping system and treatment (Table 4) showed that cropping system and treatment effect had no significant (p>0.05) effect on vine length and number of branches plant1. However, in contrast to treatment, cropping system also had no effect on number of leaves plant1. Cropping system and treatment exhibited significant difference to the other assessed variables (plant biomass, number of pods plant1, weight of fresh pods plant1 and fresh pod yield hectare1) of vegetable cowpea. Among the systems, intercropping exhibited lower values in plant biomass, number of pods plant1, weight of fresh pods plant1 and fresh pod yield by 55, 23, 46 and 46%, respectively relative to the mono-cropped cowpea. Intercropped TME 419//cowpea had the highest number of leaves plant1 and number of pods plant1 contrary to the other cassava//cowpea mixes. The fresh pod plant1 and fresh pod yield (Mt ha1) obtained from mono-cropped cowpea weighted more relative to the mixes while cassava TMS 98/0505//cowpea intercrop gave the highest amount of valued fresh pod yield among the intercrops.
Correlation analysis (Table 5) on the cassava component indicated that weight of marketable roots plant1 and root:shoot ratio showed positive and highly significant (p<0.01) correlation with fresh root yield of cassava with correlation coefficients (r) of 0.74 and 0.50, respectively.
Table 2: | Two-way analysis of variance for cropping system, cassava cultivar effects and their interactions on growth, root yield and yield components of cassava in mono- and intercrop |
ns,*, **: Not significant, significant at p<0.05 or p<0.01, respectively. SED: Standard error of difference between means. Analysis of variance |
Table 3: | Effect of cropping system and genotype interaction on some growth and root yield parameters of cassavaa in mono- and intercrop |
ns, *, **: Not significant, significant at p<0.05 or p<0.01, respectively. SED: Standard error of difference between means. Two-way ANOVA, aData in interaction with least squares means and means separation with least significant difference (LSD) |
Table 4: | One-way analysis of variance for cropping system and treatment effects on growth, fresh pod yield and yield components of cowpea in mono- and intercrop |
ns, *, **: Not significant, significant at p<0.05 or p<0.01, respectively, SED: Standard error of difference between means. One-way ANOVA |
Table 5: | Correlation matrix of some cassava plant characters (above diagonal) and some vegetable cowpea plant characters (below diagonal) |
ns: **Correlation not significant or significant at p<0.01(2-tailed), respectively. Above and below diagonals indicate the correlation matrix of the variables of cassava and vegetable cowpea, respectively |
The other variables (number of leaves plant1 and plant height) were not significantly (p>0.05) correlated with all the variables evaluated. In vegetable cowpea, positive and highly significant (p<0.01) correlation was recorded between fresh pod weight plant1 and fresh pod yield, plant biomass and fresh pod yield as well as plant biomass and fresh pod weight plant1 with r = 1.00, 0.73 and 0.73, respectively.
Analyzed core soil samples after total crop harvest (Table 6) indicated significant (p<0.05) variations in soil pH, total nitrogen (N), available phosphorus (Av. P), organic matter (OM) and base saturation (BS) among the treatments. Mono-cropped cowpea had the highest pH value, total N, available P, OM and BS, relative to the other treatments in both mono- and intercrops.
Table 6: | Effect of sequential planting of vegetable cowpea on soil pH and other chemical properties in mono- and intercrop after total crop harvest |
Means in the same column with the same letter do not differ significantly at *p<0.05, **p<0.01. SED: Standard error of difference between means. One-way ANOVA |
Table 7: | Effect of sequential planting of vegetable cowpea on some soil chemical properties in mono- and intercrop after total crop harvest |
Means in the same column with the same letter do not differ significantly at *p<0.05, **p<0.01. SED: Standard error of difference between means. One-way ANOVA |
The results further showed that all the soil parameters evaluated were generally higher in the intercrops and mono-cropped vegetable cowpea compared to the initial values obtained prior to planting. The intercropped plots had higher pH values, total N, available P, OM and BS relative to the mono-cropped cassava plots, except mono-cropped vegetable cowpea.
One-way analysis of variance of soil samples that were collected and subjected to standard laboratory analysis after crop harvests (Table 7) indicated significant variations in exchangeable bases (Na+, K2+, Mg2+ and Ca2+), exchangeable acidity (EA) and effective cation exchange capacity (ECEC). The soil exchangeable bases and ECEC were high in mono- and intercropped cowpea with sequential planting, especially mono-cropped cowpea compared with mono-cropped cassava. In contrast, EA were higher in mono-cropped cassava genotype plots relative to their corresponding intercropped plots and mono-vegetable cowpea plot.
In contrast to partial land equivalent ratio (LER), (Table 8) total LER were all above unity, indicating higher yield productivity in the intercropped system. The crop mixture cassava NR 8082//cowpea gave the highest LER, which was higher by 8, 16 and 14 percent compared with TMS 30572//cowpea, TME 419//cowpea and TMS 98/0505//cowpea mixes, respectively. This implies that an LER>unity could result from low inter-specific competition or strong facilitation among the component crops in the mixes. Land equivalent coefficient (LEC) indicated that intercropped TME 419//cowpea gave the lowest LEC while TMS 8082//cowpea recorded the highest LEC. Competitive ratio (CR) showed cassava as not only the aggressive crop in the system but also the dominant component as an erectophile that ramified much of the aerial space in the intercropping situation while percentage land saved indicated NR 8082//cowpea intercrop had the largest amount of land saved, which was higher by 19, 40 and 34 % relative to TMS 30572//cowpea, TME 419 and TMS 98/0505//cowpea intercrops, respectively.
The economic assessment indicated that mono-cropping had better partial gross monetary returns (GMRs) than the crop mixes (Table 9). However, total GMRs for the intercropping system was higher relative to their mono-cropped equivalents.
Table 8: | Effect of sequential planting of vegetable cowpea on biological productivity of the component crops in mono- and intercrops |
†Partial LER for cassava and vegetable cowpea were obtained by dividing each intercrop yield by its corresponding mono-crop yield, ‡Total LER was the sum of the partial LERs from cassava and vegetable cowpea in the intercropping system, §Dashes indicate no measurements were taken from the corresponding plots because the representative component crop (cassava or vegetable cowpea) was not planted in the plot (mono-crop) |
Table 9: | Effect of sequential planting of vegetable cowpea on the economic productivity of the component crops in mono- and intercrops‡ |
‡Cassava and vegetable cowpea were sold at current market price (₦ kg1) of ₦80 kg1 and ₦200 kg1, respectively, at time of harvest. ₦ is Naira, Nigerian currency, 1 USA Dollar = ₦198:00, †Net return (NR) was the difference between total gross monetary return (TGMR) and variable total costs of production (TCP) of cassava and vegetable cowpea in the mono- and intercrop system while BCR is the ratio of NR and TCP, §Dashes indicate no measurements were taken from the corresponding plots because the representative component crop (cassava or vegetable cowpea) was not planted in that plot (Mono-crop) |
Among crop mixes, TMS 98/0505//cowpea intercrop had the highest monetary return while TME 419//cowpea intercrop gave the lowest financial returns in the systems. Furthermore, the results showed that higher LERs did not automatically indicate highest GMRs, net returns (NRs) nor benefit cost ratio (BCRs). The total cost of production expended in the mono-cropped plots was lower compared to mixes. The net returns among treatments showed TMS 98/0505//cowpea intercrop gave the highest net return. Except mono-cropped cowpea, whose BCR was lower compared with TMS 98/0505//cowpea, the BCRs in the crop mixes were all higher relative to their corresponding mono-crops.
The regression analysis between LER and net return (NR) indicated the relationship as poly-linear, positive (Fig. 2a), which implied that net return ($ ha1) increased as total LER increased from unity upwards up to 1.4 and then stabilized even as LER increased. The same relationship trend was exhibited between LER and benefit cost ratio (BCR). However, BCR increased as LER increased up to 1.25 and then decreased with further increase in total LER (Fig. 2b). Benefit cost ratio exhibited positive, weak linear relationship with total crop yield (cassava+vegetable cowpea, Mt ha1) with coefficient of determination (R2), which is a measure of how well the regression line represents the whole data as 4.697 (Fig. 3a).
Fig. 2(a-b): | Relationship between land equivalent ratio and (a) Net return ($ ha1) and relationship between land equivalent ratio and (b) Benefit cost ratio with quadratic regression lines, respectively |
Fig. 3(a-b): | Relationship between benefit cost ratio, (a) Total crop yield [(cassava+cowpea (Mt ha 1)] and relationship between land equivalent ratio and (b) Percentage land saved with linear regression lines, respectively |
It further explained that 47% of the total variation in total crop yield (cassava+vegetable cowpea, Mt ha1) can be explained by the linear association between benefit cost ratio and total crop yield. Also, LER had positive and very strong linear relationship with percentage land saved (R2 = 0.9976) (Fig. 3b).
The mono-cropped cassava genotype TME 419 had the smallest weight of marketable roots plant1 and fresh root yield in both cropping systems compared with the other tested genotypes. The findings corroborated previous studies by Udealor and Asiegbu48 on Cassava//vegetable cowpea (Vigna unguiculata L. Walp. ssp. sesquipedalis) in Umudike, Nigeria, Sherif and Salem49 on cassava//fodder cowpea (Vigna sinensis L.) in Giza, Egypt, Mbah et al.8 on cassava//soybean (Glycine max L. Merrill) in Umuahia, Nigeria and De Albuquerque et al.50 on Cassava//cowpea (Vigna unguiculata L. Walp.) in Roraima, Brazil, in which they reported that intercropping was significantly beneficial to the cassava component in the system because of wide marginal variations recorded in both growth and yield variables of the crop associated with time of harvest of the component crops in which the cassava had enough time to recover from the competition it experienced after the harvest of the short seasoned legume component crop in the mix as well as benefitted from the nitrogen fixed and decomposed crop left-over (biomass) of the crop. Olasantan51 on intercropping cassava//cowpea or maize under row arrangements, Stern52 on nitrogen fixation and transfer in intercrop systems, San-Nai and Ming-Pu53 on nitrogen transfer between N2-fixing plant and non-N2-fixing plant, Aduramigba and Tijani-Eniola54 on cassava//groundnut (Arachis hypogaea L.) intercrop in their studies on planting densities as well as Udealor and Asiegbu48 on cassava//vegetable cowpea intercrop in their various studies further reported that the leguminous crop provided not only ground cover but also conserved more moisture alongside atmospheric nitrogen fixation and mineralization of bio-materials, which was made available in the crop mixture and invariably of benefit to the companion crop (cassava) in the cropping system.
The intercropped TMS 98/0505 cassava genotype exhibited highest available P and BS in both cropping systems (mono- and intercrop) in contrast to total N and OM. The results corroborate similar works by Mugendi, et al.55, Odedina et al.56 as well as Mbah and Onweremadu57 who reported significant increase in soil pH as organic matter presence in the soil increases due to cumulative increase in alkaline earth materials associated with the mineralization of the materials, thereby increasing soil fertility. The increased presence of soil nutrients in the mono-cropped vegetable cowpea and intercropped plots was due to perhaps crop left-over of the cowpea, which served as live-mulch, soil fertility enhancer through air nitrogen fixation and as a strong soil moisture conservator. Similarly, Owolabi et al.58, Zhang and Li59, Adeleye et al.60 as well as Njoku and Mbah61 submitted that the application of organic amendment enhances soil exchangeable cations, reduces exchangeable acidity and invariably increases soil base saturation, which is achieved through the process of buffering during mineralization of the organic materials.
An assessment of the productivity of the systems indicated that our findings corroborated similar biological productivity results from intercropping studies by Udealor and Asiegbu31 on cassava//vegetable cowpea mixture, Cenpukdee and Fukai30 on cassava//maize (Zea mays L.)//melon (Citrullus colocynthis L.) of the family Cucurbitaceae intercrop, Mutsaers et al.62 on cassava-based intercropping with legumes, Olasantan et al.63 on cassava//maize intercrop. Furthermore, Zhang and Li59 on competitive and facilitative interactions in intercropping systems, Ayoola and Makinde64 on contrasting cassava cultivars//legume intercrop, Njoku and Muoneke35 on cowpea//cassava mixture as well as Salau et al.65 on cassava//pumpkin (Cucurbita moschata Duchesne) intercropping systems showed that the legume or cereal component crop, which was less competitive for growth resources with the erectophile cassava at critical stages of growth of the component crop significantly contributed to yield advantage obtained in the mixes because the productivity indices were above unity relative to the monocrops.
The yield advantage achieved in the mixes could be due to better utilization of available growth resources coupled with complementary synergy between cassava an erectophile and vegetable cowpea, a planophyll and nitrogen fixer. These observations were consistent with Mbah et al.8 on cassava//soybean (Glycinemax L. Merrill) intercropping, Udealor and Asiegbu48 on cassava//vegetable cowpea intercrop, Njoku and Muoneke35 oncowpea//cassava mixture as well as Nyi et al.66, Ndonda et al.67 in cassava and groundnut (Arachis hypogea L.) of the family Fabaceae intercrop in which they surmised from their various studies in diverse locations that productivity in intercropping situation becomes relevant when subjected to real monetary value vis-à-vis mono-cropping, which showed yield advantage of intercropping over monocropping. The results further showed that intercropping improved cassava root and vegetable cowpea fresh pod yield as well as the fertility of the soil hence, could be considered a reliable and economically viable system for production of the component crops under tropical agro-ecological conditions.
The results showed that intercropping NR 8082cassava cultivar with vegetable cowpea gave higher crop yields compared with the other intercrops. The bio-productivity indices (LER, LEC and %-land saved) indicated that NR 8082//cowpea intercrop exhibited highest yield advantage in the systems. However, financial analysis indicated that in terms of total gross monetary return (TGMR), net return (NR) and benefit cost ratio(BCR), TMS 98/0505//cowpea intercrop was more productive in both mono- and intercrop. Therefore, farmers in the region can be encouraged to intercrop TMS 98/0505 cassava cultivar with cowpea for sustainable higher crop and economic yield.
The efficiency of sequential cropping of vegetable cowpea in cassava-based cropping system depends on the morpho-type of the cassava cultivar used and the growth vigour of the vegetable cowpea. Our findings showed that intercropping NR 8082 or TMS 98/0505 cassava cultivars with vegetable cowpea was beneficial. More so, sequential cropping of vegetable cowpea in a cassava-based cropping system significantly improved the nutrient status of the soil, which was of benefit to the cassava component. Hence, the sequential cropping of the short-duration, soil fertility improving legume crops such as vegetable cowpea served as a viable avenue in reducing the cost of production, improve environmental status in cassava-legume intercrops and guarantee higher economic crop yield.