Experimental site

A two-year (2014 and 2015 growing seasons) study was carried out at the International Institute of Tropical Agriculture (IITA) experimental stations at Zaria (11°11’N, 7°38’E, 686 m asl) in the northern Guinea savanna and at Iburu(10^o16’N, 7^o46’E, 662 m asl) in the southern Guinea savanna. In 2014, the minimum and maximum air temperatures during the experimental period were 20.1 and 30.9°C (Zaria) and 20.8 and 31.2 °C (Iburu), respectively. In 2015, minimum and maximum air temperatures were 20.8 and 31.4°C, respectively in Zaria. In Iburu, minimum air temperature was 21.1°C and maximum temperature was 31.2 °C. The total rainfall received during the experimental period in 2014 was 941.6 mm in Zaria and 1071.0 mm in Iburu. In 2015, total rainfall was 911.6 mm in Zaria and 1285.0 mm in Iburu (Figure 1). Weather information was collected using WatchDog 2000 Series Weather Stations (Spectrum Technologies, Aurora, Colorado, USA), installed at the trial sites. Prior to establishment of the trials, soil samples were taken from each location in both years and analyzed using routine procedures prescribed by IITA (1982). The dominant soil type in Zaria was chromic acrisols while that of Iburu was cambic umbrisols (World Reference Base-FAO http://www.fao.org/soils-portal/soil-soey/soil-classification/world-reference-base/en/). The results of soil analysis showed that in Zaria, the soil had 490 g kg⁻¹ sand; 330 g kg⁻¹ silt; 180 g kg⁻¹ clay; organic C of 8.6 g kg⁻¹; N, 0.79 g kg⁻¹; Mehlich P, 12.7 mg kg⁻¹; K, 0.26 cmol kg⁻¹ and pH 6.5. In Iburu, the soil had 560 g kg⁻¹ sand; 240 g kg⁻¹ silt; 200 g kg⁻¹ clay; organic C of 5.5 g kg⁻¹; N,0.65 g kg⁻¹; Mehlich P, 2.9 mg kg⁻¹; K, 0.16 cmol kg⁻¹ and pH 5.

Figure 1. Monthly rainfall during the growing periods in (a) Zaria (b) lburu.

Treatments and experimental layout

There were four treatment combinations in the experiment: sole maize (M); sole soybean (S); maize spaced at 50 cm and intercropped with soybean (MS50); and maize spaced at 65 cm and intercropped with soybean (MS60). Early maturing maize (Zea mays L.) variety 2009 EVDT (mature between 80–85 days) and a medium maturing soybean ({Glycine max (L.) Mer.} variety TGX1951-3F (mature between 100– 110 days) obtained from IITA were used in this study. The experiment was laid out in a randomized complete block design with three replications. The experimental field was disc-harrowed and ridged before planting. Each treatment plot had four 5 m-long rows with spacing of 0.75 m between rows. For sole and intercropped maize, planting dates in 2014 were June 21 at Zaria and June 17 at Iburu. In 2015, planting dates were June 30 in Zaria and July 1 in Iburu. Sole maize was planted on the ridges at an intra-row spacing of 50 cm between plants stand with four maize seeds sown per stand and later thinned to two plants per stand. This gave a plant population of 53,333 plants ha⁻¹. Soybean was also planted at the same time maize was planted. For sole soybean, seven seeds were planted per stand at intra-row spacing of 10 cm and later thinned to four plants per stand to give a final population of 533,333 plants ha⁻¹. For MS50 intercrop treatment, the maize optimum population was maintained at 53,333 plants ha⁻¹. Soybean was planted between maize having 50 cm spacing between plant stands. Seven seeds of soybean were sown between the maize stands at intra row spacing of 10 cm and later thinned to four plants per stand one week after planting. Similarly, for the MS65 intercrop treatment, soybean was planted between maize spaced at 65 cm between stands at intra row spacing of 10cm per stand. The maize population at intra-row spacing of 65 cm was 41,000 plants ha⁻¹.

Cultural practices

For maize, the recommended fertilizer rate of 120:60:60 of NPK was applied using a compound fertilizer (NPK 15:15:15) to supply 60 kg each of N, P and K ha⁻¹ at two weeks after planting (WAP) as basal application and urea (46% N) to supply the remaining dose (60 kg N ha⁻¹) of nitrogen at 4 WAP. For soybean, recommended rate of 40 kg P₂O₅ ha⁻¹ in the form of Single Super Phosphate was applied to both sole and intercropped soybeans at planting. Gramaxone (1:1-dimethyl-4,4-bipyridinum dichloride, Syngenta Crop protection AG, Switzerland) at a rate of 1 L ha⁻¹ was applied immediately after planting maize using a knapsack sprayer. This was followed by hoe weeding at 4 WAP.

Measurements for IPAR and leaf area index

Leaf area index (LAI) and intercepted photosynthetically active radiation (IPAR) were measured at the flowering stages for both maize and soybean using AccuPAR model LP-80 PAR/LAI Ceptometer (Decagon Devices, Pullman WA, USA). Measurements of incident light above and below the canopies were used to estimate IPAR. Five above and below canopy measurements were taken from each plot and the displayed average was recorded. Three profiles of incident light below canopy were taken: (i) below maize canopy, but above soybean canopy for intercropped maize; (ii) below maize and soybean for intercropped soybean and (iii) the solar radiation measured on top and below the canopy of the sole crops for each plot. The sensor was placed diagonally across the two inner rows, such that the end of the sensor coincided with the line of the plants in each row. LAI of both crops were simultaneously recorded. Measurements were taken under cloud free conditions between 12:00 and 14:00 h. IPAR was calculated as unity minus the fraction of the average below canopy to above canopy measurements of each plot, as follows:

(1) $$\begin{equation} {\rm{IPAR}} = \left[ {1.0-\left( {{\rm{PARb}}/{\rm{PARa}}} \right)} \right] \end{equation}$$

where IPAR is intercepted PAR, PARa is PAR (μmol m⁻² s⁻¹) measured above maize/soybean canopy and PARb is PAR (μmol m⁻² s⁻¹) measured below maize/soybean canopy.

Yield and its components of maize and soybean

Data were collected from the two middle rows of each plot leaving the outside rows as borders. Maize was harvested at 90% physiological maturity. For maize, all the plants in a quadrat (1 × 1.5 m) placed across the two middle rows were harvested for dry matter determination. The samples were separated into leaves, stems and cobs. Leaves and stem were then sun-dried to constant weight. The cobs were shelled, weighed, counted and the grain moisture at harvest was then determined using a Farmex MT-16 grain moisture tester (Farmcomp Oy, Tuusula, Finland). Leaf, stem and grain weight were expressed as g m⁻², which was then used to calculate total dry matter (TDM). The number of grains m⁻² was also estimated. For grain yield determination, the remaining maize plants from the two middle rows excluding the quadrat area were hand-cut at the soil surface. Maize ears were removed, sun-dried for one week and shelled. Grains were weighed and added to those from the quadrat area and final grain yield was expressed as kg ha⁻¹.

Soybean was harvested at pod maturity. A quadrat (1 × 1.5 m) was placed across two middle rows for the measurement of yield components and dry matter. The samples in the quadrats were separated into leaves, stem, pods and grain and sun-dried to constant weight. The weights of leaf, stem, empty pods and grain were expressed as g m⁻² and summed to obtain TDM. The pods in each quadrat were harvested and counted before threshing. The number of pods and seeds in the quadrat were counted and expressed as units m⁻². Pods from all the other plants from the two middle ridges excluding the quadrat area were harvested, threshed and weighed for grain yield. Grain yield (kg ha⁻¹) was calculated based on assumed 12% moisture content. The moisture content of grain samples was determined with the Farmex MT-16 grain moisture tester.

Land equivalent ratio

The relative advantage of intercropping compared to sole cropping was calculated for each proportion using total LER. LER (LER) was calculated as the sum of the ratios of yield of each component crop in intercropping systems to its corresponding yield under sole crop (Mead and Willey Reference Mead and Willey1980):

(2) $$\begin{equation} {\rm{LER}} = \left( {{\rm{Yab}}/{\rm{Yaa}}} \right) + \left( {{\rm{Yba}}/{\rm{Ybb}}} \right) \end{equation}$$

where Yaa and Ybb are the sole crop yields of crops a and b, respectively, Yab is the intercrop yield of crop a, and Yba is the intercrop yield of crop b. In this calculation crop a is maize and crop b is soybean.

Gross monetary value and monetary advantage index

Gross Monetary Value (GMV) and MAI were calculated from the yield of maize and soybean in order to measure the productivity and profitability of intercropping as compared to sole cropping of the associated component crops. Crop value in the systems was calculated by converting the Naira value (₦, Nigerian currency; 1 USD = ₦ 200) to US dollars Monetary returns’ values were estimated based on the current market price of produce during the harvest period. Therefore, GMV was calculated by multiplying yields of the component crops by their respective current market price. MAI was computed as

Statistical analysis

Combined analysis of variance (ANOVA) across years was performed for each location using the PROC Mixed procedure of SAS (SAS Institute, 2012). The significance of the treatment effect was determined using F-test. Differences between two treatment means were compared using LSMEANS statement (with option pdiff) of PROC MIXED code of SAS at 5% level of probability. The statement calculates the difference between two means and the standard error of the difference (SAS Institute, 2012).