1. Introduction
For the past two decades, scientists have hailed genetically modified (GM) crops and chemical fertilizer as the magic bullet that will solve the world’s food crisis [
1]. Farming system design has always been relatively neglected. To overcome future challenges for human kind in terms of land degradation, climate change and population growth, this will demand an all-embracing approach, including the design of sustainable or climate change-resilient farming systems [
2,
3,
4,
5].
Intercropping systems play an important role in increasing crop quality and yield through efficient utilization of land, light, water and soil nutrients [
6], and enhancing resilience to present and future climate change (the increase in global surface temperature and water scarcity) and pest, disease and weed damage [
3,
4]. It is defined as growing individuals of at least two crop species in close proximity at (about) the same time, always leading to harvest at least two different kinds of crop products and higher comprehensive economic benefits. To some extent, sustainable intensification of agriculture by intercropping is a new “Green Revolution” [
7].
The benefit obtained from intercropping is frequently attributed to niche complementarity and interspecific facilitation in resource use due to different temporal, spatial, or plant phenological/eco-physiological characteristics [
8,
9,
10,
11]. Cultivation and farming system practices, including planting density of the component crops, fertilization and irrigation all influenced the degree of interspecific interactions (competition, complementarity and facilitation), the total yield performance and the relative contribution of the individual components [
12,
13,
14,
15,
16,
17,
18]. Yields of crops in intercropping have been reported to fluctuate with component crop populations [
17,
19,
20,
21,
22]. To obtain better productivity or the optimal yield as a major agronomic goal, population density of the component crop should be at the optimum level since plant density is one of the most important agronomic management decisions determining the degree of competition in the intercropping system [
23]. Intercrop components may utilize resources more efficiently than sole crops, thus the optimum plant density in intercrops outweigh the optimum density in sole crop [
24]. In addition, the optimum plant density at one experimental location may not be suitable for other sites, due to regional variations in climate (solar radiation, temperature, precipitation, wind etc.) and soil (pH, organic matter, nitrogen, phosphorus, potassium, salt, soil water hold capacity, etc.) conditions [
17].
Positive relationships between productivity or the community stability of productivity and species richness were observed in a number of experimental ecosystems, especially in grasslands or for herbaceous plant mixtures [
25,
26,
27,
28,
29], which suggested that more diverse communities are more stable and more resistant to invasion, e.g., growing different mixtures of rice varieties suffered less blast incidence and exhibited greater yield than homogeneous fields without the need to use fungicides [
30], and increasing plant diversity with border crops and intercrops [
31,
32] or through a “push-pull” strategy [
33] reduced insecticide use and/or some specific diseases. Intercropping has been shown to increase crop yields and improve resource utilization in many cases, but it is less well-known how the community stability of productivity is influenced by management schemes e.g., population densities of component crops.
At present, China’s cereal grain self-sufficiency has fallen to less than 90%, its self-sufficiency rate of edible oils and fats is less than 35%, and soybean products almost completely (>85%) rely on imports. Yet the country has little spare land. Driven by an urgent need to both produce more cereal grains and more oils/soy proteins, the Chinese government and scientists recently started to seek answers from intercropping of cereals with legumes. For the first time in 30 years, the General Office of the State Council of China issued a document in 2015 to heavily promote crop intercropping, especially for maize-based intercropping with peanut or soybean in Huang-Huai-Hai plain in China. In addition to the higher productivity and land/resource use efficiency, the legume/maize intercropping is much less risky in that if one crop fails another may still have a good return [
21], has lower water consumption and more ecological and environmental benefits compared to sole maize or a cereal-cereal intercropping [
34,
35,
36,
37,
38].
In this study, maize/peanut was selected as a test intercropping system because of its function in the production of cereal grains and oils simultaneously, and its representation for traditional and modern Chinese agriculture. It has evolved from the 1950s to date with changes in social, economic and cultural factors, its planting area in China covers a wide region extending from southern tropical and sub-tropical systems at low latitudes to temperate-cool systems at high latitudes, and it also ranges from arid and semi-arid areas (annual precipitation < 320 mm) to semi-humid and humid areas (annual precipitation > 1000 mm). Meanwhile, it is in harmony with ecological and environmental sustainability, due to the benefits of biological/symbiotic N
2 fixation in legume crops for the improvement of soil fertility [
22,
34,
39].
When maize and peanut are intercropped together, optimizing intercropping management practices can maximize the yield of the intercrop system, and assist in the effective use of space and resources. Here, we examine the effects of increasing maize densities in maize/peanut intercropping on grain/biomass yields of maize and peanut, land equivalent ratios (LERs), plant and ear traits of maize, plant, pod and root traits of peanut and the community stability of productivity across three different experimental sites and years, to guide farmers in improving their practices.
4. Discussion
Increasing intercrop density dramatically influences the competitive dynamics between component crop species because dominance is always enhanced [
17]. In a recent maize/pea intercropping study, the increase of maize planting density could improve the yield of intercropped maize and the partial LER of maize but decreased the grain yields of intercropped pea and corresponding partial LERs [
22]. Similar results were obtained from three different experimental locations/years in this current study, which confirmed that increasing maize densities in maize/peanut intercropping enhanced maize grain/biomass yields but reduced the companion peanut grain/biomass yields (
Table 2 and
Table 4). Therefore, there was a competitive and balanced relationship between the two crop species restricting each other [
44], the higher maize yields were achieved at the expense of peanut yields. No matter how the maize densities (i.e., maize inter-plant distances) or yields of maize and peanut changed, there were no significant changes in LERs at most situations or averaged over three locations. The comprehensive yield effect of the whole intercropping system is stable and there is an equilibrium effect.
LERs of grain yields averaged over three locations ranged from 0.89 to 0.98 (<1.0) among various maize inter-plant distances, while LERs of biomass yields ranged from 0.94 to 1.09 (>1.0 except for the maize inter-plant distance of 27 cm) (
Table 2 and
Table 4). Paired t test showed LERs of biomass yields were all significantly higher than those of grain yields for each experimental site (
n = 15) or for each maize inter-plant distance across three locations (
n = 9). All these results indicated that the intercropping of maize/peanut was not beneficial to the accumulation of grain yields but had some advantages on biomass yields. Paired t test showed that the partial LERs of grain yields of peanut were all significantly lower than those of biomass yields for each experimental site (
n = 15) or for each maize inter-plant distance across three locations (
n = 9), and the partial LERs of grain yields of maize were also significantly lower than those of biomass yields in Licheng (
n = 15) and at the maize inter-plant distance of 16 cm (
n = 9), which corresponded to the grain yield disadvantage of the whole intercropping system. Maize-legume intercrops could substantially increase forage quantity and quality and decrease the requirement for protein supplements [
45]. Since LERs of biomass yields are > 1.0, there is potential for maize silage and peanut forage production.
Harvest index (the ratio of grain yield to biological yield or biomass) is an important agronomic index to reflect the ability of a cereal crop to translocate photosynthates to grains [
46]. In a maize/peanut intercropping, the dry matter distributed toward the stem and leaf of intercropped maize was reduced as compared to the sole maize, intercropping promoted the distribution of photosynthetic assimilates toward the grain and increased the harvest index by 0.7–3.0% [
47]. In a relay intercropping of wheat/maize reported by Zhou et al. (2017) [
48], the over-yielding of intercropped wheat (especially for border rows) was mainly attributed to more aboveground biomass across the whole growing season and the increased harvest index. In the present study, according to the paired t tests between partial/total LERs of grain and biomass yields mentioned above and the calculation formulas of the partial LER and total LER, it was mainly the reduced harvest indexes of intercropped peanut compared to monoculture that led to lower partial LERs of grain yields of peanut than those of biomass yields and the disadvantage of grain yields of the whole intercropping system (
Table 2,
Table 4 and
Table 6). Shading was found to impair nutrient acquisition in intercropping systems of wheat with alfalfa or soybean [
49], and of maize with soybean [
50], mainly due to reduced photosynthetic capacity and below-ground root and above-ground shoot biomass accumulation of the shaded crop as compared with monoculture. Therefore, shading induced by maize in the present study may play an important role in decreasing not only peanut biomass, but also leading to less translocation of dry matter from vegetative organs to peanut grains. Obvious reductions in hundred pod weights, double kernel rates and especially the pod number per plant possibly explain the decrease in the harvest index of intercropped peanut. Compared with peanut, the maize harvest index was less affected by intercropping (
Table 5 and
Table 6).
There exists the optimum crop planting density in intercropping. Craufurd (2000) [
51] noted that poor management of planting density could be detrimental to intercropping. Plant densities that are too low limit the potential yield, and that are too high lead to increased stress on the plant, and increased interplant competition for light, water and nutrients [
52] which also decreases the yield. In South Africa, three maize densities (18,500, 24,700 and 37,000 plants/ha) and two dry bean arrangements (single and double row arrangement) were intercropped together, maize density of 18,500 plants/ha achieved significantly lower maize yield than 24,700 and 37,000 plants/ha, and that of 37,000 plants/ha with double row of dry bean is recommended [
19]. In Wolaita Zone Southern Ethiopia of Africa, intercropping of maize (44,444 plants/ha) with common bean (93,750 plants/ha) obtained both higher agronomic and economic advantage than sole crops and the intercropping with bean at 62,500 plants/ha [
21]. In field trails on the loess Plateau, China, the dry matter production and leaf area index of maize increased as the plant density increased irrespective of whether it was grown in monoculture or intercropping; while the greatest LER was observed in two rows of maize intercropping with two rows of soybean at low density [
17]. In our study, the rational increase of maize densities in intercropping from the inter-plant distance of 27 to 20 cm increased LERs (
Table 2 and
Table 4), especially for the averaged LER of the biomass yield over three locations, which was enhanced from 0.94 (<1.0) to 1.03, showing the intercropping yield advantage. Willey and Osiru (1972) [
24] determined that a higher density of component intercrops resulted in greater intercropping advantages in a maize/bean intercropping. However, further increase in maize planting densities by narrowing the maize inter-plant distances (≤16 cm) didn’t lead to significantly higher LERs of grain/biomass yields than those at 20 cm (
Table 2 and
Table 4), unfortunately wasted maize seeds and reduced the community stability of productivity severely (especially for maize and total LERs), compared to monoculture and intercropping at the maize inter-plant distances of 27 and 20 cm (
Table 7). A maize/sweet potato intercropping study in northern Uganda showed similar results that Land Equivalent Ratios of >1.2 were obtained at maize intercrop densities of 41,666 and 55,555 but not at 88,888 plants/ha [
20]. Simultaneously, the
β-carotene content and yield in sweet potato roots were significantly reduced by high maize density. In the present study, the excessive increase in maize densities are more likely to lead to abnormal maize ears with long bald tips, low seed setting rates and irregular grain/seed shortcomings and peanut with relative much stalks and leaves but little pods bearing (
Figure 2 and
Figure 3), and whether the corresponding grain nutritional quality also deteriorate is worth further investigation.
Three limitations existed in this current study. (1) No yield platform was found for maize or peanut in intercropping with increasing the maize density. The possible reason is the actual maximum maize density is not high enough. (2) At harvest, the actual maize planting density was not determined. (3) Lack of corresponding density treatments on monocropped maize. All partial LERs of maize were calculated based on the performance of maize in conventional monoculture at the inter-plant distance of 27 cm, which was convenient for mechanical single seed sowing and widely adopted by local farmers.
Yang et al. (2018) [
22] reported that net returns and benefit to cost ratios of maize/pea intercropping were increased with an increase of maize planting density. The economic benefits of maize/peanut intercropping as affected by maize planting densities were not investigated in the present study. The maize/peanut intercropping required more labor in their production than sole cropping. Consequently, like the maize/pea intercropping [
22], the grain yield, net returns and benefit to cost rations of maize/peanut intercropping may be similar or even lower than sole maize. However, the inclusion of annual legumes in cropping systems via either cereal/legume intercropping or cereal-legume rotations can significantly reduce the use of synthetic N and P fertilizer, as the legumes fix N
2 from the atmosphere to reduce the requirement for inorganic nitrogen in crop production, and secret H+ and organic acids to mobilize soil sparingly soluble P to facilitate P uptake by maize [
34,
35,
53,
54,
55,
56,
57]. Furthermore, such a cereal/legume intercropping system can provide significant ecological and environmental benefits by also lowering the environmental carbon footprint [
38,
58,
59,
60], and enhancing soil and ecological sustainability and/or resilience to climate change and pest, disease and weed damage [
3,
4,
10,
61,
62,
63].