Achievements of Banana (Musa sp.)-Based Intercropping Systems in Improving Crop Sustainability
Abstract
:1. Introduction
2. Growing Bananas Sustainably Requires Changes in Land Use and Crop Management
3. Monoculture and Intercropping Systems
Monoculture | Reference | Intercropping | Reference |
---|---|---|---|
Single crop | [6,21,27] | Two or more crops simultaneously | [13,29] |
Large scale | [23] | Small scale | [34] |
Impact on biodiversity | [14] | Increased biodiversity | [30,31] |
Deplete soil nutrients | [22] | Stability environmental resources | [14] |
Increase susceptibility to pest and diseases | [22] | Increased pests and diseases suppression | [22] |
Reliance on chemical inputs | [14] | Less reliance on chemical inputs | [14] |
Negative environmental and agriculture consequences with greater impact from climate change | [14] | Stability agricultural production due to seasonal variability with less impact on climate change | [14,30,31] |
Higher yield per unit area | [13] | Can achieve higher yield per unit area with two or more component crops | [22] |
Specialization of economies of scale when increasing the scale of production leads to a reduction in production costs per unit | [9] | Economies of scope when the same inputs are used to produce two or more products | [9] |
4. Evaluating Intercropping Indicators
Indicator | Formula | Criteria for Decisions | Reference |
---|---|---|---|
LUE | LUE = (Yai)/(Ybm) + (Ybi)/Yam) | LUE > 1 indicates a productive advantage of intercropping; LUE = 1 no productive advantage; LUE < 1 productive disadvantage | [9,22,33,35,40] |
LER | LER = Yam/Ybm + Yai/Ybi | LER > 1 intercropping is most effective; LER < 1 intercropping has a negative effect on the yield | [22] |
ATER | ATER = [(LUEa × ta) + (LUEb × tb)]/Tbi | ATER > 1 productive advantage; ATER = 1 no productive advantage; ATER < 1 productive disadvantage | [40] |
RDC | RDC = {(Yai × Zb)/[(Yam − Yai × Za)]} × {(Ybi × Za)/[(Ybm − Ybi) × Za]} | RDC > 1 productive advantage; RDC = 1 no productive advantage; RDC < 1 productive disadvantage; RDCai > RDCbi indicates that the main crop presents strong interspecific competition | [35,40] |
A | Both crops are equally competitive when A = 0. When A is +, the culture with a + sign is dominant and the culture with a—sign is dominated | [35,40] | |
C | C = Cb + Cl Cb = (LUEa/LUEb) × (Za/Zb) Cb = (LUEb/LUEa) × (Zb/Za) | [22] | |
SPI | SPI = [(Yam/Ybm) × Ybai] + Yabi | [40] | |
IA | IA = AYat × Pat + AYbc × Pbt | IA > 0 intercropping advantage; IA ≤ 0 intercropping disadvantage | [36,40] |
GI | CPa × Pa; CPb × Pb | [40] | |
NI | NI = GI − TC | [40] | |
RR | RR = GI/TC | [40] | |
PM | PM = (NI/GI) × 100% | [40] | |
YL | YL = (WL/WI) × 100% | [40] |
5. Intercropping Benefits
5.1. Increasing or Maintaining Productivity and Profitability
5.2. Promoting the Effective Use of Natural Resources
5.3. Weed Control
5.4. Pest and Disease Reduction
5.5. Nutrient Cycling
5.6. Improving Nutritional Management
5.7. Crop Resilience
6. Intercropping Limitations and Risks
6.1. Size of the Growing Area
6.2. Decreased Crop Yield
6.3. Appropriate Choice of Component Crops
6.4. Proper Fertilization and Nutritional Status
6.5. Use of Machinery
6.6. Shade Intensity
6.7. Disposed Waste
7. Banana Planting Design
8. Banana-Based Intercropping Outcomes
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Component Crop | Outcomes | Reference |
---|---|---|
Green Manures: Cajanus cajans and Crotalaria juncea | Greater banana growth | [88] |
Coffee (Coffea arabica) | Increase economic viability; advantageous for NI, better LUE efficiency, increase the revenue, high quality bananas and weed supression | [11,44,47,48,54,66] |
Bean (Phaseolus vulgaris) | Bananas appeared more competitive, low banana productivity and the need for investment in external inputs | [42,43,65] |
Climbing beans (Phaseolus coccineus) and soya (Glycine max) | Reduced banana growth and yield | [43] |
Onion (Allium cepa) | Highest net revenue | [45] |
Sweet goud (Momordica cochinchinensis), Bitter gourd (Momordica charantia), red amaranth (Amaranthus cruentus) and radish (Raphanus sativus) | Lower yield and economic analysis with maximum cost-benefit ratio | [46] |
Yacon (Smallanthus sonchifolius) | Higher GI and optimizes the use of the area | [49] |
Aromatic species | Additional income, reduce costs and environmental damage | [55,56,59] |
Lemongrass (Cymbopogon citratus) | Entry into consumer markets, similar performance compared with monocropping, reduced weed control and without the need to select specific fertilizers for lemongrass | [30,60] |
Sweet potato (Ipomoea batatas) | Regulating the structure and compositions and improving the abundance and diversity of soil microbial population | [69] |
Millet (Panicum miliaceum) | Lower number of banana weevil | [52,70] |
Leguminosae (Canavalia muzzina and Tephrosia vogelli) | Repellent or insecticidal properties | [52] |
Maize (Zea mays), taro (Xanthosoma sagittifolium) and gourd (Lagenaria siceraria) | Alter the structure of ant community which contributes to the control of weevil (Cosmopolites sordidus) | [71] |
Chinese chives (Allium tuberosum) | Potential to reduce Fusarium wilt disease | [76] |
Leguminosae White clover (Trifolium repens) | Reduced the incidence of Fusarium wilt disease | [68,77,78] |
Oil palm (Elaeis gineensis) | Sustainable LUE and revenue | [50] |
Grevillea (Grevillea robusta) | Low soil fertility continually restricts production | [89] |
Rubber (Hevea brasiliensis) | Increase in the growth of rubber | [95] |
Cocoa (Cocos nucifera) | Necessity to reduce the density of banana plantation | [43] |
Agroforestry systems | Optimizzing LUE, diversifying production and increasing GI | [6] |
FARMdesign model | Disparity in agroecological practices and socioeconomic constraints | [41] |
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Leonel, S.; Leonel, M.; Jesus, P.R.R.d.; Tecchio, M.A.; Silva, M.d.S.; Cândido, H.T.; Molha, N.Z.; Ouros, L.F.d. Achievements of Banana (Musa sp.)-Based Intercropping Systems in Improving Crop Sustainability. Horticulturae 2024, 10, 956. https://doi.org/10.3390/horticulturae10090956
Leonel S, Leonel M, Jesus PRRd, Tecchio MA, Silva MdS, Cândido HT, Molha NZ, Ouros LFd. Achievements of Banana (Musa sp.)-Based Intercropping Systems in Improving Crop Sustainability. Horticulturae. 2024; 10(9):956. https://doi.org/10.3390/horticulturae10090956
Chicago/Turabian StyleLeonel, Sarita, Magali Leonel, Paulo Ricardo Rodrigues de Jesus, Marco Antonio Tecchio, Marcelo de Souza Silva, Hebert Teixeira Cândido, Nicholas Zanette Molha, and Lucas Felipe dos Ouros. 2024. "Achievements of Banana (Musa sp.)-Based Intercropping Systems in Improving Crop Sustainability" Horticulturae 10, no. 9: 956. https://doi.org/10.3390/horticulturae10090956
APA StyleLeonel, S., Leonel, M., Jesus, P. R. R. d., Tecchio, M. A., Silva, M. d. S., Cândido, H. T., Molha, N. Z., & Ouros, L. F. d. (2024). Achievements of Banana (Musa sp.)-Based Intercropping Systems in Improving Crop Sustainability. Horticulturae, 10(9), 956. https://doi.org/10.3390/horticulturae10090956