Sustainable soil management options for Malawi: can smallholder farmers grow more legumes?

Snapp, Sieglinde S.; Rohrbach, David; Simtowe, Franklin; Freeman, H. A.

doi:10.1016/s0167-8809(01)00238-9

Cited by 139 publications

(115 citation statements)

References 20 publications

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“…Three cropping systems were compared: (1) current practice, which is a maize continuous system using the average fertilizer rate of 18 kg N ha 1 from survey data (low-density potato intercrop at a 6:1 ratio of maize:potato was not possible to simulate given current model limitations), (2) recommended practice, which is a maize continuous system at the recommended rate of 69 kg N ha 1 , over threefold higher than current fertilizer use, and (3) integrated practice, which is rotation of a grain legume with maize; the recommended N fertilizer rate for the system in the second year is 69 kg N ha 1 minus legume N credit of 35 kg N ha 1 from residues incorporated after grain legume rotation. Pigeonpea was the grain legume of choice since it consistently has been shown to perform well under low soil fertility on smallholder farms and to produce residues containing 60 kg N ha 1 where we assume from N mineralization assays that 35 kg N ha 1 is available to subsequent crops [9,10]. This is similar to results from other Malawi studies of on-farm production of pigeonpea residues, although considerably less than is biologically possible [13,15].…”

Section: Nitrogen Budgetssupporting

confidence: 67%

“…Malawi cropping systems are constrained by a unimodal precipitation pattern that limits farmers to one crop per season and to an average area of land per farm holding of less than 2 ha [9] . Soils are Alfisols and Ultisols, generally sandy in texture and deficient in N status.…”

Section: Introductionmentioning

confidence: 99%

“…Maize (Zea mays) accounts for 60 to 80% of the area sown. The remainder of smallholder arable land is sown to tobacco (Nicotiana tabacum), groundnut (Arachis hypogaea), common bean (Phaseolus vulgaris), pigeonpea (Cajanus cajan), and, in highland sites, potato (Solanum tuberosum) [9]. Fertilizer is frequently applied 2 to 4 weeks after crop emergence.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Improving Nitrogen Efficiency: Lessons from Malawi and Michigan

Snapp

Borden

Rohrbach

2001

The Scientific World JOURNAL

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Section: Nitrogen Budgetssupporting

confidence: 67%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Improving Nitrogen Efficiency: Lessons from Malawi and Michigan

Snapp

Borden

Rohrbach

2001

The Scientific World JOURNAL

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“…Legumes have the potential to contribute to the soil N budget through biological N 2 -fixation (BNF), and are potentially a cheap alternative to mineral N fertilizers for providing N to crops (Boddey et al 1997;Giller et al 1997). Grain legumes are more attractive to most smallholder farmers than other legume-based technologies, such as green manures, which do not contribute directly to income or food security (Giller 2001;Snapp et al 2002). However, most grain legumes have high N harvest indices and may only have a small or net negative contribution to the soil N budget (Giller and Cadisch 1995).…”

Section: Introductionmentioning

confidence: 99%

“…Major challenges exist to enhance productivity of soyabean and other grain legumes under smallholder farm conditions (Snapp et al 2002). Soils cultivated by smallholder farmers are predominantly infertile and sandy, with small contents of soil organic matter, available P and bases, and are also acidic.…”

Section: Introductionmentioning

confidence: 99%

Variable grain legume yields, responses to phosphorus and rotational effects on maize across soil fertility gradients on African smallholder farms

Zingore

Murwira²,

Delve³

et al. 2007

Nutr Cycl Agroecosyst

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Promiscuous soyabean varieties have potential to contribute significantly to income generation, food security and soil N budgets on smallholder farms. One of the major factors limiting this potential is farmers' preference to allocate nutrient resources to food security cereal crops on the most fertile fields, leaving grain legumes to grow on residual fertility on infertile fields. Two experiments were conducted to: (i) compare the current farmer practice with targeting manure and single super phosphate (SSP) to soyabean in a three-year rotation cycle on two fields with different soil fertility: an infertile sandy soil and a more fertile clay soil; and (ii) assess the effects of variability of soil fertility within and across farms on productivity of soyabean and groundnut. In the first experiment, soyabean (<0.2 t ha À1 ) and maize yields (<0.7 t ha À1 ) without fertilizer were poor on a degraded sandy soil. Both crops responded poorly to SSP due to deficiency of other nutrients. Manure application significantly increased soyabean and maize yields, led to yield stabilization over three seasons and also significantly increased the proportion of N 2 fixed by soyabean (measured using 15 N natural abundance) from 60% to 83%. On the sandy soil, P was used more efficiently and gross margins were greater when SSP and manure were applied to maize in a maize-soyabean rotation. Soyabean and maize yields without fertilizer inputs were larger on clay soil with moderate fertility (0.4-0.7 t ha À1 and 2.0-2.3 t ha À1 respectively) and were significantly increased by application of SSP and manure. Within rotations, P recovery was higher when manure and SSP were applied to maize (43 and 25%) than when applied to soyabean (20 and 19%). However, application of manure to soyabean on the clay was more profitable than application to maize for individual crops and within rotations. In the second experiment, soyabean and groundnut yields were largest (*1 and *0.8 t ha À1 respectively) on plots closest to homesteads on wealthy farms, which were more fertile due to good past management. Yields were poor (< 0.5 t ha À1 ) on other fields which previously had received little nutrient inputs. Soyabean and groundnut yields correlated well with available P (R 2 = 0.5-0.7) and soil organic C (SOC) contents (R 2 = 0.4-0.6). For smallholder farmers to maximise benefits from legume production they need to focus attention on the more fertile plots, although production should be optimized in relation to maize. Targeting nutrients to maize as currently practiced by farmers was more efficient and economic under poor soil fertility conditions, whilst potential exists to increase income by targeting manure to soyabean on the more fertile soils.

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Little or no maize (Zea mays) grain yield loss occurred in intercrop with mid‐maturity lablab (Lablab purpureus) in northeastern Tanzania

Gott¹,

Massawe²,

Miller³

et al. 2023

Crop Science

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Intercropping is among sustainable intensification tactics farmers may use to increase or maintain productivity and environmental quality. Effects of planting lablab (Lablab purpureus (L.) Sweet) one or two weeks after planting maize (WAPM) are not well characterized, especially when mid‐maturity lablab cultivars are used. Greenhouse (Springfield, MO, USA) and field studies (Arusha, Tanzania) were conducted in 2018 and 2019 to assess early (≤60 d) and full‐season effects on growth and grain production. The greenhouse study characterized early growth characteristics when lablab was sown 0‐, 1‐, or 2‐WAPM for each of four cultivars of lablab. ‘Echo Cream’ lablab produced greater vine length and more nodes than other cultivars in the greenhouse. Greenhouse lablab biomass and node number were greatest when sown ≤1‐WAPM. The field study compared monoculture and intercrop grain yields. Highest maize yields occurred when lablab was sown ≥1‐WAPM, but highest lablab yields occurred when planted at the same time as maize. The maize/lablab intercrop always resulted in favorable Land Equivalent Ratios (LERs) ranging from 1.5 to 2.1. The partial LER of maize yield was not reduced by more than 7% relative to monoculture either year. Lablab yield was negatively affected by planting delay, decreasing about 60% in 2018 and 31% in 2019 in the 2‐WAPM planting date treatment. Although twining lablab vines complicate grain harvest, our results demonstrate increased grain production per unit area with maize/lablab intercropping, with a potential for increased farmer income and household nutrition.This article is protected by copyright. All rights reserved

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Sustainable soil management options for Malawi: can smallholder farmers grow more legumes?

Cited by 139 publications

References 20 publications

Improving Nitrogen Efficiency: Lessons from Malawi and Michigan

Improving Nitrogen Efficiency: Lessons from Malawi and Michigan

Variable grain legume yields, responses to phosphorus and rotational effects on maize across soil fertility gradients on African smallholder farms

Little or no maize (Zea mays) grain yield loss occurred in intercrop with mid‐maturity lablab (Lablab purpureus) in northeastern Tanzania

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