Crop yield responses to conservation agriculture practices

in Sub-Saharan Africa: a meta-analysis

Raymond Sakyi, Marc Corbeels, Ronald Kühne, Anthony Whitbread

Department of Crop Production Systems in the Tropics, Georg-August

Universität, Göttingen, Germany Agro-ecology and Sustainable Intensification of Annual Crops, CIRAD, Montpellier, France

corbeels@cirad.fr

18 -21 March, Lusaka, Zambia

Introduction

• Growing number of studies have been carried out comparing the practices of conservation agriculture (CA) to conventional tillage (CT) in Sub-Saharan Africa

• Conducted under a range of conditions (climate, soil, crop management, cropping systems)

• The effects of CA on crop yield compared to CT are diverse

Aim of the study

• Better understanding of crop responses to CA

• Identifying the agro-ecological and management conditions that favor positive crop responses to CA

• Contributing to better targeting the investments with CA development and research

Methods

• Search of scientific literature on the effects of the CA (no-tillage, crop residue mulching and rotations) on crop yields in SSA

• 42 (peer-reviewed) papers were selected for the final dataset with 61 independent studies

• Meta-analysis: random effects model to calculate effect sizes

• Weighted mean difference in grain yield between the CA and CT treatment

• Weight given to each study was calculated as the inverse of the variance

Overall results

• Large variability in grain yield responses (from positive to negative) to CA compared to CT

• NTM had the largest positive mean (378 kg ha-1) followed by NTR with a positive mean of 142 kg ha-1, and then NT with a negative mean (- 24 kg ha-1)

Short-term yield responses

• Positive responses: under conditions where water stress occurs (e.g. dry spells), since mulching increases soil water availability (e.g. Mkoga et al. 2010; Mupangwa et al. 2012; Thierfelder and Wall 2009).

• Negative responses: i) under high rainfall, as mulching may exacerbate waterlogging (Thierfelder and Wall 2012); ii) increased weed competition and problems with seeding (Mashingaidze et al. 2012).

Crop responses in time • Yield benefits are expected to accumulate over time, because CA is known to

gradually improve biological, chemical and physical properties of the soil

• Results from a meta-analysis of existing crop yield data from long-term experiments in sub-Saharan Africa do not confirm this hypothesis, and show large variation in the data

Data from: Vogel (1993), Lal (1997), Nehanda (2000), Moyo (2003) and Thierfelder et al. (2013)

Rotations with legumes!

• meta-analysis of results from long-term experiments in sub-humid and semi-arid regions of the world

Rusinamhodzi L, Corbeels M, van Wijk M, Rufino MC, Nyamangara J, Giller KE. Long-term effects of conservation agriculture practices on maize yields under rain-fed conditions: lessons for southern Africa.

Agron Sustain Dev 2011;31:657-673.

Underlying reasons: soil carbon?

Location Soil

texture

Soil

depth

(cm)

Duration (yr) Soil C (Mg ha-1) ΔC

/year

Reference

CT CA

Mulching including rotation or intercropping

Monze, Zambia loamy sand 0-30 5 23.4 32.3 1.78 Thierfelder et al.

2013c

Henderson,

Zimbabwe

loamy sand 0-30 4 18.4 24.7 1.57 Thierfelder et al.

2012

Malende, Zambia sand 0-30 3 Non-significant differences Thierfelder et al.

2013c

Lemu,

Malawi

sandy clay

loam

0-30 6 Non-significant differences Ngwira et al. 2012

Zidyana, Malawi sandy loam 0-30 6 Non-significant differences Ngwira et al. 2012

Kayowozi, Zambia loamy sand 0-20 3 Non-significant differences Thierfelder et al.

2013c

Underlying reasons: soil carbon?

Location Soil texture Soil

depth

(cm)

Duration (yr) Soil C (Mg ha-1) ΔC

/year

Reference

CT CA

No rotation – mulching

Harare, Zimbabwe clay 0-20 8 18.7 26.8 1.01 Nyagumbo 2002;

Chivenge et al. 2007

Domboshawa,

Zimbabwe

loamy sand 0-20 8 13.0 20.7 0.96 Nyagumbo 2002

Madziwa,

Zimbabwe

sand 0-30 5 7.4 10.0 0.52 Thierfelder et al.

2012

Chikato, Zimbabwe sand 0-20 4 6.9 13.3 1.60 Thierfelder and Wall

2012

Hereford,

Zimbabwe

sandy clay

loam

0-20 3 37.5 43.3 1.93 Thierfelder and Wall

2012

Domboshawa,

Zimbabwe

sandy clay

loam

0-20 2 16.8 16.9 0.05 Nyamadzawo et al.

2008

Ibadan, Nigeria sandy-loam 0-10 8 13.4 24.3 1.36 Lal 1998b

Nyabeda, Kenya sandy-loam 0-30 5 Non-significant differences Paul et al. 2013

Abomey-Calavi,

Benin

sandy loam 0-15 1 Non-significant differences Saito et al. 2010

Effect on no-tillage

• less than 3 years: overall effect in terms of yield benefit is positive (88 kg ha-1) more than 3 years: overall negative effect (-227 kg ha-1)

• in the longer term no-tillage without crop residue mulching triggers negative impacts on crop production, which may be mainly due to a soil compaction or soil surface crusting

Number of observations

0 20 40 60

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-4000

-2000

0

2000

4000

NT

Duration < 3 years

*

Number of observations

0 10 20 30 40

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-4000

-2000

0

2000

4000

NT

Duration > 3 years

*

Effect of mulching

• positive yield response seems to increase over time (from 294 to 487 kg ha-1)

• positive short-term effect on crop growth and productivity through increased soil water conservation, and a positive long-term effect through enhancing soil carbon levels and soil fertility in general.

Number of observations

0 20 40 60 80 100

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-8000

-6000

-4000

-2000

0

2000

4000

6000

8000

NTM

Duration < 3 years

*

Number of observations

0 20 40 60 80 100 120 140 160

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-8000

-6000

-4000

-2000

0

2000

4000

6000

8000

NTM

Duration > 3years

*

Fertilizer!

• response increases with N fertilization (from 85 to 391 kg ha-1)

• appropriate fertilization is critical for increasing crop productivity and the availability of crop residues for mulching

Number of observations

0 20 40 60 80 100 120

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-6000

-4000

-2000

0

2000

4000

6000

N input < 100 kg/haNS

Number of observations

0 20 40 60 80

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-6000

-4000

-2000

0

2000

4000

6000

N input > 100 kg/ha*

Effects of soil texture

• cop grain yields on sandy and clayey soils under CA were not significantly different than yields under CT: 72 and 45 kg ha-1

• On loamy soils: significantly higher than that of CT:299 kg ha-1

Number of observations

0 20 40 60 80

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-6000

-4000

-2000

0

2000

4000

6000

Sandy soilNS

Number of observations

0 50 100 150 200 250

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-6000

-4000

-2000

0

2000

4000

6000 Loamy soil

*

Number of observations

0 10 20 30 40 50

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-6000

-4000

-2000

0

2000

4000

6000

Clayey soilNS

Effects of seasonal rainfall

• crop grain yields were overall significantly higher under CA treatments compared to CT in all seasonal rainfall categories

• overall, crop grain yields were 143, 161 and 348 kg ha-1 higher under CA compared to CT for < 600 mm, 600-1,000 mm and > 1,000 mm, respectively

Number of observations

0 20 40 60 80

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-6000

-4000

-2000

0

2000

4000

6000

< 600 mm*

Number of observations

0 20 40 60 80 100 120 140 160

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-6000

-4000

-2000

0

2000

4000

6000

600 - 1000 mm*

Number of observations

0 10 20 30 40 50

We

ighte

d m

ean d

iffe

rence

(kg

/ha)

-6000

-4000

-2000

0

2000

4000

6000

> 1000 mm*

Conclusions • Mulching (crop residues) and rotations are required

for effective yield benefits

• (Short-term) yield benefits are variable = bottleneck for adoption; farmers need immediate benefits from investments

• Higher benefits in comparison with CT when fertilizer is applied ( better-resourced farmers)

• Seems to work better on loamy soils…

• Rainfall?