TY - CHAP

T1 - Crop spatial uniformity, yield and weed suppression

AU - Lu, Ping

AU - Jiang, Baiwen

AU - Weiner, Jacob

PY - 2020

Y1 - 2020

N2 - Most crop sowing methods result in a highly clumped two-dimensional spatial pattern of individual crop plants. Ecological theory predicts that increasing the spatial uniformity of crop plants should result in increased suppression of weeds and higher yields. We reviewed experiments in which crop spatial pattern was an independent variable and effects on yield and/or weeds were measured. We included (a) all studies we could identify in which the uniformity of spacing within the crop rows was a variable, and (b) all studies from 1996 to 2016 in which row distance was the only spatial variable investigated. In most experiments, increased crop spatial uniformity resulted in increased weed suppression. In a large majority of cases, yield was higher when seeds were more evenly spaced within the rows. Effects of reducing row distance without improving the distribution of seeds within the rows were variable, usually resulting in increases in yield, but in some cases the effects were small or absent. Increased crop spatial uniformity through reduced row spacing together with improved uniformity within the rows increased weed suppression and increased yield for a wide range of crops and sowing densities, both in the presence and the absence of weeds. Positive effects of increased spatial uniformity were stronger under mesic than dry conditions, and for crops or varieties with relatively determinate growth form. Increased crop spatial uniformity can improve plant production in the future by increasing weed suppression, crop yields and agricultural sustainability.

AB - Most crop sowing methods result in a highly clumped two-dimensional spatial pattern of individual crop plants. Ecological theory predicts that increasing the spatial uniformity of crop plants should result in increased suppression of weeds and higher yields. We reviewed experiments in which crop spatial pattern was an independent variable and effects on yield and/or weeds were measured. We included (a) all studies we could identify in which the uniformity of spacing within the crop rows was a variable, and (b) all studies from 1996 to 2016 in which row distance was the only spatial variable investigated. In most experiments, increased crop spatial uniformity resulted in increased weed suppression. In a large majority of cases, yield was higher when seeds were more evenly spaced within the rows. Effects of reducing row distance without improving the distribution of seeds within the rows were variable, usually resulting in increases in yield, but in some cases the effects were small or absent. Increased crop spatial uniformity through reduced row spacing together with improved uniformity within the rows increased weed suppression and increased yield for a wide range of crops and sowing densities, both in the presence and the absence of weeds. Positive effects of increased spatial uniformity were stronger under mesic than dry conditions, and for crops or varieties with relatively determinate growth form. Increased crop spatial uniformity can improve plant production in the future by increasing weed suppression, crop yields and agricultural sustainability.

KW - Crop yield

KW - Crop-weed competition

KW - Planting pattern

KW - Precision sowing

KW - Spatial pattern

KW - Weed biomass

U2 - 10.1016/bs.agron.2019.12.003

DO - 10.1016/bs.agron.2019.12.003

M3 - Book chapter

AN - SCOPUS:85078280936

VL - 161

T3 - Advances in Agronomy

SP - 117

EP - 178

BT - Advances in Agronomy

PB - Academic Press

ER -