Shoot and root interference of morning glory on the initial growth of sugarcane

ABSTRACT Among weeds, morning glories comprise a very important group of climbing plants that infest sugarcane crops. The objective of this study was to evaluate the shoot and root interference of Merremia cissoides on the initial growth of sugarcane cultivar RB 966928. The experiment consisted of five treatment groups: (i) sugarcane monocropping, (ii) morning glory monocropping, (iii) sugarcane intertwined with morning glory but inseparate boxes, (iv) sugarcane intertwined with morning glory in attached boxes and (v) sugarcane with morning glory in attached boxes with morning glory prevented from intertwining with the sugarcane. The experimental design consisted of randomized blocks with four replicates. Merremia cissoides adversely affected the initial growth of the RB 966928 sugarcane starting at 90 days after transplanting (DAT). This effect increased with the time of intercropping, reaching at 180 DAT with a reduction of 57.3% in height,15.5% in stalk diameter, 90.4% in leaf areas, 86.6 and 75.2% in stalk and leaf dry mass, respectively. These reductions primarily due to the weed intertwining with the sugarcane plants because the weed had a physical choking and shading effect. This negative effect of morning glory on the sugarcane plants increased when they shared the substrate (i.e., when they competed for space and water), which also adversely affected weed growth, reducing 50.2% leaf areas and 42.1% shoot dry mass. The leaf area and the stalk and leaf dry mass of sugarcane are the characteristics more sensitive to the weed interference. Thus, both the shoot and root of M. cissoides interferes negatively in the growth of sugarcane, with the effect proportional to the period of coexistence, highlighting the detrimental effect on the stem (greater economic interest), and may also compromise the mechanical harvesting of the crop.

Estimativa da área foliar de Crotalaria juncea L. a partir de dimensões lineares do limbo foliar / Estimate of Crotalaria juncea L. leaf area using linear dimensions of the leaf blade

Conhecimentos sobre a área foliar de uma planta são necessários para estudos agronômicos e fisiológicos envolvendo crescimento vegetal. O objetivo desse trabalho foi obter um modelo matemático, por meio de medidas lineares dimensionais das folhas, que permita a estimativa da área foliar de Crotalaria juncea L. Coletaram-se aleatoriamente 200 folhas dessas plantas para estudo de suas medidas lineares. Estudaram-se as correlações entre a área foliar real (Sf) e as medidas dimensionais do limbo foliar, como o comprimento ao longo da nervura principal (C) e a largura máxima (L), perpendicular à nervura principal. Todas as equações testadas (lineares, exponenciais ou geométricas) permitiram boas estimativas da área foliar (acima de 87%). As equações que apresentaram melhor ajuste foram as lineares, passando ou não pela origem. Do ponto de vista prático, sugere-se optar pela equação linear simples envolvendo o produto (C*L), considerando-se o coeficiente linear igual a zero. A estimativa da área foliar de Crotalaria juncea L. pode ser feita pela equação Sf = 0,7160 x (C*L) com um coeficiente de determinação de 0,9712.

Knowledge of the leaf area plant are needed for agronomic and physiological studies involving plant growth. The aim of this study was to obtain a mathematical model using linear measures of leaf dimensions, which will allow the estimation of leaf area of Crotalaria juncea L. Correlation studies were conducted involving real leaf area (Sf) and leaf length (C), maximum leaf width (L) and the product between C and L. All tested models (linear, exponential or geometric) provided good estimation of leaf area (above 87%). The better fit was attained using linear model, passing or not through the origin. From a practical viewpoint, it is suggested to use the linear model involving the C and L product, using a linear coefficient equal to zero. Estimation of leaf area of Crotalaria juncea L. can be obtained using the model Sf = 0.7160 x (C*L) with a determination coefficient of 0.9712.