Horticultural Performance of Greenhouse Cherry Tomatoes Irrigated Automatically Based on Soil Moisture Sensor Readings

Henrique Fonseca E De Oliveira,Ana Paula Silva Siqueira,Hugo De Moura Campos,Rhuanito Soranz Ferrarezi,Luis Sérgio Rodrigues Vale,Marcio Mesquita,Roriz Luciano Machado

doi:10.3390/w13192662

Abstract

Precision irrigation is essential to improve water use efficiency (WUE), defined as the amount of biomass produced per unit of water used by plants. Our objective is to evaluate the effect of different soil volumetric water content (VWC) in plant growth, fruit yield, quality, and WUE of cherry tomatoes grown in a greenhouse. We tested four VWC thresholds (0.23, 0.30, 0.37, and 0.44 m3 m−3) to trigger a drip irrigation system in two tomato cultivars (‘Sweet Heaven’ and ‘Mascot F1’). The experiment was arranged in a split-plot design with four replications. We used capacitance sensors connected to an open-source, low-cost platform to monitor and control the irrigation in real-time based on demand. Plants were watered every time the soil VWC dropped below the set thresholds. The treatment with VWC 0.44 m3 m−3 resulted in the highest fruit yield, with 102.10% higher WUE when compared to the VWC 0.23 m3 m−3 in both cultivars. Fruit quality traits such as longitudinal and equatorial diameter increased asymptotically with soil water content. In contrast, treatments with deficit irrigation increased the fruit soluble solids by 15.73% in both cultivars. These results strongly suggest that accurate control of the soil VWC is essential to modulate the fruit yield and quality attributes in tomatoes produced in the greenhouse.

Highlights

The accelerated increase in the world’s population and the unpredictable effects of climate change in agriculture require using natural resources like soil and water more efficiently to produce healthy and sustainable food [1]
This study evaluated the effect of different volumetric water contents (VWC) applied using a low-cost open-source automated system controlled by soil moisture sensors on plant growth, fruit yield, and quality of cherry tomatoes grown in a greenhouse
The results showed that increasing the VWC could significantly boost fruit yield, longitudinal and equatorial diameter, and water use efficiency (WUE) of two tomato cultivars

Summary

Introduction

The accelerated increase in the world’s population and the unpredictable effects of climate change in agriculture require using natural resources like soil and water more efficiently to produce healthy and sustainable food [1]. In addition to protecting the crops from pests and diseases and the adverse effects of extreme weather events, greenhouses guarantee year-round production and aid in higher water use efficiency (WUE) [3]. Water-saving technologies in protected environment production reduce water use and increase crop sustainability [4]. Supplemental irrigation is crucial in nutrient absorption and water uptake of greenhouse crops since they are not subjected to rainfall [5]. Excessive irrigation reduces water productivity and fruit quality [6]

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Conclusion