Abstract
Particles in a substrate create a network of pore pathways for water to move through, with size and shape determining the efficacy of these channels. Reduced particle size diversity can lead to increased leachate, poor substrate hydration, and an inefficient irrigation practice. This research examined the hydration characteristics of three greenhouse substrate components at three preconditioned initial moisture contents using subirrigation under five different irrigation durations and three water depths (2 mm, 20 mm, and 35 mm). Sphagnum peatmoss, coconut coir, and aged pine bark were tested at 67%, 50%, and 33% initial moisture (by weight). The objectives were to determine the impact of varying irrigation event durations (5, 10, 20, 30, 60 min) over a 60-min period, and the further influence of water depth and initial moisture, on the water capture abilities of peat, coir, and pine bark. The number of irrigation events depended on the irrigation event time of that experimental unit divided by the total time of 60 min, varying from 12, 6, 3, 2, and 1 event. Hydration efficiency was influenced by initial moisture content (IMC), water depth, pulsing duration, and inherent substrate characteristics (hydrophobicity/hydrophilicity). Initial MC had the largest impact on peat, regardless of water level or irrigation duration. Lower IMCs increased the hydrophobic response of peat, further reducing the amount of water the substrate was able to absorb. Pine bark had a 5–10% decrease in initial hydration between 67%, 50%, and 33% IMC, while coir’s hydrophilic nature reduced any IMC affects. At 50% IMC or less, coir had the highest volumetric water content (VWC) across all substrates, pulsing durations, and water depths. Water depth was found to increase initial hydration and final hydration 6–8% across all substrates. These three materials had altered and varied water capture responses depending on the combination of treatments employed. This work demonstrated the effects of intensity and exposure on substrates and the need for more integrated research for improving water use efficiency on container crops.
Highlights
As the global population continues to increase, demand on the limited water supply is expected to follow suit
On 24 July 2019, loblolly (Pinus taeda L.) pine bark (Pacific Organics, Henderson, NC, USA) which had been aged in outdoor windrows for four months and engineered to have a container capacity (CC) of 55% volumetric water content (VWC) was separated, moisture levels tested, and further hydrated to a moisture content of 70%
Coir represented the substrate with the highest percentage of particles smaller than 2.0 mm, showing 69.2% of all particles tested with pine bark representing the highest percentage of coarse particles with 57.0% Peat occupied the middle of the three substrates with 8.8% more coarse particles than coir, but 41.4% less than that of pine bark
Summary
As the global population continues to increase, demand on the limited water supply is expected to follow suit. With the future of water restrictions still unknown, the move towards more efficient containerized plant production systems is essential. To create an efficient system in container production, the substrate, irrigation system, and the container must be considered together as a whole. Soilless substrates were first introduced for container production to increase drainage by maintaining a high air-filled porosity as compared to mineral soils [1]. The higher air space in container substrates compared to mineral soil was used to decrease the hypoxic potential of the container, regardless of over-irrigating or increased precipitation. The side-effect of increased airspace is the practice of excess water application to limit the risk of under watering [2]
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