Overhead aluminum sprinklers, which are used during the early stages of strawberry crop development to establish transplants and to leach out salts from the root zone, deliver significant volumes of water. Micro-sprinklers, which are typically used in orchard crops, were evaluated in a commercial strawberry field in California as an alternative to conventional aluminum sprinklers to conserve water without any negative impact on yields. In addition to the water consumption, data were collected from multiple plots within each treatment to determine the impact on plant growth, disease incidence, and seasonal yield. Micro-sprinklers used 32% less water than aluminum sprinklers during a three-week period without affecting fruit yield. They also appeared to lessen the severity of powdery mildew and botrytis fruit rot. This is the first study reporting the use of micro-sprinkler system, which can be a good alternative to the aluminum sprinklers to conserve irrigation water.
Strawberry is an important commercial crop in California and primarily grown in the Watsonville, Santa Maria, and Oxnard production areas in the Central Coast on about 37,000 acres annually [
Strawberry crop requires about 2 acre-feet of irrigation water during a typical production season for fall planting. Fall planting typically starts in October-November and ends in July-August of the following year. Evapotranspiration of strawberry crop varies depending on the micro-climate of the production region, seasonal climatic variations, type of irrigation system used, and general agronomic practices. For example, a two- year study conducted in 2009 and 2011 in the Monterey Bay area showed that the average evapotranspiration varied between 2 and 2.5 acre-feet [
Strawberries are mainly irrigated through a drip system where drip tapes are installed under plastic mulch when beds are prepared. Drip irrigation is supplemented with overhead aluminum sprinkler irrigation during the first few weeks after transplanting to leach out salts from the root zone and to help with transplant establishment. Strawberry crop is sensitive to salinity and overhead aluminum sprinkler irrigation reduces and prevents salt injury [
Application efficiency (AE refers to the efficiency of an irrigation system in delivering a specific amount of water) studies showed that micro-sprinklers are more efficient (81% AE) than hand-move sprinkler systems (70% AE) [
A study was conducted in Santa Maria during the 2014-2015 production season to assess the potential of micro-sprinklers as an alternative to overhead aluminum sprinklers. Specific objectives of this study included: 1) if micro-sprinklers conserve water without a negative impact on strawberry plant growth and fruit yield; 2) if micro- sprinklers have any impact on pest and predatory mite populations; and 3) if micro- sprinklers have any impact on powdery mildew and botrytis fruit rot.
This study was conducted at Manzanita Berry Farms in Santa Maria on a conventional strawberry field with variety BG-6.3024 planted on 6 November, 2014. A strawberry block with about 135 beds aligned in a north-south direction was divided into two sections. The west half of the block was assigned for the micro-sprinklers and the east half for aluminum sprinklers, which was the grower standard (
ANOVA. Significant means were separated using Tukey’s HSD test.
Micro-sprinklers were installed on every fourth bed (about 16’ apart) and had a 15’ spacing between two sprinkler heads within a bed. Aluminum sprinklers were installed in furrows every 40’ with 7 - 8 beds in between. Sprinkler heads were spaced 30’ apart on each pipe. Supplemental irrigation during the transplant establishment period was administered from 6 to 29 November, 2014. During this period, there were 14 irrigation events using aluminum sprinklers where 125 gallons of water was delivered per minute. Micro-sprinklers were used each time for 2 hours at 1 - 3 day intervals where 40 gallons per minute were delivered at 35 PSI pressure.
Plots were marked with flags and covered with netting to prevent accidental harvesting by the commercial harvesting crew. Total and marketable strawberry yield data were collected 2 to 3 times every week, following the normal harvest schedule, between 7 February and 12 June, 2015 for a total of 34 sampling dates.
Plant growth was recorded by measuring the width of the plant canopy across and along the length of the bed from 20 random plants within each plot on the 6th day of each month from January to March, 2015. Plant health was monitored at the same time on a scale of 0 to 5 where 0 = dead, 1 = weak, 2 = moderate-low, 3 = moderate-high, 4 = good, and 5 = very good.
One mid-tier leaflet from each of the 10 random plants within each plot was sampled once a month from February to April, 2015. The number of eggs, nymphs, and adult stages of both pest and predatory mites were counted using a mite brushing machine.
One trifoliate leaf from each of the 20 random plants within each plot were collected on 14 April and 16 and 24 June, 2015. Leaves were examined under a microscope for mycelial growth and powdery mildew severity was recorded on a scale of 0 to 4 where 0 = absent, 1 = 1% - 25%, 2 = 26% - 50%, 3 = 51% - 75%, and 4 = 76% - 100% of leaf area with infection.
Strawberries harvested from each plot on 26 March, 13 April, 22 May, and 16 June, 2015, were kept at room temperature in plastic clamshell boxes. Disease severity was measured 3 and 5 days after harvest based on mold growth on the same scale used for powdery mildew.
During this period, aluminum sprinklers delivered 120,000 gallons of water over 16 hours of irrigation whereas micro-sprinklers delivered 81,600 gallons over 34 hours (
Micro-sprinkler irrigation events were continued twice a week, 15 min each time, after 29 November for the rest of the production season to discourage twospotted spider mite populations. Distribution uniformity (DU) for the micro-sprinkler system was 74% at 35 PSI when measured on 16 January, 2015. DU could not be measured for aluminum sprinklers, but it is believed to be between 50% - 60% at 70 PSI [
When seasonal average was considered, there was no significant difference (P > 0.05) between the yield of marketable berries in micro-sprinkler and aluminum sprinkler plots (
Plants in the micro-sprinkler plots had significantly smaller canopy in January (P = 0.004)
and February (P = 0.0006), but caught up with the plants in the aluminum sprinkler plots by March (P = 0.14) (
Due to sparse numbers and uneven distribution of mites, comprehensive data could not be collected.
Powdery mildew severity was significantly less in micro-sprinkler treatment on 15 April (P = 0.009) and June 24 (P = 0.01) (
Micro-sprinkler plots appeared to have a lower level of botrytis fruit rot, but significant differences were seen only 3 days after harvest for strawberries sampled on 22 May and 16 June (P = 0.02) (
The micro-sprinkler system contributed to a significant reduction in supplemental overhead irrigation water without adversely affecting the marketable strawberry yield. Since less pressure is required for micro-sprinklers than aluminum sprinklers to deliver
water, energy savings and less carbon emissions are also possible from the micro- sprinkler system. EC value below the recommended level (0.07 dS/m) also suggests that micro-sprinklers were as effective as aluminum sprinklers in leaching out salts from the root zone without excessive water use. Although data on mite populations were insufficient to draw valid conclusions, it should be noted that micro-sprinklers are considered by some growers to assist with twospotted spider mite control throughout the production season. Data also suggest that micro-sprinklers have a positive impact on reducing powdery mildew and botrytis fruit rot.
Micro-sprinkler irrigation over trees improved the color and anthocyanin of apples in a study conducted in Spain [
Thanks to Manzanita Berry Farms’ field crew, Chris Martinez, and Fritz Light for their technical assistance and Netafim and RDO Water for their financial support.
Dara, S.K., Sandoval-Solis, S. and Peck, D. (2016) Improving Strawberry Irrigation with Micro-Sprinklers and Their Impact on Pest Management. Ag- ricultural Sciences, 7, 859-868. http://dx.doi.org/10.4236/as.2016.712078