Posts Tagged: evapotranspiration
Atmometer Study
Efficient and precise irrigation management is critical if California producers are to maximize crop quality, conserve water, and protect the environment. The use of evapotranspiration (ET) estimates is a significant component of irrigation management. ET refers to the sum of water lost from the soil (evaporation) as well as that used by the crop (transpiration). While the California Irrigation Management Information System (CIMIS) network of weather stations derive daily ET values, there is a perception that CIMIS does not produce accurate ET estimates for all locations. This view is particularly prevalent in the canyons of Ventura County where weather conditions differ substantially compared to CIMIS locations. Since avocado and citrus thrive in these areas, it was concerning when it was determined that ET scheduling is not widely used.
That is, a Ventura County Resource Conservation District (RCD) review of California Department of Food and Agricultural State Water Efficiency and Enhancement Program (CDFA SWEEP) projects concluded that Ventura County growers substantially lagged their state-wide peers with respect to implementing ET-based irrigation scheduling (14% versus 44%).
RCD seeks to reverse the low implementation of ET-based irrigation scheduling within Ventura County by using simple, rugged on-site ET devices (atmometers) to determine on-site ET values. These on-site values will be compared to CIMIS values to determine local correction factors and develop refined ET maps for the canyon and valley areas. RCD will present these results at outreach events and provide workshops demonstrating how ET data, whether from CIMIS or on-site atmometers, can be used for irrigation management.
PHOTO: Atmometer Test/Calibration Site @ UC Hansen
atmometer calibration
What Happens to Trees on a Hill?
Many orchards in California are planted on slopes, the most extreme examples are usually avocado orchards with some slopes exceeding 50%. They pose difficulties in harvesting because of the steepness, but also in their irrigation. These slopes can be north/south/east/west facing or all of the quadrants in the same orchard. The plantings can be of varying steepness and at different positions (toe, top, mid-slope). These positions affect solar radiation which is the main driver of evapotranspiration, but also wind interception. South and west facing slopes intercept the most sunlight, while north and east intercept the least. The top of the slope usually intercepts the most sunlight during the day and also the most wind. There can be 100% difference in the amount of ET depending on the position on the slope. That is, some trees require twice as much water as others because they are getting more energy that drives water loss.
When looking at an older avocado grove, the trees are usually larger at the bottom of the slope where there is the least wind and most irrigation water interception. This is where the soil is the deepest and has the greatest moisture reserve. The soils at the top of the slope are the shallowest and get the greatest amount of energy driving water loss. Trees on the north side are often tall from greater soil depth and moisture reserve and less ET demand. As the solar angle changes during the year (lower in the sky during the winter), the proportion of ET in these different positions changes.
Right. OK. We know this. The problem is that many smaller orchards are laid out so that there is one valve controlling the amount of water going to all the different positions. The trees at the bottom of the slopes get the same as those at the top. Those on the north side get the same as those on the south side. This basically sets up an orchard for stress. Stress that leads to disease and impacts on yields and ultimately the longevity of the orchard.
Add to this, irrigation performance varies with pressure and many orchards have very little pressure compensation. Often trees at the top of the slope have the lowest pressure and output. The distribution uniformity is often terrible. Not only are the normal problems of broken and clogged emitters an issue, but also pressure loss from elevation differences.
So where you plant on a hillside should be part of the irrigation design. In different positions on the hillside there are different water requirements and unless they are irrigated differently, there can be major differences in tree response. These different irrigation requirements should be incorporated into the irrigation design by creating as many different irrigation blocks as possible. A valve for the top of the slope, another for the north and south slopes, etc. These can be incorporated easily in the initial design and not so easily customized after the trees have been planted.
At some point, for optimum tree performance, tree health and water use efficiency, growers should recognize the need for irrigating to trees' needs according to slope position. Avocado growers have it harder than most growers.
Read more about an ET study done on a hill:
http://www.avocadosource.com/CAS_Yearbooks/CAS_86_2002/cas_2002_pg_099-104.pdf
hill trees
Capturing Rain
Capturing Precipitation - How much rainfall do I need to capture?
Managing precipitation to your advantage is really a three step process (Lal and Stewart, 2012).
ü Step 1 - maximize preciptitation captured in the soil
ü Step 2 - minimize the evaporation of the stored soil moisture
ü Step 3 - maximize plant water use efficiency
The first step of the process is often thought of as “effective rain”. Effective rainfall refers to the percentage of rainfall which becomes available to plants and crops. It considers “losses” due to runoff, evaporation and deep percolation (Klein, 2011). In the past we might have considered deep percolation as a loss. We now know that percolation “losses” may be a vital resource in sustaining our groundwater basins. As we move into the fall of 2015, we have the opportunity to plan for effective rainfall by managing the orchard floor for maximum capture of precipitation. This will help provide stored soil moisture for plant growth as well as deep percolation of water to groundwater
The following figure illustrates some of the important points about effective rainfall and reminds us of what we can do to maximize capture of precipitation (1). We want to maximize 2 (infiltration during a rain event), 3 (surface capture), 6 (infiltration from surface capture), 7 (percolation to ground water), and 8 (rootzone storage for use by the crop). We want to minimize 4 (runoff) and 5 (evaporation).
When rain water ((1) falls on the soil surface, some of it infiltrates into the soil (2), some stagnates on the surface (3), while some flows over the surface as runoff (4). When the rainfall stops, some of the water stagnating on the surface (3) evaporates to the atmosphere (5), while the rest slowly infiltrates into the soil (6). From all the water that infiltrates into the soil ((2) and (6)), some percolates below the rootzone (7), while the rest remains stored in the rootzone (8). From FAO Irrigation Water Management 1985 http://www.fao.org/docrep/r4082e/r4082e05.htm#4.1.4 effective rainfall
Larry Stein from Texas A&M wrote a very good basic explanation “So What Constitutes an Effective Rain Event ?” (Stein, 2011) We can use his approach to look at managing precipitation in the Central Coast. Understanding these concepts can help you manage precipitation in your operation.
For example, the majority of olive roots are in the top 18 inches of soil. So how much rainfall do we need to capture to refill the rootzone of an olive grove in Paso Robles? We need to know:
ü The amount and intensity of rainfall
ü The infiltration rate of the soil (how fast the soil takes in water). Sandy soils take water in more quickly.
ü How much water the soil will hold in the rootzone of the grove
Average rainfall for Paso Robles in January is about 2.75 inches. Table 1 shows that olives on a sandy loam soil might be able to infiltrate 1 to 1.5 inches per hour. If all that rain comes in one storm then as much as 1.25 inches may either run off (4) or pond (3) in the low spots until it can infiltrate.
Average rainfall in Paso Robles in January would be adequate to refill the rootzone of olives (8) on a sandy loam soil, IF all of the rainfall infiltrates (2), and none is lost to evaporation (5) or runoff (4).
Table 1. General soil water storage and depletion characteristics for three different soil types (Klein, 2011)
|
Soil Texture |
||
|
Sands |
Loams |
Clays |
Water infiltration rate (inches / hour) |
2.0 – 6.0 |
0.6 – 2.0 |
0.2 – 0.6 |
Available water (inches / foot) |
1.0 – 1.5 |
1.5 – 2.5 |
2.5 – 4.0 |
Days to depletion when ET – 0.2 inches / day |
5 – 7.5 |
7.5 – 12.5 |
12.5 – 20.0 |
Amount of water to wet to 18 inches in a dry soil (inches) |
1.5 |
2.25 – 3.0 |
3.75 |
Cover crops help keep the soil surface from crusting as well as protecting the soil surface from erosion. Their roots provide channels for water to infiltrate into the soil. Remember that cover crops may also be using water stored in the rootzone (8). When facing drought conditions, it may be advantageous to manage with low residue cover crops to reduce the amount of water extracted from the rootzone. Here's a link to a video on low residue cover crops and their impact on runoff from work by UC Cooperative Extension Advisors in Monterey County https://www.youtube.com/watch?v=k0oVVJ_BA7s
Klein, L. 2011. So What Constitutes an Effective Rain Event? http://aggie-horticulture.tamu.edu/earthkind/drought/drought-management-for-commercial-horticulture/so-what-constitutes-an-effective-rain-event/ .
Lal. R.and, B.A. Stewart. 2012. Soil Water and Agronomic Productivity
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rain
Predicting Water Demand Along the Coast Versus in the Valley
Recently I was asked why an irrigation schedule could be projected for almond and citrus in the Central Valley (Almonds:http://cekern.ucanr.edu/Irrigation_Management/Almond_Drip_-_Microsprinkler_-
_Flood_Weekly_ET/Citrus: http://cekern.ucanr.edu/Irrigation_Management/Citrus_ET_by_age/ ) and why the same couldn't be done for the main avocado growing areas. Here was my response:
Generating a generic irrigation schedule for avocados along the coast is very difficult and if done would be terribly misleading. Scheduling gets really hairy along the coast where avocados are grown. As you get further from the coast the water demand (ETo) increases in many months, typically increasing in the summer. This can be most pronounced in the late winter/spring when the fog along the coast really causes a contrast between coastal and inland conditions. May in Ventura, the sun comes out for about 2 hours and in Fillmore 20 miles inland it may be 90 F at 4 PM. The fog is a major determinant for irrigation demand and it varies daily, monthly and year to year from Monterey to San Diego. So fog can throw off an irrigation schedule.
The next variable to area-wide scheduling is the topography where avocados are grown, usually slopes to improve air and water drainage. Depending on the aspect and slope position, the ETo can vary tremendously depending on the sky conditions and what those conditions are depending on the time of day (such as foggy in the morning and clear in the afternoon). So west and south facing will always be higher than north and east. The top of the slope that intercepts more wind than the bottom and will have higher ETo than the bottom of the slope. And if the trees intercept more evaporative conditions midday when the sun comes out, it will be much higher than the east side in the morning when fog is dripping off the trees (zero evaporative demand). Then as you go south from Monterey to San Diego the ETo goes up, just because of latitude and sun interception. These conditions are very different from Fresno where ETo in July is 0.6 inches per day and is the same until Sept, the sky is clear most days and trees are grown on fairly flat ground.
Now throw in rainfall. Almonds are deciduous and only count on the value of rainfall as that which is stored in the rooting zone going into spring when leaves are come out. Avocados rely on winter rain for transpiration and salt leaching. In a good year a significant portion of the total yearly ETcrop can be subtracted from the irrigation demand. In a low/no rainfall year that all needs to be made up by supplemental irrigation.
An almond grower in the Valley might be able to go onto a calendar, set the clock if they have water on demand and walk away. That's never going to happen in a coastal avocado orchard. Depending on where the avocado is grown and the ETo at that site, applied water might vary from 1.5 ac-ft per acre to 3.5. This will depend on rainfall (when and how much), water quality (which determines leaching requirement) and the system delivery (system efficiency). This system issue can be further complicated by whether the delivery is on-demand or whether a certain amount will be delivered at a certain date for a certain length of time - 24 hours or 48. This makes it difficult for the grower to put on exactly what ETo and other issues the trees would demand. In this case, the delivery system determines the schedule.
So this is why there's no chart showing ET demand for coastal avocados where the bulk are grown in California.
A CIMIS (CA Irrigation Management Information System) DWR weather station for calculating crop water requirement.
CIMIS station
Water Demand in Plastic Tunnels used for High Value Crops
There is an increasing use of high stature plastic tunnels (macro-tunnels) to grow high value crops, such as raspberries, blueberries, vegetables and flowers. This is even in relatively frost free environment, such as coastal California. More commonly tunnels are used in colder climates to produce early season crops. But along the California coast there is increasing use because of other benefits, such as improved production and reduced disease. There is estimated to be about 11,000 acres in tunnels in Santa Barbara County and even more in Ventura.
A recent, unpublished study by Mike Cahn et al with UCCE in Monterey County evaluated water use by raspberries in tunnels. They found that pan evaporation was reduced by 18% in the tunnels over the season compared to open-field grown raspberries. Also, less water was applied for the inside trial than the adjacent outside trial. Even with the reduction in applied water the soil moisture remained higher inside the tunnels than outside. The canopy was larger earlier inside the tunnel than outside even though there evapotranspiration was lower inside the tunnels. The main components of transpiration are altered in tunnels. There is less radiation because of the interference of the plastic, less wind, higher humidity, despite the warmer temperatures.
macro-tunnel raspberry