The growth stage of a crop is a critical piece of information for growers and agronomists. For small grain crops like wheat and triticale, many field management decisions are sensitive to the stage of crop development. These include irrigation, fertilizer additions, herbicide and pesticide applications, and harvest timing. In addition, the planting date, the amount and timing of rainfall and/or irrigation, and cumulative seasonal temperatures all impact how rapidly a crop emerges, develops and matures. Because of the extreme variability in winter weather in the state, rates of development for small grain crops in California are not always consistent from year-to-year and farm-to-farm. This can make precision management and planning more difficult.

As a result, we have created a new interactive website, The Crop Growth Stage and Forecasting Web-Tool, to improve the understanding of crop growth stages for fall-planted small grain crops in California. Users of this tool can input site- and time-specific information (e.g. location, planting date, crop type, irrigation) and receive a growth stage estimate for their wheat and triticale crops.

The growth stage estimate is based on a model developed from multi-season observations of wheat and triticale development in University of California field trials. The web-tool utilizes site- and time-specific weather to produce a predicted growth stage, alongside interactive graphs related to seasonal water and nitrogen (N) uptake patterns. The graphs include historical data (10-yr average), making it easy to compare the current season to average conditions. Forecasts are also available for the main crop-growing regions of California enabling users to anticipate changes in crop growth and development in the near-term. Users can also download their location-specific data for further exploration.

The Crop Growth Stage and Forecasting Web-Tool is one of a growing number of interactive, decision support web-tools available on the UC Small Grains Research and Information Center Website. These tools feature interactive user experience and communicate spatiotemporally specific information on a growing number of topics related to the management of small grains in California. Check them out at https://smallgrains.ucanr.edu/Decision_Support_Tools/. Also, sign up for updates related to UC small grain crop research and extension at the UC Small Grains Blog.

The California Dry Bean Advisory Board (CDBAB) is requesting applied research proposals for 2023. This commodity-based research request is sponsored by the California Dry Bean Marketing Order, under the guidance of CDFA (CA Dept Food & Ag). The Board has supported applied research by university programs for many years.

Attached, please find the grant application as well as a list of the 2023 applied research priorities developed by the CDBAB. The Board is particularly interested in pest management projects to address weeds and insects. Funding is for one year. Proposals for projects extending beyond one year must be re-submitted each year.

Due to limited research funding, proposals that demonstrate cost sharing are encouraged. Although, there is some flexibility in the budget below, the total amount of funding available for 2023 is as follows:

Board: $60,000

Baby lima council: $2,500

Blackeye council: $10,480

Garbanzo council: $15,000

Large lima council: $0

Common bean council: $0

Total: $87,980

For current information on dry bean production in California as well as past reports funded by the board, see the Dry Bean webpage on the Agronomy Research and Information Center. You can search and view previously funded research reports from the online database.

Please share this call for proposals with colleagues and others who might be interested in dry bean research. Proposals are due by Friday, February 10, 2023. Progress reports for projects funded by the CDBAB in 2022 will also be due Friday, February 10, 2023. Attached is an example progress report. 

Those who submit proposals should be prepared to give a brief presentation to the Board at their first meeting of the year, which usually occurs in early March. Funding decisions are communicated shortly thereafter by Board Manager, Nathan Sano.

With questions, or to submit 2023 proposals and 2022 final reports electronically, please email Michelle Leinfelder-Miles and Nick Clark, UC ANR co-liaisons to the CDBAB.

Although much of this year's wheat has been planted, the cost of fertilizer and an unpredictable rainy season mean it's never a bad time to learn more about how to improve nitrogen management in small grains.

Join us for nitrogen management seminars being offered in the northern San Joaquin and the southern Sacramento Valleys. The seminars will cover a range of topics related to the use of the Nitrogen Fertilizer Management Tool for California Wheat. Lunch will be provided. 

Over the years UC agronomists have had considerable success using the Webtool and working with growers to optimize nitrogen fertilizer inputs in small grains. The tool and some of the methods behind it have been able to improve grower margins by reducing inputs costs or recommending appropriate amounts of in-season fertilizer to ensure yield potential.

CCAs and other crop consultants will benefit from an improved understanding of nitrogen management in small grains that can be used to better advise their clientele. Growers will benefit from a better understanding of in-season crop needs and what types of information can be gathered to inform their crop fertility decisions. 

San Joaquin County: 

Wednesday December, 14 2022

2101 E Earhart Ave

Stockton, CA 95206

10:00 a.m. - 12:00 p.m.

RSVP for SJ Seminar lunch, click here

Sutter County: 

Thursday February 23, 2023

142 Garden Hwy

Yuba City, CA 95991

9:00 a.m. - 11:00 a.m. 

RSVP for Sutter Seminar lunch, click here

N-rich reference zones

Cereal rye, triticale and oats are commonly used as cover crops in the Salinas Valley in fall grown (Aug/Sept to Oct/Nov) and overwintered (Oct/Nov to Feb/March) planting slots. A key issue for growers is when to terminate the cover crop. This boils down to availability of equipment or breaks in the weather. Those types of issues are unavoidable and usually take precedence in decision making. In this article, we describe the various stages of cover crop seed development so that growers can let their cereal cover crop grow as long as possible without the risk of it producing seed that would become a weed in subsequent vegetable crops. This will allow the carbon to nitrogen (C:N) ratio to increase as high as possible to maximize the input of carbon to the soil to benefit soil health and potentially suppress soilborne diseases.

In the central coast region, there is often confusion and concern about when the cover crop will set seed. However, the presence of heads in the cover crop does not mean that seed set is about to happen. Seed formation in cereals follows the relatively lengthy process of pollination and seed development as laid out in the Feekes growth and development chart (Table 1; for a complete chart go to: Kansas State University or University of Wisconsin). Flowering occurs in Feekes stages 10.5.1 to 10.5.3 beginning in the center of the head (Figure 1). During these stages the cover crop is not setting seed but is pollinating. After pollination, the next Feekes stage is 10.5.4 which is when the seed is in the ‘watery ripe' stage (Figure 2).  To avoid the risk of viable seed set, we recommend that growers not let their cover crops get past the 10.5.4 Feekes stage.  In other words, it is best not to let the seed become milky (11.1) or mealy (soft dough) (11.2) ripe.

The amount of time from full heading through the stages of flowering shown in Figure 1 can vary based on temperature, time of year (day length) and variety. For example, in an over-winter trial planted October 1, 2021 at the USDA-ARS at organic research farm in Salinas, a UC696 barley cover crop reached the soft  dough stage (11.2) at 122 days after planting whereas by that time, Pacheco triticale and Merced rye were still only at the water ripe stage (10.5.4); by 150 days after planting the barley was at Feekes 11.3 (hard dough) while rye and triticale were at 11.1 (milky ripe stage). This is why barley is not often used as a cover crop in the region because it has greater potential to set seed than later maturing types of cereals like rye and triticale.  However, seed set by cover crops like Merced rye is extremely uncommon here.  For example, in a long term organic cover crop study with intensive vegetable production at the USDA-ARS in Salinas, there were never any problems with viable seed production by Merced rye cover crops planted from October 15 to November 2 and terminated from February 11 to March 18. Over 8 years the average oven-dry shoot biomass production in that trial was more than 6000 lb per acre and the C:N was 29 (Brennan and Boyd, 2012; Brennan, Boyd and Smith 2013).  Unfortunately, in that trial we did not collect data on the Feekes growth stages of the rye. However, data from our planting date trials this past winter at the same location indicates that overwintered Merced rye planted even early as October 1 needs more that 120 days of growth to develop past the Feekes 10.5.4 stage (watery ripe). The development of Merced rye planted October 15 to November 30 was even more delayed and had not even started to flower by 119 to 122 days after planting.

This all indicates that for an overwintered Merced rye cover crop, there is very little risk of viable seed set before 120 days of growth even for rye planted as early as October 1 when the days are still relatively long and warm. Our data thus far suggests that it takes approximately 1000 degree days (°C) to reach the 10.5.4 growth stage; this assumes a 4 °C based threshold and single sine/horizontal method calculated on the UCIPM degree day calculator available here.  To put this in context, for a summer/fall cover crop planted on August 1 this year, 1000-degree days were reached by October 13 (74 days after planting) based on this weather station (NCDC #7669, Salinas FAA Airport).  In contrast, if that cover crop had been planted on October 1, 2021, it would reach 1000 degree days by January 24, 2022 (115 days after planting).  Thus, growers can use the degree calculator and historic data to estimate degree day accumulation for cover crops planted at various times of year. 

The simplest way to determine how close the cover crop is to forming viable seed is to examine the cover crop to see if fresh yellow anthers are present (older anthers may hang onto the head, but will often bleach to a dull, white color) and where they are occurring on the head (Figure 1). Anthers are visible regardless of the type of cereal crop, but in our experience, they are more apparent in crops like rye than in other cereals. It should be noted that anthers may be present/visible after the crop has moved beyond anthesis. To confirm if the seed is getting close to maturing, it is best to examine the seed in the heads to see if they are maturing past the watery ripe stage (Figure 2), particularly if the crop has not been frequently monitored and/or the onset of anthesis is unknown. Given favorable weather and available equipment, this information can help provide context about the risk of seed set and help you decide whether to allow the cover crop to continue to grow and thereby increase the C:N ratio. Learning to identify the Feekes growth stages of a cover crop will not only help growers become more knowledgeable about when a cover crop needs to be terminated to avoid setting viable seed. It will also help growers get a higher cover crop nitrogen scavenging credit as part of Ag Order 4.0 as described in this recent video.

Figure 2. A Merced rye seed at Feekes stage 10.5.4, watery ripe and the head that it came from. Notice that it is greenish and translucent. This cover crop was planted at the USDA-ARS in Salinas on November 30, 2021, and photographed April 15, 2022. It will become more opaque when it reaches Feekes stage 11.1, the milky ripe stage.

Table 1 has an evaluation that we just completed of a fall-grown cover crop in a grower's field in Gonzales, CA over a three-week period. As can be seen, the biomass production and C:N ratio of the cover crop increased each week that the cover crop was allowed to continue growing (Table 1, Figure 3). By October 24^th many seed in the heads of the cover crop were at the watery ripe stage and it was judged that it was time to terminate the cover crop to avoid the risk of setting viable seed.

A cover crop with a greater C:N ratio provides more carbon to the soil which can provide greater benefits to soil health such as improving water infiltration and soil tilth and potentially help the soil be more suppressive of soilborne diseases. It also gives you a better ‘return' on the investment (seed cost, irrigation, labor, etc.) that you put into the cover crop.

Table 1. Merced rye late summer/fall cover crop evaluation conducted in 2022 evaluating the impact of allowing the cover crop to continue to grow. The cover crop was planted Aug. 18 in Gonzales. These values are based on data from 10 samples in the field on each harvest date.

 

 

Figure 3. Merced rye cover crop biomass changes over time.

Caveats and cautions:

Merced rye, like other cereal rye varieties (i.e., FL104) is an out-crossing variety that tends to be more variable in its development than other small grains like triticale that are self-pollinated and more uniform.  This is important keep in mind when evaluating the growth stage of a field. However, with all cereal cover crops it is important to look at the most advanced part of the field (i.e., where irrigation occurred first) and the most developed plants and make your decision about how to manage the field from them. When checking grain stages, be aware that different kernels from the same head can vary in developmental stage. Therefore, checking multiple kernels to determine the status of the head is advisable.