Welcome to the North San Joaquin Valley Cling Peach Day Sponsored by UC Cooperative Extension & the California Cling Peach Board.

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Presentation transcript:

Welcome to the North San Joaquin Valley Cling Peach Day Sponsored by UC Cooperative Extension & the California Cling Peach Board

Fertilization Guidelines for Peaches Roger Duncan Pomology & Viticulture Advisor University of California Cooperative Extension Stanislaus County

Today we will discuss: Nitrogen Phosphorus Potassium Zinc

A good fertility program is based on: Replacing what is removed with the crop –shouldn’t be based on “what I always do” Monitoring long term trends with annual tissue samples Occasional soil samples for gradual changes in soil chemistry. Yield is already affected by the time you see symptoms

Nitrogen Deficiency Mild deficiency: lack of growth, smaller, pale green leaves with red tinge N is mobile, shows in old and new leaves

Nitrogen Deficiency As deficiency worsens, leaves get yellower and smaller May develop red spots

Nitrogen Deficiency Lower N favors good color in fresh market fruit

Crop load drives demand for N: Between 2 – 3 pounds of N removed with every ton of peaches Perennial structure requires additional ~ 20 lb. per acre –More in high density orchards Leaves & prunings ~ 60 lb. (80-90% recycled)

Approximate N fertilizer requirements for mature peach and nectarine orchards. Assumes that prunings are not removed from the orchard 2.69 lbs. N are removed per ton yield 19 lb for perennial part of tree 90% recycle of leaves & prunings (~ 9 pounds) N use efficiency is 70% Yield (tons / acre)N (lb / acre)

Excessive N Fertilization Leads to: Excessive shoot growth Increased (summer) pruning costs Excessive shading of lower wood Shorter orchard lifespan More brown rot Poor coloration and delayed harvest (fresh market) Potential ground water contamination Regulations

Leaf sampling procedure: June – July Sample each variety / block separately Weaker or “different” areas of a block should be sampled separately

Leaf sampling procedure: 60 – 100 mid shoot leaves from current season shoots. Leaves treated with foliar zinc are not useful to determine zinc status Trees sprayed with N should not be sampled for at least one week Analyze promptly or refrigerate

Dormant Shoot Sampling: July sampled leaves too late for current season adjustment and for zinc contamination Sample 30 – 40 moderately vigorous shoots inches long from lower canopy. Guidelines are for January but fall may give similar results

UC Guidelines for Nitrogen in July- Sampled Leaves and Dormant Shoots July Leaf (%)Dormant Shoot (%) Fresh MarketProcessing Deficient< 2.3< 2.4 Adequate2.4 – – Excessive> 3.0> 3.5

Nitrogen Fertilizers: Trees don’t care – N is taken up as nitrate whether organic or inorganic Nitrate very mobile in soil, leachable Ammonium less mobile but converted to NO 3 within days at warm temps –Nitrification; acidifies soil Urea converted to ammonium, will volatilize quickly on soil surface

Time of Nitrogen Fertilizer Application: Trees take up almost no nitrogen when leaves are absent. Nitrogen for spring growth comes from N stored in roots, trunk, shoots. Nitrogen applied before leaf out is susceptible to loss by leaching and volatilization.

Time of Nitrogen Fertilizer Application: Peaches relatively low users of nitrogen compared to almonds so don’t need to “front load” so much. Extra earlies (especially May – June fresh market peaches) –Too much N early leads to excessive growth after harvest, poor quality –Late summer applications might be good strategy Provides N for next year’s crop without excessive post-harvest growth –Foliar urea in fall

Foliar Nitrogen Application: Studies show that 20 – 50% of N can be supplied through the leaves Urea is cheapest and mostly easily absorbed into the leaf Up to 50 lbs. of N / acre (100 lbs. urea) can be sprayed per application Multiple applications OK two weeks apart

Foliar Nitrogen Application: When to spray October –Before natural leaf senescence –September too soon due to earlier defoliation If combined with zinc, more N (and Zn) mobilized into storage than if applied alone

Phosphorus P deficiency is very rare in California Most soils contain a lot of P, most is in unavailable form

Phosphorus Deficiency Lack of spring growth

Phosphorus Deficiency Reddening of new growth in spring More mature leaves can be darker green than normal

Phosphorus Deficiency Phosphorus deficient leaves turn purple in fall

Phosphorus Deficiency Branches can defoliate and collapse under severe deficiency

Phosphorus Deficiency Some varieties may crack under severe P deficiency

UC Guidelines for Phosphorus in July- Sampled Leaves and Dormant Shoots July Leaf (%) Dormant Shoot (%) Deficient< 0.12* Adequate0.12 – Excessive> 0.4 *Previous literature cited 0.10% P as adequate for leaves

Phosphorus Fertilization: Very rarely needed in California peaches 0.5 – 1.0 lb. P 2 O 5 removed per ton of fruit –10 – 20 lb. P in a 20 ton crop P is very immobile in soil. Cannot be leached with irrigation or rain. Therefore timing is not important. Usually drilled 6 -8 inches deep If fertigated by drip, be careful not plug with calcium phosphate precipitate

Phosphorus Fertilization: Side note – phosphorous acid materials (phosphites) do not supply tree with P Good for Phytophthora management, not as a P fertilizer

Potassium (a.k.a. Potash) More potassium removed than N Can influence fruit size Might be neglected more than it should be

Potassium (a.k.a. Potash) Deficiency usually first seen in early summer Potassium deficient leaves tend to roll at the edges –Midshoot leaves affected most

Potassium Deficiency Leaves may also be a little pale. Margins may scorch

Potassium Deficiency Fruit set, shoot growth and leaf size is reduced Fruit size and color are reduced *Fruit size can be reduced before other signs are obvious

Potassium Deficiency Severe potassium deficiency can lead to defoliation and limb death

UC Guidelines for Potassium in July-Sampled Leaves July Leaf (%) Dormant Shoot (%) Deficient< 1.0 Adequate> 1.2*? Excessive *Probably should be > 1.5% K to ensure that the majority of trees are over 1.2%

Potassium Fertilization: Average of 4 – 5 lb. K 2 O (3.3 – 4.2 lb. K) removed per ton of fruit = 80 – 100 lb. K 2 O in 20 ton yield

Potassium Fertilizers: Potassium can be tightly bound to clay particles so generally we apply high quantities in concentrated applications to overcome problem Less of an issue in sandy soil or where active roots are very shallow –Drip or microsprinklers Adding gypsum (CaSO 4 ) can help K move deeper in soil

Potassium Fertilizers: Potassium chloride (KCl) Probably cheapest form per pound of K 2 O but risky due to Cl component Should be applied after leaf drop in fall Sulfate of potash (K 2 SO 4 ) –More expensive than KCl but safer –Not soluble but can be applied through solutionizer –May be able to broadcast in sandy soil under microsprinkler

Potassium Fertilizers: If banding sulfate of potash (K 2 SO 4 ) in drip-irrigated orchard, drip hose must be placed over band

Potassium Fertilizers: Potassium nitrate (KNO 3 ) –Also supplies N which should be accounted for –Can be applied as foliar spray –Foliar KNO3 applied during stage III may be effective – high demand period –May require multiple sprays at 40 lb to correct deficiency Potassium thiosulfate (KTS ) –Efficiently applied with fertigation but more expensive

Zinc - Influences on Deficiency: Soil pH – Zn availability decreases over pH 6.0 Lime (calcium carbonate) ties up zinc. Magnesium carbonate is worse Land leveling - zinc content decreases with soil depth. High amounts of phosphorus (ties up zinc)

Zinc - Influences on Deficiency: Organic matter and manure –Zinc is less available in soils with a high OM content. –Heavy manure - chicken manure is particularly bad High levels of other metallic elements (copper, iron, manganese) can induce zinc deficiency Cool, wet soils Rootstock (nemaguard is bad)

Zinc Deficiency Interveinal yellowing with mild zinc deficiency

Zinc Deficiency Very small, pale, pointy leaves in a rosette (very short space between leaves) with more severe zinc deficiency

Zinc Deficiency Extreme deficiency looks like glyphosate damage

UC Guidelines for Zinc in July-Sampled Leaves and Dormant Shoots July Leaf (ppm) 1 Dormant Shoot (ppm) Deficient< 15 2 < 15 1 Leaf samples are not reliable if orchard has been previously sprayed with zinc 2 Recent experiments indicate that a threshold of 10 ppm zinc is more appropriate for July-sampled leaves

Foliar Applications of Zinc

Zinc Materials Basic Chemicals Zn sulfate Zn oxide Zn carbonate Zn chloride Zn oxysulfate Zn nitrate Chelates & Complexes EDTA Lignosulfonate Amino acid Sugar Citric acid Fulvic acid, humic acid

Zinc Materials Zinc Sulfate (35% Zn) Inexpensive Very soluble Widely used Considered to be effective Can be phytotoxic

Zinc Materials Basic or Neutral Zinc Cost = 2x Zn sulfate Mostly insoluble Widely used Considered to be effective Not phytotoxic Can be mixed with oil

Zinc Materials Amino Acid Complexes Expensive Considered to be effective Can be phytotoxic 6 to 7% zinc

Zinc Materials Zinc Chelates Not cheap Usually EDTA Low phytotoxicity 7 to 9% zinc

Zinc Sulfate Damage Sprayed in April at 1000 ppm (2 lb)

Fruit Damage from Zinc Sprays

Control Neutral -52% Fulvic Sulfate Lignosulfonate A.A. Complex EDTA Nitrate Leaf & Fruit Damage on Peach, Plum and Apricot Trees Sprayed in April with Different Formulations of Zn at 1,000 ppm Leaf & Fruit Damage on Peach, Plum and Apricot Trees Sprayed in April with Different Formulations of Zn at 1,000 ppm Fruit damage Leaf damage Damage Rating

Treatment Zinc Formulations Applied Foliarly to Peach Seedlings Leaf Area on Lateral Shoots Zinc Formulations Applied Foliarly to Peach Seedlings Leaf Area on Lateral Shoots c b a b b b a Leaf Area (cm 2 ) UTC Zn to Roots SO 4 EDTA Polyamine Leonardite O + SO 4

Comparing Zinc Formulations Most Effective =Nitrate (Patrick’s mix) Sulfate – 36% Carbohydrate (Zicron) Polyamine EDTA Leonardite Oxysulfate – 52% Least Effective =ZnO Suspension

Strategies with Zinc Sulfate (Timing, Rate, etc) 1.Spring – Phytotoxicity concerns 2.All Season – Low rate 3.Fall or Dormant

Strategies with Zinc Sulfate (Timing, Rate, etc) 1.Spring – Phytotoxicity concerns Zn Oxide or Neutral Zn? 2.All Season – Low rate 3.Fall or Dormant

Strategies with Zinc Sulfate (Timing, Rate, etc) 1.Spring – Phytotoxicity concerns Zn Oxide or Neutral Zn? 2.All Season – Low rate Efficiency? 3.Fall or Dormant

Strategies with Zinc Sulfate (Timing, Rate, etc) 1.Spring – Phytotoxicity concerns Zn Oxide or Neutral Zn? 2.All Season – Low rate Efficiency? 3.Fall or Dormant Early fall better than late fall Use rate that doesn’t defoliate quickly

Strategies with Zinc Sulfate (Timing, Rate, etc) 1.Spring – Phytotoxicity concerns Zn Oxide or Neutral Zn? 2.All Season – Low rate Efficiency? 3.Fall or Dormant Early fall better than late fall Use rate that doesn’t defoliate quickly Fall better than dormant

Zinc Conversions (Approximate) Zn Concentration (ppm) Zn Sulfate/100 gals (lbs) 36% Zn Zn EDTA/100 gals (qrts/ gals) 9% Zn Zn Metalosate/100 (gals) 6.8% Zn /3 qt1 pint /3 qt1 qt qt3 pints /3 gal½ gal 5001½ gal 1,00021 gal5 qts 2,00052 gals2.5 gals 5, gals 10, gals

Cost of Zinc Materials - October 2007 $2.22 $4.12 $7.55 $9.15 $12.88 $15.19 $16.51 $17.01 $ % 40% 9% 5% 6.8% Zn Metalosate Zn Fulvic N Zn Zn Leonardite Zn EDTA Zn Ligno-Sulfonate ZnO Suspension Neutral Zn Zn Sulfate 52% 7% 6.5% 10% Zn Oxide 80% $1.15