Method for reduction of sucrose loss during storage or sugar beets due to reduction in respiration and invert sugar formation

Information

  • Patent Grant
  • 4021231
  • Patent Number
    4,021,231
  • Date Filed
    Tuesday, May 14, 1974
    50 years ago
  • Date Issued
    Tuesday, May 3, 1977
    47 years ago
Abstract
Respiration of sucrose to carbon dioxide and water is reduced and the formation of invert sugar is inhibited in the storage of sugar beets which have had an effective amount of ethylene introduced into the ground near the roots of the growing plants.
Description

BACKGROUND OF THE INVENTION
Ethylene has received some attention as a potentially useful plant growth regulator. For example, ethylene and acetylene are described in U.S. Pat. No. 2,047,874 as being useful in either gaseous form or in an aqueous solution for causing pineapple and other plants to flower and mature sooner than they would otherwise. U.S. Pat. No. 2,084,461 is directed to the use of ethylene gas, or another unsaturated hydrocarbon gas such as butylene or propylene, for inducing uniformity of blooming and fruit production in fruiting plants, especially fruit trees. U.S. Pat. No. 3,661,549 is directed to the use of aqueous solutions of ethylene and compounds which yield ethylene for inducing growth of yield crops such as soybean and corn. Although some of the findings of the effects of treating plants with ethylene are interesting from a scientific point of view, they have not met with any substantial commercial success.
SUMMARY OF THE INVENTION
This invention is based upon the discovery that when sugar beets are treated with soil injected ethylene during growth, at 1.4 to 5 pounds ethylene per acre, the resulting sugar beets have about 20% less respiration during storage and have only about one third the usual amount of invert sugar as untreated sugar beets. This results in about a 20% increase in recoverable sucrose when the beets are processed.





DESCRIPTION OF PREFERRED EMBODIMENT
The depth beneath the ground surface and the distance from the sugar beet rows at which ethylene is introduced will depend upon several factors, as for example, the type of soil, moisture content of soil and the like. The depth at which ethylene is introduced for sugar beets is from about 6 to 8 inches at about 6 foot intervals in about the middle of the row when the sugar beets have reached the fifth leaf stage of growth.
The ethylene is introduced in an amount sufficient to reduce respiration and invert sugar formation. The ethylene is injected 6 to 8 inches deep in the soil at about 6 foot intervals near the middle of the rows when they have reached the fifth leaf stage of growth at a rate of about 1.4 to 2.8 pounds per acre with from one to three applications. The injections are made at the equivalent of late June or early July and the ethylene carries through its effects even after harvest. The treated sugar beets are found to have a much lower endogenous ethylene evolution from the tissues than untreated beets which in turn shows a much lower respiration during storage.
The respiration as set forth in Tables I and II was determined in respiration chambers in the following manner. Air which has been humidified and scrubbed clean of carbon dioxide is passed through respiration chambers each of which contained 20 pounds of sugar beets. The air flushed the carbon dioxide given off by respiration out of the chamber and the carbon dioxide is captured in a sodium hydroxide solution. The sodium hydroxide was back titrated with 0.5N hydrochloric acid to determine the amount of carbon dioxide evolved. Respiration measurements were carried out at 40.degree. F. which is considered an ideal temperature for storage of beets.
TABLE I______________________________________Effect of Soil Injected Ethylene on RespirationSugar Loss - lb/Ton/DayTreat- Mean of Percentment Numbers of Mean of All Ethylene Differ-in lbs/A Applications Replications Versus Control ence______________________________________0 0 0.389 0.3891.4 1 0.3101.4 3 0.327 0.333 -14.42.8 1 0.3722.8 3 0.321______________________________________
TABLE II__________________________________________________________________________Effect of Soil Injected Ethylene on Respiration of Harvested Sugar Beets Sugar Content Weight Loss Sugar Loss ExtractableTreatment Number of Sugar at After 124 Days After Storage- After Storage- Sugar Loss-in lbs/A Applications Harvest-% Storage-% lbs/ton/day loss/ton/day lbs/ton/day__________________________________________________________________________0 0 17.19 14.44 0.113 0.458 0.451Ethylene1.4 1 16.31 14.72 0.082 0.268 0.3461.4 3 16.92 14.86 0.187 0.359 0.3782.8 1 17.02 14.94 0.110 0.318 0.3272.8 3 16.91 14.77 0.110 0.359 0.383 Mean of all ethylene versus control Control 0.458 0.451 All Ethylene 0.326 0.359 Percent Difference -28.8 -20.4__________________________________________________________________________
Table III shows the effect of soil injected ethylene on invert sugars in harvest sugar beets. Invert sugar (glucose and fructose) forms during storage from degradation of sucrose. Soil injected ethylene inhibits the formation of invert sugar during storage. Invert sugar was determined by the tetrazonium method of A. Carruthers and A. E. Wooton (1955 Int. Sug. J. 57:193).
TABLE III__________________________________________________________________________Effect of Soil Injected Ethylene on Invert Sugars in Harvested SugarBeets Increase In Mean of All Invert Invert EthyleneTreatment Number of Time of Sugars Sugars Versus Control Percentin lbs/A Applications Sample g/100 RDS g/100 RDS g/100 RDS Difference__________________________________________________________________________0 0 in 0.644 out 1.785 1.141 1.1411.4 1 in 0.602 out 0.962 0.3601.4 3 in 0.650 out 0.786 0.136 0.510 -55.22.8 1 in 0.541 out 1.121 0.5802.8 3 in 0.491 out 1.453 0.962in = Invert sugars determined at harvestout = Invert sugars determined after 124 days storageInvert Sugar Formation Plus Respiration Loss Sugar Loss, Percent lbs/ton/day DifferenceControl 0.431Ethylene (all treatments) 0.347 -19.5__________________________________________________________________________
Table IV shows the ethylene evolution from stored sugar beets treated with ground injected ethylene. The table shows that beets treated with ground injected ethylene display a lower ethylene evolution from the beet tissue which indicates a much lower respiration during storage than the untreated control.
TABLE IV______________________________________Stored Sugar Beet EthyleneEvolution From Field Soil Injected Ethylene Replication I Replication II Ethylene Ethylene Number of Evolved EvolvedTreatment Applications in parts/billion in parts/billion______________________________________Control 0 90 751.4 lbs/acre 1 40 501.4 lbs/acre 3 50 402.8 lbs/acre 1 50 402.8 lbs/acre 3 40 35______________________________________
Respiration of sucrose to carbon dioxide and water accounts for a major portion of the sucrose lost during storage. Sucrose is also lost in the stored beet when it is hydrolized to invert sugars. Under normal storage conditions respiration and invert sugar formation account for 85% to 95% of the total sucrose degradation. Invert sugars indirectly increase the storage loss by decreasing extraction of sucrose in the factory process. The loss of sucrose during storage amounts to a monetary loss to the industry of millions of dollars each year.
Claims
  • 1. A method for reduction of sucrose loss during storage of sugar beets due to respiration and invert sugar formation which comprises injecting ethylene gas into the soil between and near the middle of rows of growing sugar beets at spaced intervals in amounts sufficient to reduce respiration and inhibit invert sugar formation in the harvested beets, at a depth of from 6 to 8 inches beneath the soil when the beets have reached the fifth leaf stage.
  • 2. The method of claim 1 when the ethylene is injected at about six foot intervals in the amounts of from about 1.4 to 2.8 pounds per acre in from one to three applications.
US Referenced Citations (4)
Number Name Date Kind
2285932 Leavitt Jun 1942
2424520 Tonkin Jul 1947
3184891 Frontzen May 1965
3661549 Freytag et al. May 1972
Non-Patent Literature Citations (4)
Entry
Wyse et al., Chem Abst., vol. 80 (1974) 105944r.
Tewari et al., Chem. Abst., vol. 81 (1974) 34449r.
Sagir et al., Chem Abst., vol. 76 (1972) 95618p.
Narayama, Chem. Abst., vol. 76 (1972) 95623m.