The present disclosure provides compositions including a carrier and an element. The carrier includes starch and the element is covalently bonded to the carrier. A water droplet contact angle of the composition is greater than a water droplet contact angle of starch under the same conditions and after the same elapsed time up to one hours. The compositions may be used as a coating, such as for a seed or fertilizer particle, or may be added to soil for delivery of the element in biologically available form to a plant.
C05G 5/30 - Engrais caractérisés par leur forme en couches ou enrobés, p. ex. enrobages anti-poussière
A01N 25/26 - Biocides, produits repoussant ou attirant les animaux nuisibles, ou régulateurs de croissance des végétaux, caractérisés par leurs formes, ingrédients inactifs ou modes d'applicationSubstances réduisant les effets nocifs des ingrédients actifs vis-à-vis d'organismes autres que les animaux nuisibles sous forme de particules revêtues
A01N 59/00 - Biocides, produits repoussant ou attirant les animaux nuisibles, ou régulateurs de croissance des végétaux, contenant des éléments ou des composés inorganiques
The invention provides compositions comprising a polymeric carrier of cellulose and/or starch, and an element. The carrier is insoluble in water and a salt of the element is soluble or partially soluble in water. The compositions include at least about 5% (wt/wt) of the element, based on a total weight of the composition, and have particle sizes between about 0.05 mm and about 1.5 mm. Also provided are methods of making such compositions and methods for using the compositions to deliver the element to a plant.
The invention provides compositions comprising a polymeric carrier of cellulose and/or starch, and an element. The carrier is insoluble in water and a salt of the element is soluble or partially soluble in water. The compositions include at least about 5% (wt/wt) of the element, based on a total weight of the composition, and have particle sizes between about 0.05 mm and about 1.5 mm. Also provided are methods of making such compositions and methods for using the compositions to deliver the element to a plant.
C05G 3/40 - Mélanges d'un ou plusieurs engrais avec des additifs n'ayant pas une activité spécifique d'engrais pour influer sur le dosage de l’engrais ou sur sa vitesse de libérationMélanges d'un ou plusieurs engrais avec des additifs n'ayant pas une activité spécifique d'engrais pour influer sur la solubilité
11.
COMPOSITIONS FOR DELIVERY OF AN ELEMENT TO A PLANT AND METHODS OF MAKING SAME
The invention provides compositions comprising a polymeric carrier of cellulose and/or starch, and an element. The carrier is insoluble in water and a salt of the element is soluble or partially soluble in water. The compositions include at least about 5% (wt/wt) of the element, based on a total weight of the composition, and have particle sizes between about 0.05 mm and about 1.5 mm. Also provided are methods of making such compositions and methods for using the compositions to deliver the element to a plant.
C05G 3/40 - Mélanges d'un ou plusieurs engrais avec des additifs n'ayant pas une activité spécifique d'engrais pour influer sur le dosage de l’engrais ou sur sa vitesse de libérationMélanges d'un ou plusieurs engrais avec des additifs n'ayant pas une activité spécifique d'engrais pour influer sur la solubilité
The invention provides compositions and systems comprising a carrier and an element. The carrier is a network of polymers insoluble in water comprising phenolic hydroxyl moieties, aliphatic hydroxyl moieties or a combination thereof. An association between the carrier and the element is labile in response to biological demand and the lability of the association in the presence of water is less than the lability of the association in response to biological demand. Also provided are methods of making such compositions and methods for delivering the element to an organism.
C05D 9/02 - Autres engrais inorganiques contenant des éléments à l'état de traces
C05G 3/40 - Mélanges d'un ou plusieurs engrais avec des additifs n'ayant pas une activité spécifique d'engrais pour influer sur le dosage de l’engrais ou sur sa vitesse de libérationMélanges d'un ou plusieurs engrais avec des additifs n'ayant pas une activité spécifique d'engrais pour influer sur la solubilité
42 - Services scientifiques, technologiques et industriels, recherche et conception
Produits et services
Marine research in the field of marine exploration and discovery, marine ecosystem health, marine resource utilization, and technology for ocean science
42 - Services scientifiques, technologiques et industriels, recherche et conception
Produits et services
Marine research in the field of marine exploration and discovery, marine ecosystem health, marine resource utilization, and technology for ocean science
The invention provides compositions and systems comprising a carrier and an element. The carrier is a network of polymers insoluble in water comprising phenolic hydroxyl moieties, aliphatic hydroxyl moieties or a combination thereof. An association between the carrier and the element is labile in response to biological demand and the lability of the association in the presence of wate is less than the lability of the association in response to biological demand. Also provided are methods of making such compositions and methods for delivering the element to an organism.
The invention provides compositions and systems comprising a carrier and an element. The carrier is a network of polymers insoluble in water comprising phenolic hydroxyl moieties, aliphatic hydroxyl moieties or a combination thereof. An association between the carrier and the element is labile in response to biological demand and the lability of the association in the presence of wate is less than the lability of the association in response to biological demand. Also provided are methods of making such compositions and methods for delivering the element to an organism.
PROCESS AND METHOD FOR THE ENHANCEMENT OF SEQUESTERING ATMOSPHERIC CARBON THROUGH OCEAN IRON FERTILIZATION, AND METHOD FOR CALCULATING NET CARBON CAPTURE FROM SAID PROCESS AND METHOD
Disclosed is an enhancement of a carbon sequestration process and method for calculating the quantity of atmospheric carbon sequestration manifested by enhanced oceanic photosynthetic productivity through the process of Iron fertilization. This method and process comprises (1) defining a project boundary, (2) obtaining certain baseline measurements, metrics and observations within and beyond the project boundary, (3) applying an Iron compound within the project boundary to enhance photosynthesis, (4) obtaining certain measurements, metrics and observations within and adjacent to the project boundary prior to and after the introduction of Iron compound and last, (5) applying a method based on the measurements from steps 2 and 4 to determine the net quantity of atmospheric carbon that is sequestered.
Disclosed is a method and process for measuring oceanographic parameters that may be used to create estimates of the quantity of carbon dioxide gas that is removed from the atmosphere from an Ocean Iron Enrichment event. This process uses data observations from Autonomous Underwater Vehicles, Satellite observations and/or Unmanned Aerial Vehicles to determine metrics such as chlorophyll, temperature, turbidity, oxygen, particulate inorganic carbon etc. that may be used to calculate the total anthropogenic carbon dioxide that is removed from the atmosphere. Therefore, the carbon dioxide removal may be determined without requiring a manned presence in the area of study, providing a significant reduction in cost. Direct in-situ measurements of carbon flux through analysis of physical samples through the water column may be used as a verification/calibration metric using sediment traps spaced vertically in the water column from surface to the deep thermocline layer. Alternatively, water samples may be collected and used as an alternative.
Disclosed is a method and process for manifesting sustainable improvement in fisheries productivity in Ocean waters. This method and process comprises (1) selecting a location of the Ocean that is considered both High Nutrient Low Chlorophyll (HNLC) and (2) that this location is within proximity to fisheries feeding grounds or migratory routes or within areas that are considered to be fish feeding areas (3) within this location, a surface sea height anomaly (Ocean Eddy) is defined using satellite s.s.h. data (4) applying a fertilizer that contains an Iron compound within the Ocean Eddy.
PROCESS AND METHOD FOR THE ENHANCEMENT OF SEQUESTERING ATMOSPHERIC CARBON THROUGH OCEAN IRON FERTILIZATION, AND METHOD FOR CALCULATING NET CARBON CAPTURE FROM SAID PROCESS AND METHOD
Disclosed is an enhancement of a carbon sequestration process and method for calculating the quantity of atmospheric carbon sequestration manifested by enhanced oceanic photosynthetic productivity through the process of Iron fertilization. This method and process comprises (1) defining a project boundary, (2) obtaining certain baseline measurements, metrics and observations within and beyond the project boundary, (3) applying an Iron compound within the project boundary to enhance photosynthesis, (4) obtaining certain measurements, metrics and observations within and adjacent to the project boundary prior to and after the introduction of Iron compound and last, (5) applying a method based on the measurements from steps 2 and 4 to determine the net quantity of atmospheric carbon that is sequestered.
G01V 9/00 - Prospection ou détection par des procédés non prévus dans les groupes
30.
PROCESS AND METHOD FOR THE ENHANCEMENT OF SEQUESTERING ATMOSPHERIC CARBON THROUGH OCEAN IRON FERTILIZATION, AND METHOD FOR CALCULATING NET CARBON CAPTURE FROM SAID PROCESS AND METHOD
Disclosed is an enhancement of a carbon sequestration process and method for calculating the quantity of atmospheric carbon sequestration manifested by enhanced oceanic photosynthetic productivity through the process of Iron fertilization. This method and process comprises (1) defining a project boundary, (2) obtaining certain baseline measurements, metrics and observations within and beyond the project boundary, (3) applying an Iron compound within the project boundary to enhance photosynthesis, (4) obtaining certain measurements, metrics and observations within and adjacent to the project boundary prior to and after the introduction of Iron compound and last, (5) applying a method based on the measurements from steps 2 and 4 to determine the net quantity of atmospheric carbon that is sequestered.
