In Costa Rica, using isotopic techniques scientists have found that applying fertilizer on the leaves of pineapple plants is much more efficient than spreading it on the soil.
José Luis Hernández, from Costa Rica’s Ministerio de Agricultura y Ganadería (MAG) – Ministry of Agriculture and Livestock, said farmers have changed their farm practices since they learned the new tactic. ‘Small, medium and large pineapple producers have learnt their lesson,’ he said. ‘Applying fertilizer through the leaves means more work, but at the same time saves money. This tactic has largely improved crop management.’
Soil is a mixture of minerals, organic matter, gases and water. Carbon is a key ingredient of soil and its health, but, in a gaseous form as CO, it is a GHG. Plants capture carbon in the form of carbon dioxide (CO) from the air, transforming it into organic matter and thereby transferring it into soil, which boosts soil productivity and resilience to harsh climate conditions.
The idea of soil capturing and storing atmospheric CO, also known as carbon sequestration, can counterbalance the increase of GHGs. Analysing carbon isotopes allows researchers to evaluate soil quality and sources of carbon sequestered in the soil. By measuring carbon sequestration, they can identify if biochar is enhancing soil fertility and helping reduce COemissions.
Similarly, using fertilizers in defined plots labelled with the nitrogen-15 stable isotope (N) scientists can track the amount of nitrogen taken by plants or lost to the atmosphere as GHG or to surface and groundwater and can determine how effectively the crops are taking up the fertilizer. This helps them optimize fertilizer use on farms.
“Most producers apply more fertilizers and pesticides than pineapples need, and a large part of these are lost to the atmosphere as greenhouse gases or pollute rivers and groundwater,” said Cristina Chinchilla, agronomy scientist at the University of Costa Rica’s Environmental Pollution Research Center (CICA).