Preferential flow of water in the soil by applying Darcy-Buckingham\'s equation and the soil water balance

The understanding of the processes involving soil water movement is essential to soil and water management and conservation. There are situations in which the water moves faster in the soil profile through channels, during an event of intense rain, without interacting with soil matrix; this movement is known as preferential flow. Currently, it is accepted in field studies the existence of preferential flow in a wide range of soils. Nevertheless, many methods used to directly determine it change the water flow through the soil matrix, a drainage process of unquestionable relevance in soils. In a recent study carried out in Japan, this problem has been successfully overcome by simultaneously applying Darcy-Buckingham\'s equation and the soil water balance method during and shortly after rain events; the Darcy-Buckingham\'s equation infers on the presence of preferential water flow, defined in this approach as the residue of the soil water balance equation during the rain events. Therefore, this method has the great advantage of making possible the experimental determination of the preferential flow at a certain depth in soil, in field conditions, without significantly interrupting matric water flow. This study aimed to determine and characterize preferential water flow in depths corresponding to textural and latosolic B horizons of a Eutrophic Red Nitosol in field conditions, applying Darcy-Buckingham\'s equation and the soil water balance method, during and shortly after rain events. Due to the low volume of rain in the last rainy season, a significant change in soil moisture below 0.5 m was only observed in two situations, where preferential flow in Bt horizon was also verified. Preferential flow was not verified in the Bw horizon during the analyzed rain events. The methodology used was efficient in the observation of soil water flows not influenced by the soil matrix. (AU)