Nuevos dispositivos y criterios de análisis de señales de resonancia magnética para la caracterización humedad/porosidad de suelos y acuíferos superficiales

Un estudio geofísico mediante resonancia se realiza mediante la excitación del agua del subsuelo a partir de la emisión de una intensidad variable a lo largo de un cable extendido sobre la superficie en forma cuadrada o circular. El volumen investigado depende del tamaño de dicho cable, lo cual, junto con la intensidad utilizada para la excitación del agua determina las diferentes profundidades del terreno de las que se va a extraer información, que se encuentran entre 10 y 100 m, habitualmente. La tesis doctoral presentada consiste en la adaptación del Método de Resonancia Magnética para su utilización en aplicaciones superficiales mediante bucles de tamaño reducido. Dicha información sobre el terreno en la escala desde decímetros a pocos metros es interesante en relación a la física de suelos y en general en relación a diferentes problemas de Ingeniería, tanto de extracción de agua como constructiva. Una vez realizada la revisión del estado de conocimiento actual del método en relación a sus aplicaciones usuales, se estudian los problemas inherentes a su adaptación a medidas superficiales. Para solventar dichos problemas se han considerado dos líneas de investigación principales: En primer lugar se realiza un estudio de la influencia de las características del pulso de excitación emitido por el equipo en la calidad de las medidas obtenidas, y las posibles estrategias para mejorar dicho pulso. El pulso de excitación es un parámetro clave en la extracción de información sobre diferentes profundidades del terreno. Por otro lado se busca la optimización del dispositivo de medida para su adaptación al estudio de los primeros metros del suelo mediante el equipo disponible, tratándose éste del equipo NumisLITE de la casa Iris Instruments. ABSTRACT Magnetic Resonance Sounding is a geophysical method performed through the excitation of the subsurface water by a variable electrical intensity delivered through a wire extended on the surface, forming a circle or a square. The investigated volume depends on the wire length and the intensity used, determining the different subsurface depths reached. In the usual application of the method, this depth ranges between 10 and 100 m. This thesis studies the adaptation of the above method to more superficial applications using smaller wire loops. Information about the subsurface in the range of decimeter to a few meters is interesting regarding physics of soils, as well as different Engineering problems, either for water extraction or for construction. After a review of the nowadays state of the art of the method regarding its usual applications, the special issues attached to its use to perform very shallow measures are studied. In order to sort out these problems two main research lines are considered: On the one hand, a study about the influence of the characteristics of the emitted pulse in the resulting measure quality is performed. Possible strategies in order to improve this pulse are investigated, as the excitation pulse is a key parameter to obtain information from different depths of the subsurface. On the other hand, the study tries to optimize the measurement device to its adaptation to the study of the first meters of the ground with the available instrumentation, the NumisLITE equipment from Iris Instruments.

Use of DFOT Heat Pulse Method ForWetting Pattern Determination in Drip Irrigation Emitters

Although there are numerous accurate measuring methods to determine soil moisture content in a spot, until very recently there were no precise in situ and in real time methods that were able to measure soil moisture content along a line. By means of the Distributed Fiber Optic Temperature Measurement method or DFOT, the temperature in 0.12 m intervals and long distances (up to 10,000 m) with a high time frequency and an accuracy of +0.2º C is determined. The principle of temperature measurement along a fiber optic cable is based on the thermal sensitivity of the relative intensities of backscattered photons that arise from collisions with electrons in the core of the glass fiber. A laser pulse, generated by the DTS unit, traversing a fiber optic cable will result in backscatter at two frequencies. The DTS quantifies the intensity of these backscattered photons and elapsed time between the pulse and the observed returned light. The intensity of one of the frequencies is strongly dependent on the temperature at the point where the scattering process occurred. The computed temperature is attributed to the position along the cable from which the light was reflected, computed from the time of travel for the light.