PONTIFICIA UNIVERSIDAD CATÓLICA DEL PERÚ ESCUELA DE POSGRADO  MEDICIONES DE LA CONCENTRACIÓN DE RADON 222  EN AMBIENTES INTERIORES EN LIMA – PERÚ  Artículo publicable para optar el título de Magister en Física que presenta:   PATRIZIA EDEL PEREYRA ANAYA Asesora: DRA. MARÍA ELENA LÓPEZ HERRERA Miembros del Jurado DR. EDUARDO MASSONI KAMIMOTO DR. HERNÁN CASTILLO EGOAVIL San Miguel, Agosto 2015 Resumen Ejecutivo Nombre del graduando: Patrizia Edel Pereyra Anaya Posgrado en: Física Título del artículo publicado: Concentration measurements of radon 222 indoors in Lima – Peru. Este artículo ha sido publicado en : International Journal of Physics, 2015, Vol. 3, No. 4, 165-169 DOI:10.12691/ijp-3-4-5 Concentration Measurements of Radon 222 Indoors in Lima – Peru P.Pereyra*, M.E. López, L. Vilcapoma Sección Física, Pontificia Universidad Católica del Perú, Lima – Perú Abstract The measurement of the levels of 222Rn was accomplished during autumn to spring season in 2014 at residences distributed throughout 30 districts of Lima Metropolitan Area, including the north, centre and south areas of the city. The houses where the measurements were achieved were selected considering several variables as type of construction, age, construction materials, coatings, soil type, occupational use of rooms monitored, etc. For all the measurements of 222Rn passive detectors was used (Solid State Nuclear Track Detectors SSNTDs) of cellulose nitrate (LR- 115). Procedure and data acquisition are described and results; this monitoring is the first realized in this city. The results are only indicating the presence of 222Rn, the detectors used do not allow to the discrimination of its descendants. Resumen Se realizó la medición de los niveles de Radón 222 en las estaciones de otoño y primavera del 2014 en residencias correspondientes a 30 distritos de Lima Metropolitana, incluyendo a las zonas Norte, Centro y Sur de la ciudad. Las casas en donde se realizaron las mediciones fueron seleccionadas considerando diversas variables como antigüedad, materiales de construcción, revestimientos, tipo de suelo, uso de las habitaciones monitoreadas, etc. Para las mediciones de Radón 222 se utilizaron detectores pasivos (Detectores de Estado Sólido de Huellas Nucleares) de nitrato de celulosa (LR – 115). En el trabajo se muestra el procedimiento de toma de datos, lectura de los dosímetros y los resultados de la medición, que es la primera que se realiza en esta ciudad. Los resultados solo indican la presencia de Rn 222, los detectores empleados no permiten discriminar la presencia de los descendientes del Radón 222. A María Pía, mi familia, profesores, amigos y todos los que de alguna forma me animaron a seguir tras mis huellas….. International Journal of Physics, 2015, Vol. 3, No. 4, 165-169 Available online at http://pubs.sciepub.com/ijp/3/4/5 © Science and Education Publishing DOI:10.12691/ijp-3-4-5 Concentration Measurements of Radon 222 Indoors in Lima – Peru P.Pereyra*, M.E. López, L. Vilcapoma Sección Física, Pontificia Universidad Católica del Perú, Lima – Perú *Corresponding author: ppereyr@pucp.edu.pe Received June 30, 2015; Revised July 14, 2015; Accepted July 17, 2015 Abstract The measurement of the levels of 222Rn was accomplished during autumn to spring season in 2014 at residences distributed throughout 30 districts of Lima Metropolitan Area, including the north, centre and south areas of the city. The houses where the measurements were achieved were selected considering several variables as type of construction, age, construction materials, coatings, soil type, occupational use of rooms monitored, etc. For all the measurements of 222Rn passive detectors was used (Solid State Nuclear Track Detectors SSNTDs) of cellulose nitrate (LR- 115). Procedure and data acquisition are described and results; this monitoring is the first realized in this city. The results are only indicating the presence of 222Rn, the detectors used do not allow to the discrimination of its descendants. Keywords: Monitoring of 222Rn, nuclear tracks detectors, cellulose nitrate Cite This Article: P.Pereyra, M.E. López, and L. Vilcapoma, “Concentration Measurements of Radon 222 Indoors in Lima – Peru.” International Journal of Physics, vol. 3, no. 4 (2015): 165-169. doi: 10.12691/ijp-3-4-5. 1. Introduction 222Rn Gas, natural radioisotope that presents imperceptibly in our senses is the main contributor to the natural radiation received by humans. 222Rn is an inert gas that emits alpha particles and has a relatively short average life (3.8 days). Radon proceeds from the decay of 226Ra. Radon gas emanates in small quantities from the soil and building materials. It incorporates to the air, usually in low concentrations; decays in his daughters (218Po, 214Po) but it can be risky in poorly ventilated or closed areas where it is susceptible to be inhaled by living beings. In ideal conditions it should not exceed 200Bq•m-3 [10]. Research works establish a close relationship between inhalation of significant concentrations of radon indoors and lung cancer. This risk increases in active smokers and even in passive smokers up to in a factor of 10. In this case, Radon is the most important factor about lung cancer incidence [11]. Although ground radon is the main source of this natural radioactivity contaminant indoors, it can sometimes come from well water or watershed. On the other hand, in certain types of houses, the building materials can also emit radon, increasing its presence, but rarely does this constitute the main cause of a high concentration. Radon can enter a house through cracks in the foundations, cracks in the walls, through the joints of the walls or internal cavities in the walls, through the spaces around the pipes, through water, etc. The main interest of this study is the measurement of radon concentration in different types of houses in the city of Lima, considering its geographical location and give suggestion if it is suitable. Nuclear tracks solid state detectors used in this 222Rn monitoring have been used in similar investigations; methodology and fundamentals of the technique are known [4]. 2. Rationale Lima, the capital of Peru, is a city with near 10 million inhabitants located on the west coast of South America, in front of the Pacific Ocean at 12° South Latitude and 77°3' West Longitude, it covers an area of 3900 km2. Lima is a flat city, rounded by some hills and mountains irrelevant. Geological outcrops correspond to intrusive, extrusive and lesser sedimentary rocks amount. It is located on the valleys of Rimac, Chillon and Lurin rivers. Presents mostly alluvial gravel soils and rocky outcrops; also it presents some areas of sandy soils (seismic micro zonation of Lima). The urban development of the city of Lima throughout its history has been increased in recent 40 years, in which its population has tripled. Mostly on the new city is over a desert terrain, but also comprises fertile areas. Due to excessive and disordered urban growth, the city extends in the so called north, south and west cones, growing on rocky, sandy terrains, slopes and hills of surrounding terrains. The province of Lima is divided into 43 districts, distributed for this study in 4 areas: North, East, Central and South. The aim of this research is to know concentration levels of 222Rn in some houses for begin to do a Radon map from Lima and to be a beginning to identify an eventual 166 International Journal of Physics sanitary risk to its inhabitants related about lung cancer and others. To conduct the measurements some houses of teachers, students and workers of Pontificia Universidad Católica del Perú (PUCP) were selected, who voluntarily collaborated to host detectors in their homes. Formerly mails were sent with concise information (scope of the project, reason of the measurements and how it would be done.) Those who answered affirmatively and were selected due to their geographic location were given additional information and guidelines for site selection of measurements in their houses and the commitment to place detectors properly. Volunteers themselves removed and placed detectors. 3. Materials and Methods To conduct measurements of 222Rn on the selected buildings we used passive detectors using the Nuclear Tracks technique (SSNTDs). The detectors are made of cellulose nitrate LR115 Type 2, 12 μm thickness, high sensitivity, capable of recording the passage of low energy alpha particles. These detectors are not affected by electrons or other type of electromagnetic radiation (gamma radiation, X-rays, etc.). They can be stored in standard conditions for periods of time that exceed one year. Naked passive detectors were used, of square shape, 20 mm by side, supported to a square bracket of 60 mm a side, taken from a transparency film, duly coded as shown in Figure 1. Figure 1. LR 115 detectors used in Radon 222 monitoring 3.1. Sampling Conditions Three sampling areas were taken in consideration in Lima: North, Central and South. The distribution of the number of districts and number of houses monitored are shown in Table 1 and in Figure 2. The total population of this districts is 7 252 455 inhabitants [12] it represents about 74.5 % from Lima population. Table 1. Dwellings monitoring Radon in Lima by zone. Zone Districts by zone Districts Number of dwellings by zone Central 13 Lima Cercado, San Borja, Miraflores, Magdalena, Pueblo Libre, San Miguel, Jesús María, Breña, Lince, La Victoria, Surco, Surquillo, San Isidro 50 South Cone 3 San Juan de Miraflores, Villa María del Triunfo, Chorrillos 11 North Cone 5 Independencia, Puente Piedra, San Martín de Porres, Los Olivos, Comas 18 East Cone 4 La Molina, El Agustino, Ate-Vitarte, San Juan de Lurigancho 18 Figure 2. Geographical location of LR 115 detectors used in 222Rn monitorin The detectors were coded according to the area, and then the district selected, houses of that district A, B or C and finally the detector number (from 1 to 6). In total 396 detectors were processed. Sampling was given in periods from 7 to 8 weeks during autumn and winter in 2014. During this period 2 detectors were placed per house, this is to say that six detectors were recorded in total for each sampling site. Indications were given to consider placing the detector at the less ventilated area of the house (bedroom, bathroom, basement, garage ....) Participants filled out a form where the characteristics of the building and lining the walls of the room and the floor were indicated, as well as the average time spent by the family in the rooms studied. Other data recorded were the age of the house, building materials and if the people who lived there were smokers or other relevant data. 3.2. Etching and Reading Process Etching was made under standard conditions in a thermostated bath using NaOH solution. It was shown in Figure 3a. For the reading an optical microscope was used (Figure 3b), counting four fields per detector to determine the average reading. It can be used the usual procedure for these detectors [3,9]. After that, the density of traces per mm2 was determined using the calibration factor corresponding [7]. International Journal of Physics 167 Figure 3. (a) Etching process (b) Reading process 4. Results Results are shown by zones and districts in the following tables. The North zone is in Table 2; the east zone is in Table 3; the south zone is in Table 4 and the center zone is in Table 5. The measurements above 500 Bq/m3 of Rn 222 concentration are highlighted. Some detectors were loses and the time of monitoring each of them could be inexact. Detectors were placed in basements or closed rooms, without ventilation and non- habited. North Zone Monitoring was made in 5 of 8 districts of north zone, with more population and area. The population in this area is about 2 129 075 inhabitants [12]. It represents near 86% population in north zone. Results are shown in Table 2. Table 2. Monitoring results of 222Rn in the Northern Area of Lima City District D w el lin gs m on ito rin g M in im um v al ue B q/ m 3 M ax im um v al ue B q/ m 3 M ea n va lu e B q/ m 3 Pe rc en t d w el lin gs le ss ta n 20 0B q/ m 3 Pe rc en t d w el lin gs le ss th an 4 00 Bq /m 3 Pe rc en t d w el lin gs u p to 4 00 Bq /m 3 Puente Piedra 1 562 0 0 100 San Martín de Porres 8 20 632 205 62.5 25 12.5 Los Olivos 4 48 162 108 100 0 0 Comas 3 122 141 129 100 0 0 Independencia 2 64 97 81 100 0 0 East Zone Measurements were made in 5 of the 8 districts in this zone; the districts with more population and area were selected. In the selected districts live 2 101 866 inhabitants [12], it represents near 81% population in the east zone. Results are shown in Table 3. Table 3. Monitoring results of 222Rn in the Eastern Area of Lima City District D w el lin gs m on ito rin g M in im um v al ue B q/ m 3 M ax im um v al ue B q/ m 3 M ea n va lu e B q/ m 3 Pe rc en t d w el lin gs le ss ta n 20 0B q/ m 3 Pe rc en t d w el lin gs le ss th an 4 00 Bq /m 3 Pe rc en t d w el lin gs u p to 4 00 Bq /m 3 Ate 2 9.48 257 133 50 50 0 Chacla cayo 2 214 251 232 0 100 0 El agustino 1 1 272 0 100 0 San juan de Lurigancho 10 81 432 173 70 0 30 La Molina 3 22 180 96 100 0 0 South Zone Measurements were made in 5 of the 7 districts in this zone, with most demographic density. In this selected districts live 1 618 049 inhabitants [12], it represents near 71% population in the east zone. Results are shown in Table 4. Table 4. Monitoring results of 222Rn in the Southern Area of Lima City District D w el lin gs m on ito rin g M in im um V al ue B q/ m 3 M ax im um v al ue B q/ m 3 M ea n va lu e B q/ m 3 Pe rc en t d w el lin gs le ss ta n 20 0B q/ m 3 Pe rc en t d w el lin gs le ss th an 4 00 Bq /m 3 Pe rc en t d w el lin gs u p to 4 00 Bq /m 3 Chorri llos 2 17 75 46 100 0 0 San Juan de Mira flores 5 23 387 219 20 80 0 Villa el Salvador 1 173 100 0 0 Villa María del triunfo 3 18 319 214 33 66 0 Centre Zone Measurements were made in 12 of the 16 districts in this zone; the districts with more population and area were selected. In the selected districts live 1 543 180 inhabitants [12], it represents near 83% population in the east zone. Results are shown in Table 5. Table 5. Monitoring results of 222Rn in the Central Area of Lima City District D w el lin gs m on ito rin g M in im um V al ue B q/ m 3 M ax im um v al ue B q/ m 3 M ea n va lu e B q/ m 3 Pe rc en t d w el lin gs le ss ta n 20 0B q/ m 3 Pe rc en t d w el lin gs le ss th an 4 00 Bq /m 3 Pe rc en t d w el lin gs u p to 4 00 Bq /m 3 Breña 2 156 348 252 50 50 Jesús María 3 70 136 112 100 Lince 2 129 269 199 50 50 Magdalena del Mar 4 90 305 181 40 60 Miraflo res 5 57 942 312 40 40 20 Pueblo Libre 6 118 268 185 67 33 San Borja 4 0 658 221 75 0 25 San Miguel 11 20 480 178 64 27 9 La Victoria 2 109 129 119 100 0 0 Lima Cercado 7 61 604 246 42 29 29 Surco 2 109 285 197 50 50 0 Surqui llo 1 584 0 0 100 168 International Journal of Physics Summarizing results by zone are shown as follow Mean ( Bq/m 3 ) North 177 East 168 South 182 Central 205 Districts were shown now in relation with the concentration level measures obtained. It is noted that detectors with higher concentration was located in central zone. In this zone the dwellings are older (overall in Lima Cercado). San Juan de Miraflores and Villa el Salvador are the highest means at south zone; they are located in granular and sedimentary soils. Most of them who present low levels of Radon are located in rocky soils. In the case of Puente Piedra and Surquillo only one dwelling has been monitoring, so the result are not representative. A tentative radon map is shown in Figure 4. Level concentration mean of 222Rn by zone are shown in Figure 5 for each district. Districts with only one dwelling were not considered [8]. Figure 4. Districts of Lima and concentration of 222Rn registered Figure 5. Concentration levels of 222Rn in Bq/m3 – Average values by district in Lima 5. Conclusions The first approach in environmental monitoring of Radon 222 in the city of Lima has been accomplished. Reports of similar investigations employing SSNTDs in other cities have similar results [1,5,6]. In general most detectors recorded values corresponding to concentrations below 200 Bq/m3; when registering high values, it may indicate a correlation between the age of the house and the level of 222Rn; these levels are increased in basements considerably, and are just 3 of the 4 cases with a higher concentration of 222Rn measured. It can also be understood that in the case of basements, water pipes increase radon levels with poor ventilation, a key factor in the diffusion of radon. Variables such as building materials and floor and wall coverings require further analysis and data number. In general the methodology is consistent and concentration gives similar results to other methods in similar geographic locations. Acknowledgment The authors thank the members of the Pontificia Universidad Católica del Perú community: Heads, teachers in Physics and Industrial Engineering, administrative staff, undergraduate students in physics and General Studies (Science and Letter) who cooperated willingly and hosted the detectors in their homes. References [1] Canoba, A., López, F.O., Arnaud, M.I., Oliveira, A.A., Neman, R.S., Hadler, J.C., Iune, P.J., Paulo, S.R., Osorio, A.M., Aparecido, R., Rodríguez, C., Moreno, V., Vásquez, R., Espinosa, G., Golzarri, J.I., Martínez, T., Navarrete, M., Cabrera, I., Segovia, N., Peña, P., Taméz, E., Pereyra, P., López-Herrera, M.E., Sajo-Bohus, L., “Indoor radon measurements in six Latin American countries”, Geofísica Internacional (2002), Vol. 41, Num. 4, pp. 453-457 (2002). [2] Espinosa, G., Trazas Nucleares en Sólidos, UNAM, México, ISBN: 968-36- 4219-5 (2002). 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