MARCACCIO_corretto_Layout 6 811 Effects on the groundwater levels of the May-June 2012 Emilia seismic sequence Marco Marcaccio1, Giovanni Martinelli2,* 1 Agenzia Regionale Prevenzione e Ambiente (ARPA) dell'Emilia-Romagna, Direzione Tecnica, Bologna, Italy 2 Agenzia Regionale Prevenzione e Ambiente (ARPA) dell'Emilia-Romagna, Sezione di Reggio Emilia, Reggio Emilia, Italy ANNALS OF GEOPHYSICS, 55, 4, 2012; doi: 10.4401/ag-6139 1. Introduction A variety of phenomena were observed in the ground- waters in concomitance with the May-June 2012 seismic se- quence that occurred in the Emilia Romagna area. In particular, phreatic wells close to the epicentral area were af- fected by a sudden increase in water level of up to 4 m. In some cases, the sands of aquifers were ejected outside wells, and >700 liquefaction phenomena were recorded [Bertolini and Fioroni 2012, this volume]. Some automatic stations of the regional well network recorded variations in well levels. These data can be considered useful to understand the rela- tionships between seismic events and the local groundwaters [see also Italiano et al. 2012, this volume]. 2. Hydrogeological features The Po sedimentary basin is filled by sediments of Alpine and Apennine origin [Ori 1993]. The sedimentation processes have filled the sedimentary basin with alternate lay- ers of sands and clay [Ori 1993, and references therein]. Grav- els are present near the Apenninic chain front in the alluvial fan areas, while the bottom of the Quaternary sediments is at depths of 100 m to 700 m. These multilayered sequences constitute the Po aquifer system [Regione Emilia-Romagna and ENI-AGIP 1998]. In the part of the basin close to the Apenninic chain front (the belt of alluvial fans), the aquifers are located in undersaturated sediments and are subject to seasonal variations in their recharging processes. North of this area, fine sediments host confined or semiconfined aquifers that are characterized by low circulation velocities. Isotopic data indicate that deep groundwaters in this area are of Alpine origin, while 3H and 14C data indicate ages of 15000 to 30000 years [Martinelli et al. 1998, and references therein]. At depths shallower than 50 m, load fluctuations are observed in connection with rainfall, although lenses of con- fined aquifers that are poorly sensitive to rainfall are known to be at shallow depths too. The May-June 2012 seismic se- quence occurred in the low plain area in the provinces of Modena and Ferrara, where fine sediments generate multi- layered confined aquifers, and phreatic aquifers are limited to the first 10 m to 30 m in depth. 3. The monitoring network In 1976, a regional network composed of 330 wells was set up with the purpose of monitoring the groundwater lev- els using manual techniques. These data have been used for environmental purposes and for water management. In re- cent years, the monitoring network managed by Agenzia Re- gionale Prevenzione e Ambiente (ARPA) has increased the number of wells (to about 600), and chemical analyses are also periodically carried out for environmental monitoring activities. In the past three years, an automatic monitoring network composed of 40 stations was set up and this has al- lowed the monitoring of the water levels and the tempera- tures, at a rate of one measure per hour, and to broadcast the data to the host center located in Bologna (Figure 1a). 4. Recorded data Most of the stations located in the whole of the Emilia- Romagna region did not record significant signals that are at- tributable to seismic events, while some stations located in the provinces of Modena and Ferrara (Figure 1b) recorded sudden water uprising phenomena, of up to 1.5 m (Figure 2). The internal clock of the monitoring stations was syn- chronized according to Coordinated Universal Time (UTC). In this way, the first measures after the M 5.9 and M 5.8 shocks were recorded about 1 h after these seismic events. Figure 2 shows that a decay of the water level signal was seen, and the higher water levels probably occurred in con- comitance with these seismic events, although they were not recorded here (Table 1). Figure 3 gives the water level variations observed at three selected monitoring stations of the Emilia-Romagna Article history Received July 23, 2012; accepted August 20, 2012. Subject classification: Groundwater processes, Groundwaters, Seismic effects, Water level, Hydrology. 2012 EMILIA EARTHQUAKES MARCACCIO AND MARTINELLI 812 Relevant seismic events (magnitude) Seismic events occurrence date Seismic events occurrence time (UTC) Pre-seismic recording time (UTC) Post-seismic recording time (UTC) 5.9 20/05/2012 02.03.52 02.00.00 03.00.00 5.8 29/05/2012 07.00.03 07.00.00 08.00.00 Figure 1. (a) Geographical sketch of the Emilia-Romagna region showing all of the groundwater automatic monitoring stations managed by ARPA Emilia-Romagna. (b) Monitoring stations considered and epicenters of the most relevant seismic events, as characterized by 5.1 ≤M ≤5.9 [INGV 2012]. Figure 2. Water-level changes in concomitance with some significant seismic events. The events characterized by 5.1 ≤M ≤5.9 were considered. Table 1. Occurrences of the two most relevant seismic events, with the pre and post recording times. 813 groundwater automatic monitoring network. In particular, for each station, two different water level variations were recorded in concomitance with most of the relevant seismic events, which were characterized by the M 5.9 (full dot) and M 5.8 (empty dot) seismic events. Water level variations were calculated according to values recorded at the UTC hours re- ported in Table 1. The M 5.9, May 20, 2012, seismic event occurred at a dis- tance of about 10 km to 14 km from the monitoring stations. The observed signal amplitude was relevant in all of the three monitoring stations considered. The M 5.8, May 29, 2012, seismic event occurred at a distance of about 10 km from the MO80-00 station, and at about 21 km to 23 km from the FE80-00 and FE81-00 stations. These distance differences might explain the higher effects recorded at the MO80-00 sta- tion (Figure 3). Most of the relevant groundwater variations that have occurred in concomitance with other earthquakes were de- scribed by Roeloffs [1996] and by Wang and Manga [2010], while previous investigations on earthquake-related piezo- metric variations in Italy were carried out by Albarello et al. [1991] and Albarello and Martinelli [1994]. In the Italian his- torical records, earthquakes related to piezometric variations were reported by Boschi et al. [1995] and by Martinelli [1997]. As a general rule, possible water-level anomalies can be pos- itive or negative according to the well location. If the area is subjected to compressive strain, the expected anomaly is pos- itive [Okada 1992]. The sizes of the recorded anomalies can be tentatively related to the aquifer characteristics, to the dis- tances of the recording station from the hypocentral area, and to the locations of the monitored aquifers in areas prob- ably subjected to compressive strain. The step-like signals ob- served indicate that all of the monitoring stations in the near-field area, in which undrained consolidation is the dom- inant mechanism for coseismic groundwater level changes [Wang and Manga 2010], were affected by significant water- level variations. 5. Conclusions The observed anomalies are within the characteristics previously reported in the common scientific literature re- lating to undrained consolidation phenomena linked to earthquake occurrence. Their sizes and shapes are probably a function of their relatively small distances from the hypocentral area and to their location in an area subjected to compressive strain. The collection and processing of all of the available data on piezometric variations during the Emilia 2012 seismic sequence will allow a better under- standing of the phenomena observed. Acknowledgements. Thanks are due to Michele Di Lorenzo for quick data recovery from hosting centers. Thanks are also due to Francesco Salvini and to an unknown Reviewer, for their kind suggests which contributed to the improving of the text. References Albarello, D., G. Ferrari, G. Martinelli and M. Mucciarelli (1991). Well-water variations as a seismic precursor: a sta- tistical assessment from Italian historical data, Tectono- physics, 193, 385-395. Albarello, D., and G. Martinelli (1994). Piezometric levels as possible geodynamic indicators: analysis of the data from a regional deep waters monitoring network in northern Italy, Geophys. Res. Lett., 21, 1955-1958. Bertolini, G., and C. Fioroni (2012). Aerial inventory of surfi- cial geological effects induced by the recent Emilia earth- quake: preliminary report, Annals of Geophysics, 55 (4); THE EFFECTS OF SHOCKS ON GROUNDWATERS Figure 3. Differences in the water levels at the three monitoring stations, as related to the distance in concomitance with the two relevant seismic events characterized by M 5.9 (full dot) and M 5.8 (empty dot). doi:10.4401/ag-6113. Boschi, E., G. Ferrari, P. Gasperini, E. Guidoboni, G. Smriglio and G. Valensise (1995). Catalogo dei forti terremoti in Italia dal 461 a.C. al 1980, Istituto Nazionale di Geofisica, Storia Geofisica Ambiente, Bologna, 973 pp. INGV (2012): http://cnt.rm.ingv.it Italiano, F., M. Liotta, M. Martelli, G. Martinelli, R. Petrini, A. Riggio, A. Rizzo, F. Slejiko and B. Stenni (2012). Geo- chemical features and effects on deep-seated fluids during the May-June 2012 southern Po Valley seismic sequence, Annals of Geophysics, 55 (4); doi:10.4401/ag-6151. Martinelli, G. (1997). Non seismometrical precursors obser- vations in Europe: steps of earthquake prediction re- search, In: G. Ferrari (ed.), Historical Seismic Instruments and Documents: a Heritage of Great Scientific and Cul- tural Value, Cahiers du Centre Européen de Geody- namique et de Séismologie, 13, 195-216. Martinelli, G., A. Minissale and C. Verrucchi (1998). Geo- chemistry of heavily exploited aquifers in the Emilia-Ro- magna region (Po valley, northern Italy), Environ. Geol., 36, 195-206. Okada, Y. (1992). Internal deformation due to shear and ten- sile faults in a half-space, B. Seismol. Soc. Am., 52, 81-86. Ori, G.G. (1993). Continental depositional systems of the Quaternary of the Po Plain (northern Italy), Sediment. Geol., 83, 1-14. Regione Emilia-Romagna and ENI-AGIP (1998) Riserve idriche sotterranee della Regione Emilia-Romagna, S.EL.CA., Firenze, 119 pp. Roeloffs, E. (1996). Earthquake-related hydrologic phenom- ena, Adv. Geophys., 37, 135-195. Wang, C-Y. and Manga M. (2010) Earthquakes and Water, Springer, Heidelberg, 225 pp. *Corresponding author: Giovanni Martinelli, Agenzia Regionale Prevenzione e Ambiente (ARPA) dell'Emilia-Romagna, Sezione di Reggio Emilia, Italy; email: giovannimartinelli@arpa.emr.it. © 2012 by the Istituto Nazionale di Geofisica e Vulcanologia. All rights reserved. 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