Extensive surface geophysical prospecting for seismic microzonation
Author(s)
Language
English
Obiettivo Specifico
5T. Sismologia, geofisica e geologia per l'ingegneria sismica
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Issue/vol(year)
/18 (2020)
ISSN
1570-761X
Publisher
Springer
Pages (printed)
5475–5502
Date Issued
May 27, 2020
Subjects
Seismic Microzonation
Abstract
This paper presents an overview of the geophysical activities for the seismic microzonation of 138 municipalities belonging to four Italian regions (Abruzzo, Lazio, Marche and Umbria) that were severely damaged by the seismic sequence of Central Italy (August 2016–January 2017). This study is the result of a collaborative effort between research Institutions and professional geologists with the support of local Administrations and the Italian Civil Protection Department and sets an unprecedented large-scale example of geophysical investigations supporting detailed seismic microzonation studies. This manuscript presents the methodological approach adopted for the geophysical activities, including the technical protocols and procedures, the best practices, the final products and the results supporting a detailed microzonation study of III level. The first step of the study was the collection and critical review of all available geophysical and geological information for planning the new geophysical surveys (specifically their type and location), in order to assess the subsoil geometry and the seismic characterization of the areas under investigation. Integration with the newly acquired geophysical data allowed the identification of zones with homogeneous local seismic hazard as well as the reference seismo-stratigraphy for each area, defining for each geological unit the ranges of the relevant properties in seismic amplification studies: layering and thicknesses, density, P-wave and S-wave seismic velocity. We also present a few representative case studies illustrating the geophysical investigation for different geomorphological situations. These examples, together with the findings of the entire project, are discussed to point out the strength points and the criticalities, as well as the necessary requirements in the application of geophysical methods to detailed microzonation studies.
References
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Albarello D, Francescone M, Lunedei E, Paolucci E, Papasidero MP, Peruzzi G, Pieruccini P (2016) Seismic characterization and reconstruction of reference ground motion at accelerometric sites of the Italian national accelerometric network (RAN). Nat Hazards 86(2):401–416. https://doi.org/10.1007/s11069-016-2310-4
Amanti M, Muraro C, Roma M, Chiessi V, Puzzilli L, Catalano S, Romagnoli G, Tortorici G, Cavuoto G, Albarello D, Fantozzi PL, Paolucci E, Pieruccini P, Caprari P, Mirabella F, Della Seta M, Esposito C, Di Curzio D, Francescone M, Pizzi A, Macerola L, Nocentini M, Tallini M (2020) Geological and geotechnical models definition for 3rd level seismic microzonation studies in Central Italy. This Issue
Bongiovanni G, Martini G, Martino S, Paciello A, Verrubbi V (2000) Studio geologico-geomeccanico dell’area di Cerreto di Spoleto (PG) finalizzato alla microzonazione sismica. Rapporto tecnico ENEA, RT/AMB/2000/14-2000
Bongiovanni G, Martino S, Paciello A, Verrubbi V (2001) Indagini geotecniche e geofisiche finalizzate alla microzonazione sismica dell’area di Cerreto di Spoleto (PG). Rapporto tecnico ENEA, RT/AMB/2001/22-2001
Chiaraluce L, Di Stefano R, Tinti E, Scognamiglio L, Michele M, Casarotti E, Cattaneo M, De Gori P, Chiarabba C, Monachesi G, Lombardi A, Valoroso L, Latorre D, Marzorati S (2017) The 2016 Central Italy seismic sequence: a first look at the mainshocks, aftershocks, and source models. Seismol Res Lett 88(3):757–771. https://doi.org/10.1785/0220160221
Cultrera G, Cardinali M, de Franco R, Gallipoli MR, Pacor F, Pergalani F, Milana G, Moscatelli M, and the Amatrice working group Team (2017) Site effects in the Amatrice municipality through dense seismic network and detailed geological-geophysical survey. In: 19th EGU General Assembly, EGU2017, proceedings from the conference held 23–28 April, 2017 in Vienna, Austria. p 13691
Dal Moro G (2008) VS and VP vertical profiling via joint inversion of Rayleigh waves and refraction travel times by means of bi-objective evolutionary algorithm. J Appl Geophys 66:15–24
Foti S, Parolai S, Albarello D, Picozzi M (2011) Application of surface–wave methods for seismic site characterization. Surv Geophys 32(6):777–825
Foti S, Hollender S, Garofalo F, Albarello D, Asten M, Bard PY, Comina C, Cornou C, Cox B, Di Giulio G, Forbriger T, Hayashi K, Lunedei E, Martin A, Mercerat D, Ohrnberger M, Poggi V, Renalier F, Sicilia D, Socco LV (2017) Guidelines for the good practice of surface wave analysis: a product of the InterPACIFIC project. Bull Earthq Eng. https://doi.org/10.1007/s10518-017-0206-7
García-Jerez A, Luzón F, Sánchez-Sesma FJ, Lunedei E, Albarello D, Santoyo MA, Almendros J (2013) Diffuse elastic wavefield within a simple crustal model. Some consequences for low and high frequencies. J Geophys Res 118(10):5577–5595
García-Jerez A, Piña-Flores J, Sánchez-Sesma FJ, Luzón F, Perton M (2016) A computer code for forward calculation and inversion of the H/V spectral ratio under the diffuse field assumption. Comput Geosci 97:67–78
Geopsy.org. GEOPSY software documentation. https://www.geopsy.org/wiki/index.php/Welcome_to_GeopsyWiki
Gruppo di lavoro (2006) Microzonazione sismica di Norcia. 1° stralcio. Relazione del Gruppo di lavoro. Regione Umbria, GR-DRATI, p 222
Konno K, Ohmachi T (1998) Ground motion characteristics estimated from spectral ratio between horizontal and vertical components of microtremor. BSSA 88(1):228–241
ICMS (2008) Indirizzi e criteri per la microzonazione sismica. Conferenza delle Regioni e delle Province autonome—Dipartimento della Protezione Civile, Roma, Italy, vol 3 and Dvd
Imposa S, Panzera F, Grassi S, Lombardo G, Catalano S, Romagnoli G, Tortorici G (2017) Geophysical and geological survey of the area struck by the August 20th 2016 Central Italy earthquake: the study case of Pretare and Piedilama. J Appl Geophys 145:17–27
Louie JN (2001) Faster, better: shear-wave velocity to 100 meters depth from refraction microtremor arrays. Bull Seismol Soc Am 91:347–364
Luzi L, D’Amico M, Massa M, Puglia R (2018) Site effects observed in the Norcia intermountain basin (Central Italy) exploiting a 20-year monitoring. Bull Earthq Eng. https://doi.org/10.1007/s10518-018-0444-3
Nakamura Y (1989) A method for dynamic characteristics estimation of subsurface using microtremor on the ground surface. QR Railway Tech Res Inst 30:25–33
Google Scholar
Nakamura Y (2000) Clear identification of fundamental idea of Nakamura’s technique and its applications. In: Proceedings of 12th world conference on earthquake engineering, New Zealand
Nogoshi M, Igarashi T (1970) On the propagation characteristics of microtremors. J Seism Soc Japan 23:264–280 (in Japanese with English abstract)
Google Scholar
NTC18 (2018) Norme tecniche per le costruzioni. G.U. n. 42 del 20 febbraio 2018
Ohori M, Nobata A, Wakamatsu K (2002) A comparison of ESAC and FK methods of estimating phase velocity using arbitrarily shaped microtremor arrays. Bull Seismol Soc Am 92:2323–2332
Pagliaroli A, Pergalani F, Ciancimino A, Chiaradonna A, Compagnoni M, De Silva F, Foti S, Giallini S, Lanzo G, Lombardi F, Luzi L, Macerola L, Nocentini M, Pizzi A, Tallini M, Teramo C (2019) Site response analyses for complex geological and morphological conditions: relevant case-histories from 3rd level seismic microzonation in Central Italy. Bull Earthq Eng. https://doi.org/10.1007/s10518-019-00610-7
Park CB, Miller RD, Xia J (1999) Multichannel analysis of surface waves. Geophysics 64:800–808
Parolai S, Picozzi M, Richwalski SM, Milkereit C (2005) Joint inversion of phase velocity dispersion and H/V ratio curves from seismic noise recordings using a genetic algorithm considering higher modes. Geophys Res Lett 32:L01303
Pergalani F, Pagliaroli A, Bourdeau C, Compagnoni M, Lenti L, Lualdi M, Madiai C, Martino S, Razzano R, Varone C, Verrubbi V (2019) Seismic microzoning map: approaches, results and applications after the 2016–2017 Central Italy seismic sequence. Bull Earthq Eng. Special Issue on “Seismic Microzonation of Central Italy”. https://doi.org/10.1007/s10518-019-00610-7
Piatti C, Socco L, Boiero D, Foti S (2013) Constrained 1D joint inversion of seismic surface waves and P-refraction traveltimes. Geophys Prospect 61:77–93. https://doi.org/10.1111/j.1365-2478.2012.01071.x
Picozzi M, Parolai S, Albarello D (2005) Statistical analysis of horizontal to vertical spectral ratios (HVSR). Bull Seism Soc Am 95(5):1779–1786. https://doi.org/10.1785/0120040152
Picozzi M, Albarello D (2007) Combining Genetic and Linearized algorithms for a two-step joint inversion of Rayleigh wave dispersion and H/V spectral ratio curves. Geophys J Int 169:189–200
Piña-Flores J, Perton M, García-Jerez A, Carmona E, Luzón F, Molina-Villegas JC, Sánchez-Sesma FJ (2017) The inversion of spectral ratio H/V in a layered system using the diffuse field assumption (DFA). Geophys J Int 208:577–588
Priolo E, Pacor F, Spallarossa D, Milana G, Laurenzano G, Romano MA, Felicetta C, Hailemikael S, Cara F, Di Giulio G, Ferretti G, Barnaba C, Lanzano G, Luzi L, D’Amico M, Puglia R, Scafidi D, Barani S, De Ferrari R, Cultrera G (2019) Seismological analyses of the seismic microzonation of 138 municipalities damaged by the 2016–2017 seismic sequence in Central Italy. Bull Earthq Eng. https://doi.org/10.1007/s10518-019-00652-x
Sánchez-Sesma FJ, Rodríguez M, Iturrarán-Viveros U, Luzón F, Campillo M, Margerin L, García-Jerez A, Suarez M, Santoyo MA, Rodríguez-Castellanos A (2011) A theory for microtremor H/V spectral ratio: application for a layered medium. Geophys J Int 186:221–225
SARA electronic instruments (2012) DoReMI Manuale d’Uso. SARA electronic instruments s.r.l. Perugia—Italy. https://www.sara.pg.it/SOFTWARE/DOREMI/DoReMi_ITA_SoftwareSection.pdf
SARA electronic instruments (2017) GEOEXPLORER HVSR Versione 2.2.3 MANUALE 'USO. SARA electronic instruments s.r.l. Perugia–Italy. https://www.sara.pg.it/SOFTWARE/GEOEXPLORERHVSR/GEOEXPLORERHVSR_IT.pdf
Servizio geologico d’Italia (2011) Note Illustrative della Carta geologica d’Italia alla scala 1:50.000 fogli 336 “Spoleto”, 324 “Foligno”. ISPRA
SESAME, WP12 (2004) Guidelines for the implementation of the H/V spectral ratio technique on ambient vibrations-Measurements, processing and interpretation. SESAME European research project, Deliverable D23. 12., Project No. EVG1-CT-2000-00026 SESAME
Tertulliani A, Azzaro (a cura di) R (2017) QUEST—Rilievo macrosismico in EMS98 per la sequenza sismica in Italia Centrale: aggiornamento dopo il 18 gennaio 2017. Rapporto interno INGV. https://doi.org/10.5281/zenodo.556929
Vuan A, Romanelli M, Barnaba C, Restivo A, Lovisa L, Priolo E, Rossi G (2007) Relazione scientifica finale. Convenzione tra Comune di Spoleto e OGS per lo studio di microzonazione del centro storico della Città di Spoleto. Rel. OGS 2007/53-CRS/12
Albarello D, Francescone M, Lunedei E, Paolucci E, Papasidero MP, Peruzzi G, Pieruccini P (2016) Seismic characterization and reconstruction of reference ground motion at accelerometric sites of the Italian national accelerometric network (RAN). Nat Hazards 86(2):401–416. https://doi.org/10.1007/s11069-016-2310-4
Amanti M, Muraro C, Roma M, Chiessi V, Puzzilli L, Catalano S, Romagnoli G, Tortorici G, Cavuoto G, Albarello D, Fantozzi PL, Paolucci E, Pieruccini P, Caprari P, Mirabella F, Della Seta M, Esposito C, Di Curzio D, Francescone M, Pizzi A, Macerola L, Nocentini M, Tallini M (2020) Geological and geotechnical models definition for 3rd level seismic microzonation studies in Central Italy. This Issue
Bongiovanni G, Martini G, Martino S, Paciello A, Verrubbi V (2000) Studio geologico-geomeccanico dell’area di Cerreto di Spoleto (PG) finalizzato alla microzonazione sismica. Rapporto tecnico ENEA, RT/AMB/2000/14-2000
Bongiovanni G, Martino S, Paciello A, Verrubbi V (2001) Indagini geotecniche e geofisiche finalizzate alla microzonazione sismica dell’area di Cerreto di Spoleto (PG). Rapporto tecnico ENEA, RT/AMB/2001/22-2001
Chiaraluce L, Di Stefano R, Tinti E, Scognamiglio L, Michele M, Casarotti E, Cattaneo M, De Gori P, Chiarabba C, Monachesi G, Lombardi A, Valoroso L, Latorre D, Marzorati S (2017) The 2016 Central Italy seismic sequence: a first look at the mainshocks, aftershocks, and source models. Seismol Res Lett 88(3):757–771. https://doi.org/10.1785/0220160221
Cultrera G, Cardinali M, de Franco R, Gallipoli MR, Pacor F, Pergalani F, Milana G, Moscatelli M, and the Amatrice working group Team (2017) Site effects in the Amatrice municipality through dense seismic network and detailed geological-geophysical survey. In: 19th EGU General Assembly, EGU2017, proceedings from the conference held 23–28 April, 2017 in Vienna, Austria. p 13691
Dal Moro G (2008) VS and VP vertical profiling via joint inversion of Rayleigh waves and refraction travel times by means of bi-objective evolutionary algorithm. J Appl Geophys 66:15–24
Foti S, Parolai S, Albarello D, Picozzi M (2011) Application of surface–wave methods for seismic site characterization. Surv Geophys 32(6):777–825
Foti S, Hollender S, Garofalo F, Albarello D, Asten M, Bard PY, Comina C, Cornou C, Cox B, Di Giulio G, Forbriger T, Hayashi K, Lunedei E, Martin A, Mercerat D, Ohrnberger M, Poggi V, Renalier F, Sicilia D, Socco LV (2017) Guidelines for the good practice of surface wave analysis: a product of the InterPACIFIC project. Bull Earthq Eng. https://doi.org/10.1007/s10518-017-0206-7
García-Jerez A, Luzón F, Sánchez-Sesma FJ, Lunedei E, Albarello D, Santoyo MA, Almendros J (2013) Diffuse elastic wavefield within a simple crustal model. Some consequences for low and high frequencies. J Geophys Res 118(10):5577–5595
García-Jerez A, Piña-Flores J, Sánchez-Sesma FJ, Luzón F, Perton M (2016) A computer code for forward calculation and inversion of the H/V spectral ratio under the diffuse field assumption. Comput Geosci 97:67–78
Geopsy.org. GEOPSY software documentation. https://www.geopsy.org/wiki/index.php/Welcome_to_GeopsyWiki
Gruppo di lavoro (2006) Microzonazione sismica di Norcia. 1° stralcio. Relazione del Gruppo di lavoro. Regione Umbria, GR-DRATI, p 222
Konno K, Ohmachi T (1998) Ground motion characteristics estimated from spectral ratio between horizontal and vertical components of microtremor. BSSA 88(1):228–241
ICMS (2008) Indirizzi e criteri per la microzonazione sismica. Conferenza delle Regioni e delle Province autonome—Dipartimento della Protezione Civile, Roma, Italy, vol 3 and Dvd
Imposa S, Panzera F, Grassi S, Lombardo G, Catalano S, Romagnoli G, Tortorici G (2017) Geophysical and geological survey of the area struck by the August 20th 2016 Central Italy earthquake: the study case of Pretare and Piedilama. J Appl Geophys 145:17–27
Louie JN (2001) Faster, better: shear-wave velocity to 100 meters depth from refraction microtremor arrays. Bull Seismol Soc Am 91:347–364
Luzi L, D’Amico M, Massa M, Puglia R (2018) Site effects observed in the Norcia intermountain basin (Central Italy) exploiting a 20-year monitoring. Bull Earthq Eng. https://doi.org/10.1007/s10518-018-0444-3
Nakamura Y (1989) A method for dynamic characteristics estimation of subsurface using microtremor on the ground surface. QR Railway Tech Res Inst 30:25–33
Google Scholar
Nakamura Y (2000) Clear identification of fundamental idea of Nakamura’s technique and its applications. In: Proceedings of 12th world conference on earthquake engineering, New Zealand
Nogoshi M, Igarashi T (1970) On the propagation characteristics of microtremors. J Seism Soc Japan 23:264–280 (in Japanese with English abstract)
Google Scholar
NTC18 (2018) Norme tecniche per le costruzioni. G.U. n. 42 del 20 febbraio 2018
Ohori M, Nobata A, Wakamatsu K (2002) A comparison of ESAC and FK methods of estimating phase velocity using arbitrarily shaped microtremor arrays. Bull Seismol Soc Am 92:2323–2332
Pagliaroli A, Pergalani F, Ciancimino A, Chiaradonna A, Compagnoni M, De Silva F, Foti S, Giallini S, Lanzo G, Lombardi F, Luzi L, Macerola L, Nocentini M, Pizzi A, Tallini M, Teramo C (2019) Site response analyses for complex geological and morphological conditions: relevant case-histories from 3rd level seismic microzonation in Central Italy. Bull Earthq Eng. https://doi.org/10.1007/s10518-019-00610-7
Park CB, Miller RD, Xia J (1999) Multichannel analysis of surface waves. Geophysics 64:800–808
Parolai S, Picozzi M, Richwalski SM, Milkereit C (2005) Joint inversion of phase velocity dispersion and H/V ratio curves from seismic noise recordings using a genetic algorithm considering higher modes. Geophys Res Lett 32:L01303
Pergalani F, Pagliaroli A, Bourdeau C, Compagnoni M, Lenti L, Lualdi M, Madiai C, Martino S, Razzano R, Varone C, Verrubbi V (2019) Seismic microzoning map: approaches, results and applications after the 2016–2017 Central Italy seismic sequence. Bull Earthq Eng. Special Issue on “Seismic Microzonation of Central Italy”. https://doi.org/10.1007/s10518-019-00610-7
Piatti C, Socco L, Boiero D, Foti S (2013) Constrained 1D joint inversion of seismic surface waves and P-refraction traveltimes. Geophys Prospect 61:77–93. https://doi.org/10.1111/j.1365-2478.2012.01071.x
Picozzi M, Parolai S, Albarello D (2005) Statistical analysis of horizontal to vertical spectral ratios (HVSR). Bull Seism Soc Am 95(5):1779–1786. https://doi.org/10.1785/0120040152
Picozzi M, Albarello D (2007) Combining Genetic and Linearized algorithms for a two-step joint inversion of Rayleigh wave dispersion and H/V spectral ratio curves. Geophys J Int 169:189–200
Piña-Flores J, Perton M, García-Jerez A, Carmona E, Luzón F, Molina-Villegas JC, Sánchez-Sesma FJ (2017) The inversion of spectral ratio H/V in a layered system using the diffuse field assumption (DFA). Geophys J Int 208:577–588
Priolo E, Pacor F, Spallarossa D, Milana G, Laurenzano G, Romano MA, Felicetta C, Hailemikael S, Cara F, Di Giulio G, Ferretti G, Barnaba C, Lanzano G, Luzi L, D’Amico M, Puglia R, Scafidi D, Barani S, De Ferrari R, Cultrera G (2019) Seismological analyses of the seismic microzonation of 138 municipalities damaged by the 2016–2017 seismic sequence in Central Italy. Bull Earthq Eng. https://doi.org/10.1007/s10518-019-00652-x
Sánchez-Sesma FJ, Rodríguez M, Iturrarán-Viveros U, Luzón F, Campillo M, Margerin L, García-Jerez A, Suarez M, Santoyo MA, Rodríguez-Castellanos A (2011) A theory for microtremor H/V spectral ratio: application for a layered medium. Geophys J Int 186:221–225
SARA electronic instruments (2012) DoReMI Manuale d’Uso. SARA electronic instruments s.r.l. Perugia—Italy. https://www.sara.pg.it/SOFTWARE/DOREMI/DoReMi_ITA_SoftwareSection.pdf
SARA electronic instruments (2017) GEOEXPLORER HVSR Versione 2.2.3 MANUALE 'USO. SARA electronic instruments s.r.l. Perugia–Italy. https://www.sara.pg.it/SOFTWARE/GEOEXPLORERHVSR/GEOEXPLORERHVSR_IT.pdf
Servizio geologico d’Italia (2011) Note Illustrative della Carta geologica d’Italia alla scala 1:50.000 fogli 336 “Spoleto”, 324 “Foligno”. ISPRA
SESAME, WP12 (2004) Guidelines for the implementation of the H/V spectral ratio technique on ambient vibrations-Measurements, processing and interpretation. SESAME European research project, Deliverable D23. 12., Project No. EVG1-CT-2000-00026 SESAME
Tertulliani A, Azzaro (a cura di) R (2017) QUEST—Rilievo macrosismico in EMS98 per la sequenza sismica in Italia Centrale: aggiornamento dopo il 18 gennaio 2017. Rapporto interno INGV. https://doi.org/10.5281/zenodo.556929
Vuan A, Romanelli M, Barnaba C, Restivo A, Lovisa L, Priolo E, Rossi G (2007) Relazione scientifica finale. Convenzione tra Comune di Spoleto e OGS per lo studio di microzonazione del centro storico della Città di Spoleto. Rel. OGS 2007/53-CRS/12
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