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Spatial and depth variability of soil characteristics greatly infuence its optimum utilization and management. Concealing nature of soil subsurface horizons has made the traditional soil investigations which rely on point information less reliable. In this study, an alternative use of ground penetrating radar (GPR)—a near-surface geophysical survey method—was tested to address the shortcomings. The focus of the study was on assessment of characteristics variability of soil layers at a test site and evaluation of efects of compaction caused by machinery trafcs on soil. GPR methods utilize electromagnetic energy in the frequency range of 10 MHz and 3.0 GHz. Fourteen profles GPR data were acquired at the test site-a farmland in Krakow, Poland. Compaction on parts of the soil was induced using tractor movements (simulating trafc efects) at difer ent passes. Data were processed using basic fltering algorithms and attributes computations executed in Refexw software. Attempt made in the study was on use of GPR geophysical technique for soil assessment. The method allows delineation of the soil horizons which depicts characteristic depth changes and spatial variability within the horizons. Moreover, trafc efects that caused compaction on parts of the soil horizons were discernable from the GPR profle sections. Thus, similar densifcation like hardpan that may develop in natural setting can be investigated using the method. The results have shown the suitability of the method for quick, noninvasive and continuous soil investigation that may also allow assessment of temporal soil changes via repeated measurement.
Wydawca
Czasopismo
Rocznik
Tom
Strony
643--653
Opis fizyczny
Bibliogr. 25 poz.
Twórcy
autor
- AGH University of Science and Technology, Mickiewicza 30 Ave, 30-059 Krakow, Poland
Bibliografia
- 1. Akinsunmade A, Tomecka-Suchoń S, Pysz P (2019) Complex analysis of GPR signals for the delineation of subsurface subtle features. Geol Geophy Environ 45(4):257–267. https://doi.org/10.7494/geol.2019.45.4.257
- 2. Annan A.P (2003) Ground penetrating radar: principles, procedures and applications. Sensors and software Inc. Technical Paper. 278
- 3. Attributes Revisited, Rock Solid Images Houston, Texas (published 2000)
- 4. Bai Y, Jin WL (2016) Chapter 10 - Offshore Soil Geotechnics. In: Bai Yong, Jin Wei-Liang (eds) Marine Structural Design, 2nd edn. Butterworth-Heinemann, pp 181–195. https://doi.org/10.1016/B978-0-08-099997-5.00010-1
- 5. Barnes AE (1991) Instantaneous frequency and amplitude at the envelope peak of a constant-phase wavelet. Geophysics 56:1058–1060
- 6. Daniels DJ (2004) Ground penetrating radar, 2nd edn. The Institution of Electrical Engineers, London
- 7. dGB Beheer B.V. (2019), dGB Earth Sciences- OpendTect version 6.4 Training manual 2019 Nijverheidstraat 11–27511 JM Enschede The Netherlands: www.https://dgbes.com
- 8. Everett ME (2013) Near-surface applied geophysics. Cambridge University Press, Cambridge
- 9. Forte E, Dossi M, Pipan M, Colucci RR (2014) Velocity analysis from common offset GPR data inversion: theory and application to synthetic and real data. Geophys J Int 197(3):1471–1483
- 10. Hubbard S, Grote K, Rubin Y (2002) Mapping the volumetric soil water content of a California vineyard using high-frequency GPR ground wave data. Lead Edge 21(6):552–559
- 11. Jol HM (2008) Ground penetrating radar theory and applications. Elsevier, USA
- 12. Jonard F, Mahmoudzadeh M, Roisin C, Weihermüller L, André F, Minet J, Lambot S (2013) Characterization of tillage effects on the spatial variation of soil properties using ground-penetrating radar and electromagnetic induction. Geoderma 207:310–322
- 13. Muñiz E, Shaw RK, Gimenez D, Williams CA, Kenny L (2016) Use of ground-penetrating radar to determine depth to compacted layer in soils under pasture. In: Hartemink AE, Minasny B (eds) Digital soil morphometrics. Springer, Cham, pp 411–421
- 14. Nawaz MF, Bourrie G, Trolard F (2013) Soil compaction impact and modelling. A review. Agron Sustain Dev 33(2):291–309. https://doi.org/10.1007/s13593-011-0071-8
- 15. Reynolds JM (2011) An introduction to applied and environmental geophysics. Wiley, UK
- 16. Raper RL, Asmussen LE, Powell JB (1990) Sensing hard pan depth with ground-penetrating radar. Trans ASAE 33(1):41–0046
- 17. Sandmeier KJ (2017a) REFLEXW Version 8.5, Windows™ 9x/ NT/2000/XP/7-program for the processing of seismic, acoustic or electromagnetic reflection, refraction and transmission data
- 18. Sandmeier KJ (2017b) User’s Manual for REFLEXW Version 8.5, Program for the processing of seismic, acoustic or electromagnetic reflection, refraction and transmission data. 578
- 19. Takahashi K, Igel J, Preetz H, Kuroda S, Kumar M (2012) Basics and application of ground-penetrating radar as a tool for monitoring irrigation process. Probl Perspect Chall Agric Water Manag. https://doi.org/10.5772/29324
- 20. Taner MT (1992) Attributes revisited. Rock solid images, Houston, Texas, USA
- 21. Taner MT, Koehler F (1969) Velocity spectra—digital computer derivation applications of velocity functions. Geophysics 34(6):859–881
- 22. Tomecka-Suchoń S, Marcak H (2015) Interpretation of ground penetrating radar attributes in identifying the risk of mining subsidence. Arch Min Sci 60(2):645–656
- 23. Utsi EC (2017) Ground penetrating radar: theory and practice. Butterworth-Heinemann, UK
- 24. Weil RR, Brady NC (2017) The nature and properties of soils, 15th edn. Pearson Education Limited, USA
- 25. Yilmaz Ö (2001) Seismic data analysis: Processing, inversion, and interpretation of seismic data. Society of exploration geophysicists. https://doi.org/10.1190/1.9781560801580
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-7a87e5b2-e17a-4cf4-8dc0-5488978da133