Publications

The selected publications include paper, textbooks and individual contributions to monographs in regard of heat-flow studies of the Earth. This list is to be complemented. To have a heat-flow relevant contribution listed here, send the new reference in the format (author, year. title, source, doi) to the administrator.

2021-2025

  • Fuchs, Sven, Förster, Andrea, Norden, Ben. (2022) Evaluation of the terrestrial heat flow in Germany: A case study for the reassessment of global continental heat-flow data. Earth-Science Reviews, 235, 104231, 10.1016/j.earscirev.2022.104231
  • Majorowicz, Jacek. 2021. "Review of the Heat Flow Mapping in Polish Sedimentary Basin across Different Tectonic Terrains" Energies 14, no. 19: 6103. 10.3390/en141961039
  • Colgan, W., Wansing, A., Mankoff, K., Lösing, M., Hopper, J., Louden, K., Ebbing, J., Christiansen, F. G., Ingeman-Nielsen, T., Liljedahl, L. C., MacGregor, J. A., Hjartarson, Á., Bernstein, S., Karlsson, N. B., Fuchs, S., Hartikainen, J., Liakka, J., Fausto, R., Dahl-Jensen, D., Bjørk, A., Naslund, J.-O., Mørk, F., Martos, Y., Balling, N., Funck, T., Kjeldsen, K. K., Petersen, D., Gregersen, U., Dam, G., Nielsen, T., Khan, A., and Løkkegaard, A.: Greenland Geothermal Heat Flow Database and Map (Version 1), Earth Syst. Sci. Data Discuss. 10.5194/essd-2021-290, in review, 2021.

2016-2020

  • Akkiraju, V.V., Roy, S., Shalivahan, 2018. Ground surface warming in peninsular India: evidence from geothermal records. Current Science, 115 (8), 1567-1571
  • Akkiraju, V.V., Roy, S., Tiwari, V.M., Shalivahan, 2018. A 19th Century baseline temperature estimate for peninsular India from combined analysis of geothermal and meteorological records. Journal of Geological Society of India, 92 (5), 542-547, doi: 10.1007/s12594-018-1064-x.
  • Antriasian, A., R. N. Harris, A. M. Trehu, S. A. Henrys, B. J. Phrampus, R. Lauer, A. R. Gorman, I. A. Pecher, D. Barker (2018), Thermal regime of the nothern Hikurangi margin, New Zealand, Geophys. J. Int., doi: 10.1093/gji/qqy450.
  • Barbero D., Bucci A., Chiozzi P., De Luca D. A., Forno M. G., Lasagna M., Verdoya M., 2018. Subsurface temperature measurements for detecting tectonic dislocations. International Journal of Terrestrial Heat Flow and Applied Geothermics, 1, 41-45. doi: 10.31214/ijthfa.v1i1.16
  • Chicco J., Verdoya M., Giuli G., Invernizzi C., 2019. Thermophysical properties and mineralogical composition of the Umbria-Marche carbonate succession (Central Italy). in Koeberl, C., and Bice, D.M., eds., 250 Million Years of Earth History in Central Italy: Celebrating 25 Years of the Geological Observatory of Coldigioco: Geological Society of America Special Paper 542, 59–67, doi: 10.1130/2019.2542(02)
  • Chopra, N., Ray, L., Satyanarayanan, M., Elangovan, R., 2018. Evaluate best-mixing model for estimating thermal conductivity for granitoids from mineralogy: A case study for the granitoids of the Bundelkhand craton, central India. Geothermics, 75, 1-14, doi: 10.1016/j.geothermics.2018.03.011.
  • El Jbeily E., Verdoya M., Chiozzi P., Ivaldi R., Ghaith A., 2019. Geothermal flow and water-load seafloor depth of the Eastern Mediterranean Sea. AIP Conference Proceedings 2123, 020018 (2019); doi: 10.1063/1.5116945
  • Fuchs, S., & Balling, N. (2016). Improving the temperature predictions of subsurface thermal models by using high-quality input data. Part 2: A case study from the Danish-German border region Geothermics, 64, 1-14. doi: 10.1016/j.geothermics.2016.04.004
  • Fuchs, S., Balling, N., Mathiesen, A. 2020. Deep basin temperature and heat-flow field in Denmark – New insights from borehole analysis and 3D geothermal modelling. Geothermics 83. doi: 10.1016/j.geothermics.2019.101722.
  • Giordano N., Chicco J., Mandrone G, Verdoya M., Wheeler W.H., 2019. Comparing transient and steady‑state methods for the thermal conductivity characterization of a borehole heat exchanger field in Bergen, Norway. Environmental Earth Sciences 78:460, doi: 10.1007/s12665-019-8397-7
  • Grad M., Puziewicz J., Majorowicz J., Chrapkiewicz K., Lepore S., Polkowski M., Wilde-Piórko M., (2018) The geophysical characteristic of the lower lithosphere and asthenosphere in the marginal zone of the East European Craton, International Journal of Earth Sciences, vol. 107(8), pp. 2711–2726, doi: 10.1007/s00531-018-1621-y
  • Hamza V., Huang S., Verdoya M., 2018. Editorial to the inaugural issue of “International Journal of Terrestrial Heat Flow and Applied Geothermics”. International Journal of Terrestrial Heat Flow and Applied Geothermics, 1, I-V. http://ijthfa.com/
  • Harris, R. N., G. A. Spinelli, and A. T. Fisher (2017), Hydrothermal circulation and the thermal structure of shallow subduction zones, Geopshere, 13, doi: 10.1130/GES01498.1.
  • Hass, B., and R. N. Harris (2016), Heat flow along the Costa Rica seismogenesis project drilling transect: Implications for hydrothermal and seismic processes, Geochem. Geophys. Geosyst., 16, doi: 10.1002/2016GC006314.
  • Majorowicz J., Grad M., Polkowski M., (2019), Terrestrial heat flow versus crustal thickness and topography – European continental study, International Journal of Terrestrial Heat Flow and Applied Geothermics, vol. 2(1), pp. 17-21, doi: 10.31214/ijthfa.v2i1.30
  • Majorowicz J., Polkowski M., Grad M., (2019), Thermal properties of the crust and the lithosphere–asthenosphere boundary in the area of Poland from the heat flow variability and seismic data, International Journal of Earth Sciences, vol. 108(2), pp. 649–672, doi: 10.1007/s00531-018-01673-8
  • Neumann, F., R. Negrete-Aranda, R. N. Harris, J. Contreras, and J. G. Sclater, (2017), Systematic heat flow measurements across the Wagner Basin, northern Gulf of California, Earth Planet. Sci. Lett. 479, 340-353, doi: 10.1016/j.epsl.2017.09.037.
  • Pasqua C., M. Verdoya, P. Chiozzi, L. Marini, 2016. Evaluation of geothermal resources in a hotspot realm: Mauritius Island (Indian Ocean). Proceedings, 6th African Rift Geothermal Conference, Addis Ababa, Ethiopia, 2nd – 4th November 2016, 11 pp.
  • Pauselli, C; Gola, G; Mancinelli, P; Trumpy, E; Saccone, M; Manzella, A; Ranalli, G. (2019). A new surface heat flow map of the Northern Apennines between latitudes 42.5 and 44.5 N, Geothermics, 81, 39-52.
  • Phrampus, B. J., Harris, R. N., and A. M. Trehu (2017), Heat flow bounds over the Cascadia margin derived from bottom simulating reflectors and implications for thermal models of subduction, Geochem. Geophys. Geosyst., doi: 10.1002/2017GC007077.
  • Podugu, N., Ray, L., Singh, S.P., and Roy, S., 2017. Heat flow, Heat production and crustal temperatures in the Archaean Bundelkhand craton, north-central India: Implications for thermal regime beneath the Indian shield. J. Geophys. Res., Solid Earth, 122, 5766-5788, doi: 10.1002/2017JB014041.
  • Popov, Y., G. Beardsmore, C. Clauser, and S. Roy, 2016, ISRM Suggested Methods for Determining Thermal Properties of Rocks from Laboratory Tests at Atmospheric Pressure, Rock Mechanics and Rock Engineering, v.49, pp.4179-4207, doi:10.1007/s00603-016-1070-5.
  • Puziewicz J., Czechowski L., Grad M., Majorowicz J., Pietranik A., Šafanda J., (2019), Crustal lithology vs. thermal state and Moho heat flow across the NE part of the European Variscan orogen: a case study from SW Poland, International Journal of Earth Sciences, vol. 108(2), pp. 673–692, doi: 10.1007/s00531-018-01674-7
  • Ray, L., Nagaraju, P., Singh, S.P., Ravi, G., and Roy., S., 2016. Radioelemental, petrological and geochemical characterization of the Bundelkhand craton, central India: Implication in the Archean geodynamic evolution. Int. J. Earth Sci., 105, 1087-1107, doi: 10.1007/s00531-015-1229-4.
  • Rizzello D., E. Armadillo, C. Pasqua, M. Verdoya, S. Kebede, A. Mengiste, G.H. Giorgis, 2016. Three-dimensional geophysical modelling of the Alalobeda Geothermal Field. Proceedings, 6th African Rift Geothermal Conference, Addis Ababa, Ethiopia, 2nd – 4th November 2016, 11 pp.
  • Rosas, J. C., C. A. Currie, R. N. Harris, and J He (2016), Effect of hydrothermal circulation on slab dehydration for the subduction zone of Costa Rica and Nicaragua, Phys. Earth Planet. Int., 255, 66-79, doi: 10.1016/j.pepi.2016.03.009.
  • Salmi, M. S., H. P. Johnson, and R. N. Harris (2017), Thermal Environment of the Southern Washington region of the Cascadia Subduction Zone, J. Geophys. Res., doi: 10.1002/2016JB013839.
  • Spinelli, G., I. Wada, K. Wang, J. He, R. Harris, and M. Underwood (2017), Diagenetic, metamorphic, and hydrogeologic consequences of hydrothermal circulation in subducting crust, Geosphere, 14, doi: 10.1130/GES01653.1
  • Verdoya M., Chiozzi P., 2018. Influence of groundwater flow on the estimation of subsurface thermal parameters. Int J Earth Sci (Geol Rundsch), 107, 137–144
  • Verdoya M., Chiozzi P., Gola G., El Jbeily E., 2019. Conductive heat flow pattern of the central-northern Apennines, Italy. International Journal of Terrestrial Heat Flow and Applied Geothermics, 2, 37-45, ISSN: 2595-4180.
  • Verdoya M., Pacetti C., Chiozzi P., Invernizzi C., 2018. Thermophysical parameters from laboratory measurements and in-situ tests in borehole heat exchangers Applied Thermal Engineering 144, 711–720.
  • Vieira, F.P. and Hamza, V.M., 2018, Global Heat Flow: New Estimates using Digital Maps and GIS Techniques. International Journal of Terrestrial Heat Flow and Applied Geothermics - IJTHFA, 1, 6-13.

2011-2015

  • Akkiraju, V.V., Roy, S., 2011a. Geothermal climate change observatory in south India 1: Borehole temperatures and inferred surface temperature histories. Phys. Chem. Earth, 36 (16), 1419-1427, doi: 10.1016/j.pce.2011.01.004.
  • Akkiraju, V.V., Roy, S., 2011b. Geothermal climate change observatory in south India 2: Set-up and first results. Phys. Chem. Earth, 36 (16), 1428-1436, doi:10.1016/j.pce.2011.01.011.
  • Armadillo E., D. Rizzello, M. Verdoya, C. Pasqua, P. Pisani, 2015. Cubic spline regularization applied to 1D magnetotelluric inverse modeling in geothermal areas Proceedings World Geothermal Congress 2015 Melbourne, Australia, 19-25 April 2015, 6 pp.
  • Barkaoui A. E., Zarhloule, Y. Rimi, A., Verdoya, M., Bouri, S., 2013. Hydrogeochemical investigations of thermal waters in the northeastern part of Morocco. Environmental Earth Sciences, doi: 10.1007/s12665-013-2582-x
  • Barkaoui A.E., Correia, A., Zarhloule, Y., Rimi, A., Carneiro, J., Boughriba, M., Verdoya, M., 2013. Reconstruction of remote climate change from borehole temperature measurement in the eastern part of Morocco Climatic Change, 118 (2), 431-441.
  • Bochiolo M., M. Verdoya, P. Chiozzi, V. Pasquale., 2012. Radiometric surveying for the assessment of radiation dose and radon specific exhalation in underground environment. Journal of Applied Geophysics 83, 100-106.
  • Fuchs, S., Balling, N., & Förster, A. (2015). Calculation of thermal conductivity, thermal diffusivity and specific heat capacity of sedimentary rocks using petrophysical well logs. Geophysical Journal International, 203(3), 1977-2000. doi: 10.1093/gji/ggv403
  • Hamza, V.M., Cardoso, R.R., Alexandrino, C.H. 2010. A magma accretion model for the formation of oceanic lithosphere: Implications for global heat loss, International Journal of Geophysics, pp. 1-16.
  • Hamza, V.M. 2013. Global Heat Flow without invoking ‘Kelvin Paradox’, Frontiers in Geosciences, Volume 1, No.1, PP. 11-20.
  • Majorowicz, J., Chan, J., Crowell, J., Gosnold, W., Heaman, L. M., Kück, J., Nieuwenhuis, G.,Schmitt, D. R.,Unsworth, M., Walsh, N., Weides, S. (2014). The first deep heat flow determination in crystalline basement rocks beneath the Western Canadian Sedimentary Basin. Geophysical Journal International, 197(2), 731-747. doi: 10.1093/gji/ggu065
  • Majorowicz J, Wybraniec S (2011) New terrestrial heat flow map of Europe after regional paleoclimatic correction application. Int J Earth Sci 100(881–887):55
  • Nagaraju, P., and Roy, S., 2014. Effect of water saturation on rock thermal conductivity measurements. Tectonophysics, 626, 137-143, doi: 10.1016/j.tecto.2014.04.007, doi: 10.1016/j.tecto.2014.04.007.
  • Nagaraju, P., Ray, L, Ravi, G, Akkiraju, V.V, and Roy, S., 2012. Geothermal investigations in the Upper Vindhyan sedimentary rocks of Shivpuri area, central India. J. Geol. Soc. India, 80, 39-47, doi: 10.1007/s12594-012-0116-x.
  • Pasquale, V., Chiozzi, P., Gola, G. and Verdoya, M. (2008). Depth–time correction of petroleum bottom-hole temperatures in the Po Plain, Italy, Geophysics, 73, 187–196.
  • Pasquale, V., Gola, G., Chiozzi, P. and Verdoya, M. (2011). Thermophysical properties of the Po Basin rocks. Geophysical Journal International, 186, 69-81.
  • Pasquale V., P. Chiozzi, M. Verdoya and G. Gola (2012). Heat flow in the Western Po Basin and the surrounding orogenic belts. Geophys. J. Int., 190, 8–22.
  • Pasquale V., M. Verdoya, P. Chiozzi, 2011. Groundwater flow analysis using different geothermal constraints: The case study of Acqui Terme area, northwestern Italy Journal of Volcanology and Geothermal Research, 1-2, 38-46.
  • Pasquale V., M.Verdoya, P. Chiozzi, 2015. Measurements of rock thermal conductivity with a Transient Divided Bar. Geothermics 53:183–189. doi: 10.1016/j.geothermics.2014.05.008
  • Pasquale V., M.Verdoya, P.Chiozzi, 2014. Heat flow and geothermal resources in northern Italy. Renewable and Sustainable Energy Reviews, 362, 77–285.
  • Ray, L., Förster, H.J., Förster, A., Fuchs, S., Naumann, R., Appelt, O., 2015. Tracking the thermal properties of the lower continental crust: measured versus calculated thermal conductivity of high-grade metamorphic rocks (Southern Granulite Province, India). Geothermics, 55, 138–149, doi: 10.1016/j.geothermics.2015.01.007.
  • Rimi A., Zarhloule Y., Barkaoui A.E., Correia A. Carneiro J., M. Verdoya, Lucazeau F., 2012. Towards a de-carbonized energy system in north-eastern Morocco: Prospective geothermal resource. Renewable and Sustainable Energy Reviews. 16, 2207– 2216.
  • Rimi, A.; Correia A., J. Carneiro, M. Verdoya, Zarhloule Y., Lucazeau F., Boughriba M., Barkaoui A. E., 2010. New geothermal prospect in northeastern Morocco. Proceedings of the World Geothermal Congress, Bali, Indonesia, April 2010, 5 pp.
  • Roy, S., Chapman, D.S., 2012, Borehole temperatures and climate change: Ground temperature change in south India over the past two centuries. J. Geophys. Res., 117, D11105, doi:10.1029/2011JD017224.
  • Roy, S., Mareschal, J.C. 2011. Constraints on the deep thermal structure of the Dharwar craton, India, from heat flow, shear wave velocities, and mantle xenoliths. J. Geophys. Res., 116, B02409, doi: 10.1029/2010JB007796.
  • Schintgen, T., Förster, A., Förster, H.-J., & Norden, B. (2015). Surface heat flow and lithosphere thermal structure of the Rhenohercynian Zone in the greater Luxembourg region. Geothermics, 56(0), 93-109. doi: 10.1016/j.geothermics.2015.03.007
  • Schütz, F., Förster, H.-J., & Förster, A. (2014). Thermal conditions of the northern Sinai Microplate inferred from new surface heat-flow values and continuous borehole temperature logging in central and southern Israel. Journal of Geodynamics, 76, 8-24. doi: 10.1016/j.jog.2014.02.010
  • Schütz, F., Norden, B., Förster, A., & Group, D. (2012). Thermal properties of sediments in southern Israel: a comprehensive data set for heat flow and geothermal energy studies. Basin Research, 24(3), 357-376. doi: 10.1111/j.1365-2117.2011.00529.x
  • Sircar, A., M. Shah, S. Sahajpal, D. Vaidya, S. Dhale, and A. Chaudhary, 2015. Geothermal exploration in Gujarat: case study from Dholera. Geothermal Energy, 3 (22), doi: 10.1186/s40517-015-0041-5.

2006-2010

  • Baujard, C., Karytsas, C., Kohl, T., Manzella, A., Schulte, T. (eds), 2008. Best Practice Handbook for the development of unconventional geothermal ressources with a focus on Enhanced Geothermal Systems, ENGINE Coordination Action (ENhanced Geothermal Innovative Network for Europe), http://engine.brgm.fr.
  • Bodri, L., Cermak, V., 2007. Borehole Climatology - A New Method on How to Reconstruct Climate, Elsevier, Oxford
  • Boughriba M., A.E. Barkaoui, Y.Zarhloule, Z. Lahmer, B. El Houadi, M. Verdoya, 2009. Groundwater vulnerability and risk mapping of the Angad transboundary aquifer using DRASTIC index method in GIS environment. Arab. J. Geosci., doi: 10.1007/s12517-009-0072-y
  • Clauser, C., 2006. Geothermal Energy, In: K. Heinloth (ed), Landolt-Börnstein, Group VIII: Advanced Materials and Technologies, Vol. 3: Energy Technologies, Subvol. C: Renewable Energies, Springer Verlag, Heidelberg-Berlin, 493-604.
  • Fuchs, S., & Förster, A., 2010. Rock thermal conductivity of Mesozoic geothermal aquifers in the Northeast German Basin. Chemie Der Erde-Geochemistry, 70(S 3), 13–22. doi: 10.1016/j.chemer.2010.05.010
  • Gupta, H., Roy, S., 2006. Geothermal Energy - An Alternative Resource for the 21st Century, Elsevier, Amsterdam
  • Gupta, H.K., Roy, S., 2006. Geothermal Energy: An Alternative Resource for the 21st Century. Elsevier, Amsterdam, 306p.
  • Hamza V.M., Cardoso R.R., Ponte Neto C.F. 2008. Spherical Harmonic Analysis of Earth's Conductive Heat Flow. International Journal of Earth Sciences, 97, 205-226.
  • Huenges, E. (ed), 2010., Geothermal Energy Systems, Wiley-VCH , Weinheim*
  • Jaupart, C. and Mareschal, J.-C, 2010. Heat Generation and Transport in the Earth, Cambridge University Press, Cambridge
  • Kumar, P.S., Menon, R., Reddy, G.K., 2007. The role of radiogenic heat production in the thermal evolution of a Proterozoic granulite-facies orogenic belt: Eastern Ghats, Indian Shield. Earth and Planetary Science Letters, 254 (1-2), 39-54, doi: 10.1016/j.epsl.2006.11.018.
  • Kumar, P.S., Menon, R., Reddy, G.K., 2009. Heat production heterogeneity of the Indian crust beneath the Himalaya: Insights from the northern Indian Shield. Earth and Planetary Science Letters, 283 (1-4), 190-196, doi: 10.1016/j.epsl.2009.04.015.
  • Majorowicz J, Šafanda J, 2008. Heat flow variation with depth in Poland: evidence from equilibrium temperature logs in 2.9-kmdeep well Torun-1. Int J Earth Sci 97:307–315. doi: 10.1007/S00531-007-0210-2
  • Norden, B., Förster, A., & Balling, N. (2008). Heat flow and lithospheric thermal regime in the Northeast German Basin. Tectonophysics, 460(1-4), 215–229. doi: 10.1016/j.tecto.2008.08.022
  • Pasquale V., M. Verdoya P. Chiozzi, 2010. Evaluation of heat and water flow in porosity permeable horizons. Bollettino Geofis. Teor. Appl., 51, 361-371.
  • Pasquale V., M. Verdoya P. Chiozzi, E. Armadillo, 2009 Thermal, radioactive and magnetic properties of the lavas of the Mt Melbourne Volcanic Field (Victoria Land, Antarctica), Annals of Geophysics 52, 197-207.
  • Przybylak, R. Majorowicz, J. Brazdol, R. Kejna, M. (eds), 2010. The Polish Climate in the European Context: An Historical Overview, Springer, Dordrecht
  • Ray, L., Bhattacharya, A., Roy, S., 2007. Thermal conductivity of Higher Himalayan Crystallines from Garhwal Himalaya, India. Tectonophysics, 434, 71-79, doi: 10.1016/j.tecto.2007.02.003.
  • Ray, L., Forster, H.J., Schilling, F.R., Forster, A., 2006. Thermal diffusivity of felsic to mafic granulites at elevated temperatures. Tectonophysics, 251, 241-253, doi: 10.1016/j.epsl.2006.09.010.
  • Roy, S., Ray, L., Bhattacharya, A. Srinivasan, R., 2008. Heat flow and crustal thermal structure in the Late Archaean Closepet Granite batholith, south India. Int. J. Earth Sci. (Geol Rundsch), 97, doi: [10.1007/s00531-007-0239-2, 245-256](http://dx.doi.org/10.1007/s00531-007-0239-2, 245-256).
  • Roy, S., 2008. Heat flow studies in India during the Past Five Decades. In: Dimri, V.P., Singh, B., (Eds.), Five Decades of Geophysics in India. Mem. Geol. Soc. India, 68, 89-122. Tester, J. W. (ed), 2006. The Future of Geothermal Energy - Impact of Enhanced Geothermal Systems (EGS) on the United States in the 21st Century, Massachusetts Institute of Technology, Cambridge, MA,
  • Verdoya M., P. P. Chiozzi De Felice, V. Pasquale, M. Bochiolo, I. Genovesi, 2009. Natural gamma-ray spectrometry as a tool for radiation dose and radon hazard modelling. Applied radiation and Isotopes, 67, 964–968.
  • Verdoya M., V. Pasquale P. Chiozzi, 2007, Thermal log analysis for recognition of ground surface temperature change and water movements. Climate of the Past, 3, 315–324.
  • Verdoya M., V. Pasquale, P. Chiozzi, 2008. Inferring hydro-geothermal parameters from advectively perturbed thermal logs. International Journal of Earth Sciences, 97, 333–344.

2001-2005

  • Beardsmore, G. R., Cull, J. P., 2001. Crustal Heat Flow - A guide to measurement and modelling, Cambridge University Press, Cambridge.
  • Clauser, C. (ed), 2003. Numerical Simulation of Reactive Flow in hot Aquifers using SHEMAT/Processing Shemat, Springer Verlag, Heidelberg-Berlin.
  • Dickson, M. H., Fanelli, M., 2003. Geothermal Energy - Utilization and Technology, UNESCO Publishing, Paris
  • Kumar, P.S., Reddy, G.K., 2004. Radioelements and heat production of an exposed Archaean crustal cross-section, Dharwar craton, south India. Earth Planet Sci. Lett., 224:309-324, doi: 10.1016/j.epsl.2004.05.032.
  • Majorowicz, J., Safanda, J., Skinner, W., 2004. Past Surface Temperature Changes as Derived from continental Temperature Logs - Canadian and Global Examples of Application of a New Tool in Climate Change Studies Advances in Geophysics, Elsevier
  • Menon, R., Kumar, P.S., Reddy, G.K., Srinivasan, R., 2003. Radiogenic heat production of late Archaean Bundelkhand granite and some Proterozoic gneisses and granitoids of central India. Curr. Sci., 85, 634-638.
  • Pasquale V., M. Verdoya, P. Chiozzi, 2001. Heat flux and seimicity in the Fennoscandian shield. Physics Earth Plan. Int. 126: 147-162
  • Pasquale V., M. Verdoya, P. Chiozzi, 2002 A possible mechanism for the thermal asymmetry of the Ligurian basin. Terra Nova, 14, 484-490.
  • Pasquale V., M. Verdoya, P. Chiozzi, 2002 Heat from radioactive elements in young volcanics by γ-ray spectrometry. Journal of Volcanology and Geothermal Research, 119: 205-214.
  • Pasquale V., M. Verdoya, P. Chiozzi, 2002. Natural occurring radioactivity at the Alps-Apennines transition. Radiation Measurements 35: 147-154.
  • Pasquale V., M. Verdoya, P. Chiozzi, 2003. Heat-flux budget in the southeastern continental margin of the Tyrrhenian basin. Physics and Chemistry of the Earth, 28: 407-420.
  • Pasquale V., M. Verdoya, P. Chiozzi, 2005. Orographic influence on the central-northern Italy climate from underground temperatures. Croatian Meteorological Journal, 40, 669-672.
  • Pasquale V., M. Verdoya, P. Chiozzi, 2005. Thermal structure of the Ionian slab. Pure appl. geophys., 162, 967-986.
  • Pasquale V., M. Verdoya, P. Chiozzi, L. Bodri, S. Bellani, 2005. Temperature signal in the underground for climate history reconstruction in Italy. Global and Planetary Change, 47: 36-50.
  • Pasquale V., M. Verdoya, P. Chiozzi, S. Minato, 2003. Natural gamma-ray activity in the volcanic islands of the Southern Tyrrhenian. Journal of Environmental Radioactivity, 67: 235-246.
  • Rao, R.U.M., Roy, S., Srinivasan, R., 2003. Heat-flow researches in India: results and perspectives. In: Mahadevan, T.M., Arora, B.R., Gupta, K.R., (Eds.), Indian Continental Lithosphere, Emerging Research Trends. Mem. Geol. Soc. India, 53, 347-391.
  • Ray, L., Kumar, P.S., Reddy, G.K., Roy, S., Rao, G.V., Srinivasan, R., Rao, R.U.M., 2003, High mantle heat-flow in a Precambrian granulite province: evidence from southern India. J. Geophys. Res., 108, 2084, doi: [10.1029/ 2001JB000688](http://dx.doi.org/10.1029/ 2001JB000688).
  • Roy, S., Ray, L., Kumar, P.S., Reddy, G.K., Srinivasan, R., 2003. Heat-flow and heat production in the Precambrian gneiss-granulite province of southern India. In: Ramakrishnan, M., (Eds.), Tectonics of Southern Granulite Terrian. Mem. Geol. Soc. India, 50, 177-191.
  • Roy, S., Harris, R.N., Rao, R.U.M., Chapman, D.S., 2002, Climate change in India inferred from geothermal observations. J. Geophys. Res., 107 (B7), 2138, doi:10.1029/2001JB000536.
  • Roy, S., Rao, R.U.M., 2003. Towards a crustal thermal model for the Archaean Dharwar craton, southern India. Phys. Chem. Earth., 28, 361-373, doi: 10.1016/S1474-7065(03)00058-5.
  • Šafanda J, Szewczyk J, Majorowicz J (2004) Geothermal evidence of very low glacial temperatures on a rim of the Fennoscandian ice sheet. Geophys Res Lett 31:L07211. doi: 10.1029/2004GL019547
  • Verdoya M., V. Pasquale, P. Chiozzi, 2001. Heat-producing radionuclides in metamorphic rocks of the Briançonnais-Piedmont Zone (Maritime Alps). Eclogae Geologicae Helvetiae, 94: 213-219.
  • Verdoya M., V. Pasquale, P. Chiozzi, 2005. Thermo-mechanical evolution and rheology of the northern sector of the Tyrrhenian-Apennines system. Journal of Volcanology and Geothermal Research, 148, 20-30.

1996-2000

  • Artemieva I.M., 1996. The dependence of transport properties of in situ rocks on pore fluid composition and temperature. Surveys in Geophysics 17: 89-306.
  • Artemieva I.M., 1997. In-situ permeability of hot dry rock. In: M.F.Middleton (Ed.) 2nd Nordic Symposium on Petrophysics: Fractured Reservoirs, Nordic Petroleum Technology Series, Part 1, Goteborg, 99- 124.
  • Bodri, L. and Cermak, V., 1997. Climate changes of the last two millenia inferred from borehole temperatures. Results from the Czech Republic. Part II. Global Planet.Change, 14: 163-173.
  • Bodri, L. and Cermak, V., 1997. Reconstruction of remote climate changes from borehole temperatures. Global Planet.Change, 15: 47-57.
  • Bulashevich Yu.P., Demezhko D.Yu., Shchapov V.A. and Yurcov A.K.,1997. Effect of Palaeoclimate on the Underground Temperature of the Urals Deep Hole. Doklady Akademii Nauk, vol.356, N 1, p.102-104. (in Russian).
  • Cercone, K.R., Deming, D., and Pollack, H.N., 1996. Insulating effects of coals and black shales in the Appalachian Basin of western Pennsylvania, Organic Geochemistry, 24, 243-249.
  • Cermak, V. and Bodri, L., 1996. Time dependent deep temperature modelling : Central Alps. Tectonophysics, 257: 7-24.
  • Cermak, V. and Bodri, L., 1997. Lithospheric thermal regimes: theoretical basis for preliminary evaluation of geothermal potential. In: K.Dimitrov, O.Mertoglu and K.Popovski (Eds.), Geothermal District Heating Schemes, pp. 7(1)-7(14). Ankara-Skopje.
  • Cermak, V., Safanda, J. and Bodri, L., 1996. Climate change inferred from borehole temperatures. World Res.Review, 8(1): 69-79.
  • Cermak, V., Safanda, J. and Bodri, L., 1997. Climate change stored below the Earth s surface. Proceedings Volume of the 8th Global Warming Conference, New York, May 26-29, 1997
  • Cermak, V., Safanda, J., Kresl, M. and Kucerova, L., 1996. Heat flow studies in Central Europe with special emphasis on data from former Czechoslovakia. Global Tectonics and Metallogeny, 5: 109-123.
  • Clauser, C., 1997. Erdwaermenutzung in Deutschland, Geowissenschaften, 15(7), 118-224.
  • Clauser, C., 1997. Thermal Signatures of Heat Transfer Processes in the Earth's Crust, Lecture Notes in Earth Sciences, Vol. 85, ISBN 3-540-65604-9, Springer Verlag, Heidelberg-Berlin.
  • Clauser, C., Giese, P., Huenges, E., Kohl, T., Lehmann, H., Rybach, L., Safanda, J., Wilhelm, H., Windloff, K., Zoth, G., 1997. The thermal regime of the crystalline continental crust: Implications from the KTB, J.Geophys. Res, 102(B8), 18417-18441.
  • Demezhko D.Yu.,1996. Using a statistical relations between the climatic factors for the paleoclimate reconstructions in the Urals by mean of geothermal data. Dep.VINITI, N 1410-B96, 18 pp.(in Russian).
  • Demezhko D.Yu.,1996. Using borehole temperature data for the ground surface temperature history reconstruction in the Urals. Dep.VINITI, N 602-B96, 11 pp.(in Russian).
  • Demezhko D.Yu.,1997. Paleoclimatic interpretation of the borehole temperature data. "Vychislitelnye tehnologii" (Computational technologies) vol.2, N 2, p. 44-47. (in Russian).
  • Demezhko D.Yu.and Ryvkin D.G.,1996. Taking into consideration of the local anomalies of surface temperature during paleoclimatic interpretation of the geothermal data. Dep. VINITI, N 1411-B96, 11 pp. (in Russian).
  • Dmitriev, V.I., Kostyanev, S.G. and Mershikova, N.A., 1997. On the inverse problem of reconstruction of paleoclimate. Jurnal of Moscow University, Computer Mathematics, 15, 5-12. (In Russian).
  • Duchkov A.D. and Kazantsev S.A., 1996. The temperature measurements in the first underwater boreholes of Lake Baikal. Russian Geology and Geophysics, 1996, No.6, p. 95-103 (in Russian)
  • Duchkov A.D. and Sokolova L.S., 1997. Thermal structure of the lithosphere of the Siberian platform. Russian Geology and Geophysics, 1997, No. 2, p. 528-537 (in Russian)
  • Duchkov A.D., Sokolova L.S., Balobaev V.T. et al., 1997. Heat flow and geothermal field in Siberia. Russian Geology and Geophysics, 1997, No. 11, p. 1716-1729 (in Russian)
  • Foerster, A. and Schroetter, J., 1997, Distributed optic-fibre temperature sensing (DTS): a new tool for determining subsurface temperature changes and reservoir characteristics: Proc. Twenty-First Workshop on Geothermal Reservoir Engineering Stanford Univ., Stanford (CA), p. 253-258.
  • Foerster, A., and Merriam, D.F., 1997, Heat flow in the Cretaceous of northwestern Kansas and implications for regional hydrology: Kansas Geol. Survey, Current Research in Earth Sciences, Bull.240, pt 1,
  • Foerster, A., Merriam, D.F., and Davis, J.C., 1996, Statistical analysis of some bottom-hole temperature (BHT) correction factors for the Cherokee Basin, southeastern Kansas: Tulsa Geol. Soc. Trans., 1995, p. 3-9.
  • Foerster, A., Schroetter, J., Merriam, D.F., and Blackwell, D.D., 1997, Application of optical fibre temperature logging, example in a sedimentary environment: Geophysics, v. 62, no. 4, p. 1107-1113.
  • Forster, Merriam (ed), 1999. Geotermics in Basin Analysis in Computer Applications in the Earth Sciences, , Kluver Academics, Plenum Press
  • Golmshtok A.Ya., Duchkov A.D., Hutchinson D.R. et al., 1997. Estimation of the heat flow on the Lake Baikal based on seismic data of gas hydrates layer low boundary. Russian Geology and Geophysics, 1997, No. 10, p. 1677-1691 (in Russian)
  • Huang Shaopeng, Wang Jiyang, and Chen Moxiang, 1996. Temperature at the Moho. In Yuan Xuecheng (Chief Compiler), Atlas of Geophysics in China (Publication No.201 of the International Lithosphere Program), Geological Publishing House, Beijing, pp. 105-107.
  • Huang Shaopeng, Wang Jiyang, and Chen Moxiang, 1996. Thickness of the Thermo-Lithosphere. In Yuan Xuecheng (Chief Compiler), Atlas of Geophysics in China (Publication No.201 of the International Lithosphere Program), Geological Publishing House, Beijing, pp. 109- 111.
  • Huang, S., Pollack, H. N., and Shen, P.Y., 1997. Late Quaterary temperature change seen in world-wide continental heat flow measurements. Geophys. Res. Lett., 24: 1947-1950.
  • Huang, S., Shen, P. Y. Pollack, H.N., 1996. Deriving century-long trends of surface temperature change from Borehole Temperatures, Geophysical Research Letters, 23: 257-260.
  • Hurter, S., and Pollack, H.N., 1996. Terrestrial heat flow in the Parana Basin, southern Brazil, Journal of Geophysical Researh, v.101, pp.8659-8671.
  • Hyndman, R.D., Yamano, M. and Oleskevich, D.A., 1997. The seismogenic zone of subduction thrust faults. Island Arc, 6: 244-260.
  • Khachay Yu.V., Demezhko D.Yu., Ryvkin D.G. and Shchapov V.A.,1996. Paleotemperature reconstructions for the Northern Urals according to borehole thermometry. "Geologiya i Geofizika" (Geology and Geophysics), vol.37, N 12, p.108-113 (in Russian).
  • Kinoshita, M. and Yamano, M., 1997. Hydrothermal regime and constraints on reservoir depth of the Jade site in the Mid-Okinawa Trough inferred from heat flow measurements. J. Geophys. Res., 102: 3183-3194.
  • Kinoshita, M., Goto, S. and Yamano, M., 1996. Estimation of thermal gradient and diffusivity by means of long-term measurements of subbottom temperatures at western Sagami Bay, Japan. Earth Planet. Sci. Lett., 141: 249-258.
  • Krilov S.V. and Duchkov A.D., 1996. The study of the formation conditions of the crustal earthquakes: the strain-strength regionalization of the seismoactive media. Proceedings of Russian Academy, 1996, v. 349, No. 6, p. 814-817 (in Russian)
  • Krilov S.V. and Duchkov A.D.,1996. Deep strain-strength regionalization of the Earth's crust (on the example of the Altai- Sayan and Baikal seismic zones). Russian Geology and Geophysics, 1996, No. 9, p. 56-65 (in Russian)
  • Kukkonen, I. and Safanda, J., 1996. Palaeoclimate and structure: the most important factors controlling subsurface temperatures in crystalline rocks. A case history from Outokumpu, Eastern Finland. Geoph.J.Int., 126: 101-112.
  • Kukkonen, I.T. and Safanda, J., 1996. Palaeoclimate and structure: the most important factors controlling subsurface temperatures in crystalline rocks. A case history from Outokumpu, Eastern Finland. Geoph.J.Int., 126, 101-112.
  • Kukkonen, I.T. and Safanda, J., 1996. Rekonstruktion der Palaoklimatischen Erdoberflachetemperaturen aus Bohrlochtemperaturen in einer heterogenen Formation in Ost-Finland, Sonderband II/1996 der Mitteilungen der DGG, 55-57.
  • Kutasov, I. M., 1999. Applied Geothermics for Petroleum Engineers (Developments in Petroleum Science 48) Elsevier, Amsterdam
  • Lewis, T. J., Lowe, C. and Hamilton, T.S., 1997. Continental signature of a ridge-trench-triple junction: Northern Vancouver Island, Journal of Geophysical Research, 102, 7767-7781.
  • Majorowicz J.A. and W.R. Skinner, 1997, Anomalous Ground Warming VS Surface Air Warming in the Canadian Prarie Provinces, Climatic Change,Vol. 35, p. 485-500
  • Majorowicz J.A., 1996, Accelerating Ground Warming in the Canadian Prarie Provinces: Is it a Result of Global Warming? Pageoph, Vol.147, No. 1,p. 1-24.
  • Majorowicz J.A., 1996, Anomalous Heat Flow Regime in the Western Margin of the North American Craton, Canada, J.Geodynamics, Vol 21,No.2, pp. 123-140.
  • Majorowicz J.A., A.M. Jessop, and A.S. Judge, 1996, Geothermal Regime, in: Geological Atlas of the Beufort-Mackenzie Area, Edited by J. Dixon,Geological Survey of Canada, Report 59, P. 33-37, Natural Resources, Canada.
  • Majorowicz, J.A. and W.R. Skinner, 1997, Potential Causes of Differences between Ground and Surface Air Temperature Warming across Different Ecozones in Alberta, Canada, Global and Planetary Change, v. 15, issue 3-4.
  • Majorowicz, J.A. and W.R. Skinner, 1997, Recent and Pre-instrumental Climatic Conditions as Reconstructed from Temperature logs in Western and Northern Canada, AMS Transactions,Global Change Symposium, 1997 Annual Conference, Long Beach, Ca.,paper 15.1
  • Pasquale V., M. Verdoya, P. Chiozzi, 1996. Heat flux and timing of the drifting stage in the Ligurian-Provençal basin (northwestern Mediterranean). Journal of Geodynamics, 21(3): 205-222.
  • Pasquale V., M. Verdoya, P. Chiozzi, 1996. Some geophysical constraints to dynamic processes in the southwestern Mediterranean. Annals of Geophysics, 39(6), 1185-1200.
  • Pasquale V., M. Verdoya, P. Chiozzi, 1998. Climate change from meteorological observations and underground temperatures in northern Italy. Studia geoph. et geod. 42:30-40.
  • Pasquale V., M. Verdoya, P. Chiozzi, 1999. Thermal state and deep earthquakes in the southern Tyrrhenian. Tectonophysics, 306:435-448.
  • Pasquale V., M. Verdoya, P. Chiozzi, G. Ranalli, 1997. Rheology and seismotectonic regime in the northern central Mediterranean. Tectonophysics 270: 239-257.
  • Pasquale V., M. Verdoya, P. Chiozzi, J. Safanda, 2000. Evidence of climate variability from underground temperatures in NW Italy. Global and Planetary Change, 25: 215-222.
  • Pasquale V., M. Verdoya, P. Chiozzi, R. Cabella, D. Russo, 1997. Thermophysical properties of the Lipari lavas (Southern Thyrhenian Sea). Annals of Geophysics XL (6): 1496-1503.
  • Pasquale, V., Verdoya, M., Chiozzi, P., 1996. Heat flux and timing of the drifting stage in the Ligurian-Provensal basin (northwestern Mediterranean). Journal of Geodynamics, 21(3): 205-222
  • Pasquale, V., Verdoya, M., Chiozzi, P., 1996. Some geophysical constraints to dynamic processes in the southwestern Mediterranean. Annali di Geofisica, 39(6): 1185-1200.
  • Pasquale, V., Verdoya, M., Chiozzi, P., Ranalli, G. 1997. Rheology and seismotectonic regime in the northern central Mediterranean. Tectonophysics, 270: 239-257.
  • Pfister, M. and Rybach, L., 1996, High-resolution temperature logging in shallow drillholes for the determination of terrestrial heat flow: field example and analysis, Tectonophysics, 257, 93-99
  • Pollack, H.N., 1997, Thermal characteristics of the Archean Earth, in Tectonic Evolution of Greenstone Belts, M. deWit and L. Ashwal, eds., Oxford University Press, pp.223-232.
  • Pollack, H.N., Shen, P.Y., Huang, S., 1996. Inference of ground surface temperature history from subsurface temperature data: Interpreting ensembles of borehole logs. Pure and Applied Geophysics, 147: 537-550.
  • Pollack, H.N., Shen, P.Y., Huang, S., 1996. Inference of ground surface temperature history from subsurface temperature data: Interpreting ensembles of borehole logs. Pure and Applied Geophysics, v.147, n.3, pp.537-550.
  • Roy, S., Rao, R.U.M., 2000. Heat flow in the Indian shield. J. Geophys. Res. 105, 25587-25604, doi: 10.1029/2000JB900257.
  • Roy, S., Rao, R.U.M., 1999. Geothermal investigations in the 1993 Latur earthquake area, Deccan Volcanic Province, India. Tectonophysics, 306, 237-252, doi: 10.1016/S0040-1951(99)00051-7.
  • Safanda, J., 1996. Possible effects of the thermal conductivity heterogeneity and anisotropy on the KTB temperature field. Sonderband II/1996 der Mitteilungen der DGG, 47-50.
  • Safanda, J., Cermak, V. and Bodri, L., 1997. Climate history inferred from borehole temperatures, data from the Czech Republic. Surveys in Geophysics, 18: 197-212.
  • Schellschmidt, R. and Clauser, C:, 1996. The thermal regime of the Upper Rhine graben and the anomaly of Soultz, Z. Angew. Geol., 42(1), 40-44.
  • Shen Xian-jie et al., 1996, Chapter 10: Thermal structure of the Lithosphere, in:Lithospheric Structure and Evolution of Qinghai-Tibet Plateau, Geological Publishing House, Beijing, p.114-125. (in Chinese with English abstract)
  • Shen Xian-jie, 1996, Crust-mantle Thermal Structure and Tectonothermal Evolution of the Tibetan Plateau, Science Press, Beijing, 224pp.
  • Shen Xian-jie, 1996, Plate-kinematic origin of the N-S heterogeneity of the Tibetan crust-mantle thermal structure and its dynamic implications, Continental Dynamics, Vol.1, No.1, p.38-48.
  • Shen, P.Y., Pollack, H.N., Huang, S., 1996. Inference of ground surface temperature history from borehole temperature data: A comparison of two inverse methods. Global and Planetary Change, 14, 49-57.
  • Stulc P., Golovanova I.V. and Selezniova G.V. 1997. Climate change in the Urals, Russia, inferred from borehole temperature data. Studia Geophysica et geodetica. 41: 225-246
  • Verdoya M., V. Pasquale, P. Chiozzi, 1999. Hydrothermal circulation in the Tertiary Piedmont Basin (NW Italy). Bulletin d'Hydrogéologie, 17: 123-134.
  • Verdoya M., V. Pasquale, P. Chiozzi, I.T. Kukkonen, 1998. Radiogenic heat production in the Variscan crust: new determinations and distribution models in Corsica (Northwestern Mediterranean). Tectonophysics 291: 63-75.
  • Wisian, K.W., Blackwell, D.D., Bellani, S., Henfling, J.A., Normann, R.A., Lysne, P.C., Foerster, A., and Schroetter, J., 1996, How hot is it? (A comparison of advanced technology temperature logging systems): Geothermal Resources Council Trans., v. 20, p. 427-434.
  • Yamano, M., Shevaldin, Yu.V., Zimin, P.S. and Balabashin, V.I., 1996. Heat flow of the Japan Sea. In: N. Isezaki, I.I. Bersenev et al. (Editors.), Geology and Geophysics of the Japan Sea. TERRAPUB, Tokyo, pp. 61-74.

1991-1995

  • Bodri, L. and Cermak, V., 1995. Climate change of the last millenium inferred from the borehole temperatures : results from the Czech Republic - Part I. Global Planet.Change, 11: 111-125.
  • Boulos, F.K., Cermak, V., Bodri, L. and Morgan, P., 1995. Geothermal models of the crust at some regions in Egypt, Annals Geol.Survey Egypt, Cairo, pp.417-426.
  • Cermák V., Balling N., B. Della Vedova, F. Lucazeau, V. Pasquale, G. Pellis, Schulz R., M. Verdoya, 1992. Heat-flow density. In: D. Blundell, R. Freeman St. Mueller (Editors), A Continent Revealed: The European Geotraverse, ATLAS of compiled data, pp. 49-57, Cambridge University Press, Cambridge, UK.
  • Cermak, V. 1995. Lithospheric thermal regimes in Europe. In: E.Barbier, G.Frye, E.Iglesias and G.Palmason (Eds.) Proceedings of the World Geothermal Congress, Firenze, Italy, 18-31 May 1995, IGA, Auckland, Vol.2, pp.731-735.
  • Cermak, V. and Bodri, L., 1995. Three-dimensional deep temperature modelling along the European geotraverse. Tectonophysics, 244: 1-11.
  • Cermak, V., 1995. Geothermal model of the Central segment of the EGT (Extended abstract). Tectonophysics, 244: 51-55.
  • Cermak, V., Kresl, M., Kucerova, L., Safanda, J., Frasheri, A., Kapedani, N., Lico, R. and Cano, D., 1995. Heat flow in Albania. Geothermics, 25: 91-102.
  • Clauser, C. and Mareschal, J.-C., 1995. Ground Temperature History in Central Europe from Borehole Temperature Data, Geophys. J.Int., 121(3), 805-817.
  • Clauser, C.and Huenges, E., 1995. Thermal Conductivity of Rocks and Minerals. In: T. J. Ahrens (ed.), Rock Physics and Phase Relations - a Handbook of Physical Constants, AGU Reference Shelf, Vol. 3, pp. 105-126, American Geophysical Union, Washington.
  • Della Vedova B., F. Lucazeau, V. Pasquale, G. Pellis, M. Verdoya, 1995. Heat flow in the tectonic provinces crossed by the southern segment of the European geotraverse. Tectonophysics, 244: 57-74.
  • Della Vedova, B., Lucazeau, F., Pasquale, V., Pellis, G., Verdoya, M., 1995. Heat flow in the tectonic provinces crossed by the southern segment of the European geotraverse. Tectonophysics, 244: 57-74.
  • Dragoni M., V. Pasquale, M. Verdoya, P. Chiozzi, 1993. Rheological consequences of the lithospheric thermal structure in the Fennoscandian Shield. Global and Planetary Change, 8: 113-126.
  • Foerster, A., and Merriam, D.F., 1995, A bottom-hole temperature analysis in the American Midcontinent (Kansas): implications to the applicability of BHTs in geothermal studies: World Geothermal Congress 1995 (Florence, Italy), Proc., v. 2, p. 777-782.
  • Gupta, M.L. and Yamano, M. (editors), 1995. Terrestrial Heat Flow and Geothermal Energy in Asia. Oxford & IBH Publishing Co., New Dehli, 516 pp.
  • Gupta, M.L., 1993. Is the Indian Shield hotter than other Gondwana shields? Earth Planet. Sci. Lett., 115, 275-285, doi: 10.1016/0012-821X(93)90227-Z.
  • Gupta, M.L., 1995. Thermal regime of the Indian shield. In: Gupta, M.L., Yamano, M., (Eds.), Terrestrial heat flow and geothermal energy in Asia. Oxford & IBH, 63-81.
  • Gupta, M.L., Sharma, S.R., Sundar, A., 1991. Heat flow and heat generation in the Archaean Dharwar cratons and implications for the Southern Indian shield geotherm and lithospheric thickness. Tectonophysics, 194, 107-122, doi: 10.1016/0040-1951(91)90275-W.
  • Gupta, M.L., Sundar, A., Sharma, S.R., Singh, S.B., 1993. Heat flow in the Bastar Craton, central Indian shield: Implications for thermal characteristics of Proterozoic cratons. Phys. Earth Planet. Inter., 78, 23-31, doi:10.1016/0031-9201(93)90081-J. Huang, S., Pollack, H.N., Shen, P. Y. and Wang, J.-Y., 1995. Reading paleoclimate from borehole temperature profiles: Principles and examples from North America and Southwest China. Quaternary Sciences, No. 3, 213-222 (in Chinese with English Abstract).
  • Huang, S., Pollack, H.N., Wang, J.-Y. and Cermak, V., 1995. Ground surface temperature histories inverted from subsurface temperatures of two borehole located in Panxi, SW China. Journal of Southeast Asian Earth Sciences , 12: 113-120.
  • Hurter, S., Huenges, E., Clauser, C. and Haenel, R., 1995. Atlas of Geothermal Resources in Europe, In: E. Barbier, G. Frye, E. Iglesias G. Palmason (eds.), Proceedings of the World Geothermal Congress, 1995, May 18-31, Firenze, Vol. 1, pp. 611-612, International Geothermal Association, Auckland.
  • Hyndman, R.D., Wang, K. and Yamano, M., 1995. Thermal constraints on the seismogenic portion of the southwestern Japan subduction thrust. J. Geophys. Res., 100: 15373-15392.
  • Jobmann, M. and Clauser, C., 1994. Heat Advection Versus Conduction at the KTB: Possible Reasons for Vertical Variations in Heat Flow Density. Geophys. J. Int., 119(1): 44-68.
  • Kinoshita, M. and Yamano, M., 1995. Heat flow distribution in the Nankai Trough region. In: H. Tokuyama, S. Shcheka et al. (Editors.), Geology and Geophysics of the Philippine Sea. TERRAPUB, Tokyo, pp. 77- 86.
  • Kolditz, O., Clauser, C., Schellschmidt, R. and Schulz, R., 1995. Modelling Flow and Heat Transfer in Fractured Rocks: Application on Heat Extraction From Hot Dry Rocks, In: E. Barbier, G. Frye, E. Iglesias and G. Palmason (eds.), Proceedings of the World Geothermal Congress, 1995, May 18-31, Firenze, Vol. 3, pp. 2575-2580, International Geothermal Association, Auckland.
  • Kosakowski, G., Clauser, C.and Neugebauer, H. J., 1994. Simulation of Fluid and Heat Transport in Variscan Rocks: From the Natural Fracture System to the Numerical Network. Terra Nostra, Schriften der Alfred- Wegener-Stiftung, 3/94, 66-69.
  • Kukkonen, I. T. and Clauser, C., 1994. Simulation of Heat Transfer at the Kola Deep-Hole Site - Implications for Advection, Heat Refraction and Palaeoclimatic Effects. Geophys. J. Int., 116(2): 409-420.
  • Pasquale V., M, Verdoya, P. Chiozzi, 1994. Types of crust beneath the Ligurian Sea. Terra Nova, 6: 255-266.
  • Pasquale V., M. Verdoya, P. Chiozzi, 1991. Lithospheric thermal structure in the Baltic shield. Geophys. J. Int., 106: pp. 611-620.
  • Pasquale V., M. Verdoya, P. Chiozzi, 1993. Thermal effects of the dynamic activity from the Ligurian Sea to the Eastern Alps. Annals of Geophysics, 36(5): 91-104.
  • Pasquale V., M. Verdoya, P. Chiozzi, 1995. On the heat flux related to stretching in the NW-Mediterranean continental margins. Studia Geophysica et Geodaetica, 39: 1-16.
  • Pasquale V., M. Verdoya, P. Chiozzi, 1995. Rifting and thermal evolution of the Northwestern Mediterranean. Annals of Geophysics, 38(1): 43-53.
  • Pasquale V., M. Verdoya, P. Chiozzi, P. Augliera, 1993. Dependence of the seismotectonic regime on the thermal state in the northern Italian Apennines. Tectonophysics, 217: 31-41.
  • Pasquale, V., Verdoya, M., Chiozzi, P., 1995. On the heat flux related to stretching in the NW-Mediterranean continental margins. Studia Geophysica et Geodaetica, 39: 1-16.
  • Pasquale, V., Verdoya, M., Chiozzi, P., 1995. Rifting and thermal evolution of the Northwestern Mediterranean. Annali di Geofisica, 38(1): 43-53.
  • Pfister, M. and Rybach, L., 1995, High resolution temperature logging in areas with significant convective heat transfer, Geothermics, Vol. 24, No. 1, 95-100
  • Safanda, J. and Wilhelm, H., 1995. Unexpected features of KTB temperature logs and their possible explanation. Scientific Drilling, 5, 129-134.
  • Safanda, J., 1995. Effect of thermal conductivity anisotropy of rocks on the subsurface temperature field. Geoph.J.Int., 120, Nr.2, 323-330.
  • Safanda, J., Kresl, M., Cermak, V., Hasanean, A.R.G., Deebes, H.A., Abd-Alla, M.A. and Moustafa, S.M., 1995. Subsurface temperature measurements and terrestrial heat flow estimates in the Aswan region, Egypt. Stud.geoph.geod., 39: 162-176.
  • Shen Xian-jie et al., 1995, Controlling mechanism of sedimentation- burial history on oil-gas maturation history, Science in China, Vol.38, No.5, p.619-631.
  • Shen Xian-jie et al., 1995, Golmud-Erjin heat flow profile and straightforward calculation of the crust-mantle temperature, Chinese Science Bulletin, Vol.40, No.10, p.830-838.
  • Shen Xian-jie et al., 1995, Heat flow study and analysis along the Golmud-Ejin Qi Geotransect, Acta Geophysica Sinica, Vol.38, Suppl.II, p.86-97. (in Chinese with English abstract)
  • Shen Xian-jie et al., 1995, Oil-gas perspective of the Caidam Basin predicted by the results of network-type basin simulation, Acta Geophysica Sinica, Vol.38, No.1, p.83-92. (in Chinese with English abstract)
  • Shen, P.Y., Pollack, H.N., Huang, S. and Wang, K., 1995. Effects of subsurface heterogeneity on the inference of climate change from borehole temperature data: model studies and field examples from Canada. J. Geophys. Res., 100, 6383-6396
  • Wang Jiyang, Huang Shaopeng, and Chen Moxiang, 1996. The Terrestrial eat flow. In Yuan Xuecheng (Chief Compiler), Atlas of Geophysics in China (Publication No.201 of the International Lithosphere Program), Geological Publishing House, Beijing, p.101-103.
  • Wang, K., Hyndman, R.D. and Yamano, M., 1995. Thermal regime of the Southwest Japan subduction zone: effects of age history of the subducting plate. Tectonophysics, 248: 53-69.
  • Yamano, M. and Kinoshita, M., 1995. Heat flow in the Philippine Sea. In: H. Tokuyama, S. Shcheka et al. (Editors.), Geology and Geophysics of the Philippine Sea. TERRAPUB, Tokyo, pp. 59-75.
  • Yamano, M., 1995. Recent heat flow studies in and around Japan. In: M.L. Gupta and M. Yamano (Editors), Terrestrial Heat Flow and Geothermal Energy in Asia. Oxford & IBH Publishing Co., New Dehli, pp. 173-201.

1986-1990

  • Gupta, M.L., Sharma, S.R., Sundar, A., Singh, S.B., 1987. Geothermal studies in the Hyderabad granitic region and the crustal thermal structures of the southern Indian shield. Tectonophysics, 140, 257-264, doi:10.1016/0040-1951(87)90233-2.
  • Pasquale V., C. Cabella, M. Verdoya, 1990. Deep temperatures and lithospheric thickness along the European Geotraverse. Tectonophysics, 176: pp. 1-11.
  • Pasquale V., M. Verdoya, 1990. Geothermal regime of the Po Basin, Italy. Mém. Soc. Géol. Fr., Paris, 156; Mém Soc. géol. suisse, Zürich, 1; Vol. spec Soc. Geol. It., Roma, 1: pp. 135-143.
  • Sundar, A., Gupta, M.L., Sharma, S.R., 1990. Heat flow in the Trans-Aravalli igneous suite, Tusham, India. J. Geodyn., 12, 89-100, doi: 10.1016/0264-3707(90)90025-P.

1981-1985

  • Gupta, M.L., 1981. Surface heat flow and igneous intrusion in the Cambay basin, India. J. Volcanol. Geotherm. Res., 10, 279-292, doi:10.1016/0377-0273(81)90080-9.
  • Gupta, M.L., Gaur, V. K., 1984. Surface heat flow and probable evolution of Deccan Volcanism. Tectonophysics, 105, 309-318, doi:10.1016/0040-1951(84)90210-5.
  • Rao, G.V., Rao, R.U.M., 1983. Heat flow in the Indian Gondwana basins and heat production of their basement rocks. Tectonophysics, 91, 105-117, doi: 10.1016/0040-1951(83)90060-4.
  • Rao, R.U.M., Rao, G.V., Reddy, G.K., 1982. Age dependence of continental heat flow - fantasy and facts. Earth and Planetary Science Letters, 59 (2), 288-302, doi: 10.1016/0012-821X(82)90132-7.
  • Rao, R.U.M., 1983. Comments on "Heat flow studies: constraints on the distribution of uranium, thorium and potassium in the continental crust" by C. Jaupart, J.G. Sclater and G. Simmons. Earth and Planetary Science Letters, 62 (3), 418-429, 10.1016/0012-821X(83)90012-2.

1976-1980

  • Rao, G.V., Rao, R.U.M., 1980. A geothermal study of the Jharia Gondwana Basin (India): heat flow results from several holes and heat production of basement rocks. Earth Plan. Sci. Lett., 48, 397-405, doi: 10.1016/0012-821X(80)90204-6.
  • Rao, R.U.M., Rao, G.V., Narain, H., 1976. Radioactive heat generation and heat flow in the Indian shield. Earth Planet. Sci. Lett., 30, 57-64, doi: 10.1016/0012-821X(76)90008-X.

1971-1975

  • Rao, R.U.M., Rao, G.V., 1974. Results of some geothermal studies in Singhbhum thrust belt, India. Geothermics, 3, 153-161, doi:[10.1016/ 0375-6505(74)90014-5](http://dx.doi.org/10.1016/ 0375-6505(74)90014-5).
  • Rao, R.U.M., 1974. Gamma-ray spectrometric set up at NGRI for analysis of U, Th and K in rocks. Geophys. Res. Bull., 12, 2&3, 91-101.

1966-1970

  • Gupta, M.L., Verma, R.K., Hamza, V.M., Rao, G.V., Rao., R.U.M., 1970. Terrestrial heat flow and tectonics of the Cambay basin, Gujarat state, India. Tectonophysics, 10, 147-163, doi:10.1016/0040-1951(70)90104-6.
  • Gupta, M.L., Verma, R.K., Rao, R.U.M., Hamza, V.M., Rao, G.V., 1967. Terrestrial heat flow in the Khetri copper belt, Rajasthan, India. J. Geophys. Res., 72, 4215-4220, doi:10.1029/JZ072i016p04215.
  • Rao, R.U.M., Verma, R.K., Rao, G.V., Hamza, V.M., Gupta, M.L., 1970a. Heat flow at Damua and Mohapani, Satpura Gondwana Basin, India. Earth Planet. Sci. Lett., 7, 406-412, doi:[10.1016/0012-821X(70) 90082-8](http://dx.doi.org/10.1016/0012-821X(70) 90082-8).
  • Rao, R.U.M., Verma, R.K., Rao, G.V., Hamza, V.M., Panda, P.K., Gupta, M.L., 1970b. Heat flow studies in the Godavari Valley, India. Tectonophysics, 10, 165-181, doi:10.1016/0040-1951(70)90105-8.
  • Verma, R.K., Rao, R.U.M., Gupta, M.L., 1966. Terrestrial heat flow in Mosabani mine, Singbhum district, Bihar. J. Geophys. Res., 71, 4943-4948, doi: 10.1029/JZ071i020p04943.

1961-1965

  • Verma, R.K., Rao, R.U.M., 1965. Terrestial heat flow in Kolar Gold Field, India. J. Geophys. Res., 70, 1353-1356, doi: 10.1029/JZ070i006p01353.

1956-1960