|
|
Regular Research Article 10 Dec 2013 Related subject areaGeophysics/Geology - Apparent relations between planetary spin, orbit, and solar differential rotation (16 Dec 2013)
R. Tattersall
Pattern Recogn. Phys., 1, 199-202, 2013 - The sunspot cycle length – modulated by planets? (04 Dec 2013)
J.-E. Solheim
Pattern Recogn. Phys., 1, 159-164, 2013 - Multiscale comparative spectral analysis of satellite total solar irradiance measurements from 2003 to 2013 reveals a planetary modulation of solar activity and its nonlinear dependence on the 11 yr solar cycle (25 Nov 2013)
N. Scafetta and R. C. Willson
Pattern Recogn. Phys., 1, 123-133, 2013 - Reply to Benestad's comment on "Discussions on common errors in analyzing sea level accelerations, solar trends and global warming" by Scafetta (2013) (24 Sep 2013)
N. Scafetta
Pattern Recogn. Phys., 1, 105-106, 2013 - Patterns in seismology and palaeoseismology, and their application in long-term hazard assessments – the Swedish case in view of nuclear waste management (24 Jul 2013)
N.-A. Mörner
Pattern Recogn. Phys., 1, 75-89, 2013 - Discussion on common errors in analyzing sea level accelerations, solar trends and global warming (13 May 2013)
N. Scafetta
Pattern Recogn. Phys., 1, 37-57, 2013 - Regional pattern of the earth's crust dislocations on the territory of Bulgaria inferred from gravity data and its recognition in the spatial distribution of seismicity (29 Apr 2013)
P. Trifonova, D. Solakov, S. Simeonova, M. Metodiev, and P. Stavrev
Pattern Recogn. Phys., 1, 25-36, 2013 - Natural oscillations and trends in long-term tide gauge records from the Pacific (08 Mar 2013)
A. Parker
Pattern Recogn. Phys., 1, 11-23, 2013 - Pattern recognition of structural boundaries from aeromagnetic data using the 2-D continuous wavelet transform and the 3-D analytic signal (05 Mar 2013)
S.-A. Ouadfeul and L. Aliouane
Pattern Recogn. Phys., 1, 1-9, 2013 - More Articles (4)
Cited articles- Abdusamatov, Kh. I.: Optimal Prediction of the Peak of the Next 11-Year Activity Cycle and of the Peaks of Several Succeding Cycles on the Basis of Long-Term Variations in the Solar Radius or Solar Constant, Kinemat. Phys. Celest., 23, 97–100, 2007 (in Russian).
- Abreu, J. A., Beer, J., Ferriz-Mas, A., McCracken, K. G., and Steinhilber, F.: Is there a planetary influence on solar activity? Astron. Astrophys., 548, A88, doi:10.1051/0004-6361/201219997, 2012.
- Bond, G., Kromer, B., Beer, J., Muscheler, R., Evans, M. N., Showers, W., Hoffmann, S., Lotti-Bond, R., Hajdas, I., and Bonani, G.: Persistent solar influence on North Atlantic climate during the Holocene, Science, 294, 2130–2136, 2001.
- Charvátová, I.: Can origin of the 2400-year cycle of solar activity be caused by solar inertial motion?, Ann. Geophys., 18, 399–405, doi:10.1007/s00585-000-0399-x, 2000.
- de Jager, C. and Versteegh, J. M.: Do planetary Motions Drive Solar Variability?, Sol. Phys., 229, 175–179, 2005.
- Holgate, S. J.: On the decadal rates of sea level change during the twentieth century, Geophys. Res. Lett., 34, L01602, doi:10.1029/2006GL028492, 2007.
- Humlum, O., Solheim, J.-E., and Stordahl, K.: Identifying natural contributions to late Holocene climate change, Global Planet Change, 79, 145–156, doi:10.1016/j.gloplacha.2011.09.005, 2011.
- Jose, P. D.: Sun's Motion and Sunspots, Astron. J., 70, 193–200, 1965.
- Konstantinov, A. N., Ostryakov, V. M., and Stupneva, A. V.: Solar activity and tree ring widths, Solar Data (Solnechnye Dannye), 2, 84–89, 1986 (in Russian).
- Le Moël, J.-L., Blanter, E., Shnirman, M., and Courtillot, V.: Solar forcing of the semi-annual variation of length-of-day, Geophys. Res. Lett, 37, L15307, doi:10.1029/2010GL043185, 2010.
- McCracken, K. G., Beer, J., Steinhilber, F., and Abreu, J.: A phenomenological study of the cosmic ray variations over the past 9400 years, and their implications regarding solar activity and the solar dynamo, Sol. Phys., 286, 609–627, 2013.
- Mörner, N.-A.: Arctic Environment by the middle of this century, Energ. Environ., 22, 207–218, 2011.
- Mörner, N.-A.: Planetary beat and solar–terrestrial responses, Pattern Recogn. Phys., 1, 107–116, doi:10.5194/prp-1-107-2013, 2013a.
- Mörner, N.-A.: Sea level changes: past records and future expectations, Energ. Environ., 24, 509–536, 2013b.
- Ogurtsov, M. G., Jungner, H., Kocharov, G. E., Lindholm, M., Eronen, M., and Nagovitsyn, Yu. A.: On the link between Northern Fennoscandian climate and length of the quasi-eleven-years cycle in Galactic Cosmic Ray Flux, Sol. Phys., 218, 245–357, 2003.
- Richards, M. T., Rogers, M. L., and Richard, D. St. P.: Long-Term variability in the Length of the Solar Cycle, Publ. Astron. Soc. Pac., 121, 797–809, 2009.
- Scafetta, N.: Empirical evidence for a celestial origin of the climate oscillations and its implications, J. Atmos. Sol.-Terr. Phy., 72, 951–970, 2010.
- Scafetta, N.: Does the Sun work as a nuclear fusion amplifier of planetary tidal forcing? A proposal for a physical mechanism based on the mass-luminosity relation, J. Atmos. Sol.-Terr. Phy., 81–-82, 27–40, 2012.
- Scafetta, N.: Multi-scale harmonic model for solar and climate cyclical variation throughout the Holocene based on Jupiter-Saturn tidal frequencies plus the 11-year solar dynamo cycle, J. Atmos. Sol.-Terr. Phy., 80, 296–311, 2012b.
- Scafetta, N.: A shared frequency set between the historical mid-latitude aurora records and the global surface temperature, J. Atmos. Sol.-Terr. Phy., 74, 45–163, 2012c.
- Scafetta, N.: Solar and Planetary Oscillation control on climate change hind-cast, forecast and an comparison with the CMIP5 GCMs, Energ. Environ., 42, 455–496, 2013a.
- Scafetta, N.: Discussion on climate oscillations: CMIP5 general circulation models versus a semi-empirical harmonic model based on astronomical cycles, Earth-Sci. Rev., 126, 321–357, 2013b.
- Scafetta, N. and Willson, R. C.: Empirical eveidences for a planetary modulation of total solar irradiance and the TSI signature of the 1.09-year Earth-Jupiter conjunction cycle, Astrophys. Space. Sci., doi:10.1007/s10509-013-1558-3, in press, 2013a.
- Scafetta, N. and Willson, R. C.: Multiscale comparative spectral analysis of satellite total solar irradiance measurements from 2003 to 2013 reveals a planetary modulation of solar activity and its nonlinear dependence on the 11 yr solar cycle, Pattern Recogn. Phys., 1, 123–133, doi:10.5194/prp-1-123-2013, 2013.b.
- Shaviv, N. J.: Using the oceans as a calorimeter to quantify the solar radiative forcing, J. Geophys. Res., 113, A11101, doi:1029/2007JA012989, 2008.
- Solheim, J.-E.: The sunspot cycle length – modulated byplanets?, Pattern Recogn. Phys., in preparation, 2013.
- Stauning, F.: Solar activity-climate relations: A different approach, J. Atmos. Sol.-Terr. Phy., 75, 1999–2012, 2011.
- Steinhilber, F., Beer, J., and Fröhlich, C.: Total solar irradiance during the Holocene, Geophys. Res. Lett., 36, L19704, doi:10.1029/2009GL040142, 2009.
- Stozhkov, Yu. I., Svirzhevsky, N. S., Bazilevskaya, G. A., Svirzhevskaya, A. K., Kvashnin, A. N., Krainev, M. B., Makhmutov, V. S., and Klochkova, T. I.: Fluxes of cosmic rays in the maximum of absorption curve in the atmosphere and at the atmosphere boundary (1957–2007), Preprint of FIAN No. 14, Moscow, FIAN, 77c, 2007.
- Stozhkov, Yu. I., Svirzhevsky, N. S., Bazilevskaya, G. A., Kvashnin, A. N., Makhmutov, V. S., and Svirzhevskaya, A. K.: Long-term (50 year) measurements of cosmic ray fluxes in the atmosphere, Adv. Space. Res., 44, 1124–1137, 2009.
- Svensmark, H. and Friis-Christensen, E.: Variation of cosmic ray flux and global cloud coverage – a missing link in solar-climate relationships, J. Atmos. Sol.-Terr. Phy., 59, 1225–1232, 1997.
- Svensmark, H., Enghoff, M. B., and Pedersen, J. O. P.: Response of cloud condensation nuclei (> 50 nm) to changes in ion-nucleation, Phys. Lett. A, 377, 2343–2347, 2013.
- Tattersall, R.: Apparent relations between Earth's length of day and the motion of the gas giant planets, Pattern Recogn. Phys., in press, 2013.
- Tinsley, B. A., Burns, G. B., and Zhou, L.: The role of the global electric circuit in solar and internal forcing of clouds and climate, Adv. Space. Res., 40, 1126–1139, 2007.
- Wilson, I. R. G.: The Venus–Earth–Jupiter spin–orbit coupling model, Pattern Recogn. Phys., 1, 147–158, doi:10.5194/prp-1-147-2013, 2013.
- Yndestad, H., Turell, W. R., and Ozhigin, V.: Lunar nodal tide effects on variability of sea level, temperature, and salinity in the Faroe-Shetland Channel and the Barents Sea, Deep-Sea Res. Pt. I, 55, 1201–1217, 2008.
- More Articles (31)
|
|