RollingThunder
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- Mar 22, 2010
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- #121
That's part of your insanity, SSoooooDDuuuumb. In reality, every time anybody argues with you, they counter your delusional claims and moronic pseudo-science with the actual facts and kick your sorry, retarded ass to the curb. You're insanely delusional though, so you foolishly imagine that you've 'won'. You end up looking like the brainless denier cult nutjob that you are.Poor SSDD's pseudoscience is so loony, even the mainstream deniers don't want anything to do with it. These days, he's usually jabbering the kookery of the Sky Dragons from Principia Scientific International, a splitoff denier group so wacky that they've been banned from WUWT. Given the degree of craziness that WUWT embraces, getting banned there takes supersized insanity, stuff at the level of the "There's no such thing as backradiation!" conspiracy theories.
And yet, every time you try to argue with me, you end up looking like the bitter old idiot that you are.
The fact that you have your head jammed so far up your own ass that you can't see the enormous amounts of scientific evidence and research that supports AGW, is just part of your delusional insanity.And feel free to show any observed, measured back radiation at ambient temperature. Want to try and claim that FLIR is looking at back radiation again?
CO2 absorption of infrared (IR), theory:
*Kouzov, A. P., & Chrysos, M. (2009). Collision-induced absorption by CO 2 in the far infrared: Analysis of leading-order moments and interpretation of the experiment. Physical Review A, 80(4), 042703.
*Chrysos, M., Kouzov, A. P., Egorova, N. I., & Rachet, F. (2008 ). Exact Low-Order Classical Moments in Collision-Induced Bands by Linear Rotors: CO 2-CO 2. Physical review letters, 100(13), 133007.
*Buldyreva, J., & Chrysos, M. (2001). Semiclassical modeling of infrared pressure-broadened linewidths: A comparative analysis in CO2–Ar at various temperatures. The Journal of Chemical Physics, 115(16), 7436-7441.
*Kratz, D. P., Gao, B. C., & Kiehl, J. T. (1991). A study of the radiative effects of the 9.4‐and 10.4‐micron bands of carbon dioxide. Journal of Geophysical Research: Atmospheres (1984–2012), 96(D5), 9021-9026.
*Stull, V. R., Wyatt, P. J., & Plass, G. N. (1964). The infrared transmittance of carbon dioxide. Applied Optics, 3(2), 243-254.
CO2 absorption of IR, laboratory measurements:
*R.A. Toth, et al., Spectroscopic database of CO2 line parameters: 4300–7000 cm−1, Journal of Quantitative Spectroscopy and Radiative Transfer, 109:6, April 2008, 906-921.
*Predoi-Cross, A., Unni, A. V., Liu, W., Schofield, I., Holladay, C., McKellar, A. R. W., & Hurtmans, D. (2007). Line shape parameters measurement and computations for self-broadened carbon dioxide transitions in the 30012← 00001 and 30013← 00001 bands, line mixing, and speed dependence. Journal of molecular spectroscopy, 245(1), 34-51.
*Miller, C. E., & Brown, L. R. (2004). Near infrared spectroscopy of carbon dioxide I. 16 O 12 C 16 O line positions. Journal of molecular spectroscopy, 228(2), 329-354.
*Niro, F., Boulet, C., & Hartmann, J. M. (2004). Spectra calculations in central and wing regions of CO 2 IR bands between 10 and 20μm. I: model and laboratory measurements. Journal of Quantitative Spectroscopy and Radiative Transfer, 88(4), 483-498.
*Benec'h, S., Rachet, F., Chrysos, M., Buldyreva, J., & Bonamy, L. (2002). On far‐wing Raman profiles by CO2. Journal of Raman Spectroscopy, 33(11‐12), 934-940.
Earth's upward emission of IR:
*Murphy, D. M., Solomon, S., Portmann, R. W., Rosenlof, K. H., Forster, P. M., & Wong, T. (2009). An observationally based energy balance for the Earth since 1950. Journal of Geophysical Research: Atmospheres (1984–2012), 114(D17).
*Trenberth, K. E., Fasullo, J. T., & Kiehl, J. (2009). Earth's global energy budget. Bulletin of the American Meteorological Society, 90(3).
*Wong, T., Wielicki, B. A., Lee III, R. B., Smith, G. L., Bush, K. A., & Willis, J. K. (2006). Reexamination of the observed decadal variability of the earth radiation budget using altitude-corrected ERBE/ERBS nonscanner WFOV data. Journal of Climate, 19(16).
*Harries, J. E. (2000). Physics of the Earth's radiative energy balance. Contemporary Physics, 41(5), 309-322.
*Kyle, H. L., Arking, A., Hickey, J. R., Ardanuy, P. E., Jacobowitz, H., Stowe, L. L., ... & Smith, G. L. (1993). The Nimbus Earth radiation budget (ERB) experiment: 1975 to 1992. Bulletin of the American Meteorological Society, 74(5), 815-830.
*Barkstrom, B. R. (1984). The earth radiation budget experiment (ERBE). Bulletin of the American Meteorological Society, 65(11), 1170-1185.
Changes in Earth's upward IR emission as a result of increased CO2 in the atmosphere:
*Gastineau, G., Soden, B. J., Jackson, D. L., & O'Dell, C. W. (2014). Satellite-Based Reconstruction of the Tropical Oceanic Clear-Sky Outgoing Longwave Radiation and Comparison with Climate Models. Journal of Climate, 27(2).
*Chapman, D., Nguyen, P., & Halem, M. (2013, May). A decade of measured greenhouse forcings from AIRS. In SPIE Defense, Security, and Sensing (pp. 874313-874313). International Society for Optics and Photonics.
*Chen, C., Harries, J., Brindley, H., & Ringer, M. (2007). Spectral signatures of climate change in the Earth's infrared spectrum between 1970 and 2006. Retrieved October, 13, 2009.
*Griggs, J. A., & Harries, J. E. (2007). Comparison of Spectrally Resolved Outgoing Longwave Radiation over the Tropical Pacific between 1970 and 2003 Using IRIS, IMG, and AIRS. Journal of climate, 20(15).
*Griggs, J. A., & Harries, J. E. (2004, November). Comparison of spectrally resolved outgoing longwave data between 1970 and present. In Optical Science and Technology, the SPIE 49th Annual Meeting (pp. 164-174). International Society for Optics and Photonics.
Changes in downwelling infrared from the atmosphere as a result of increased CO2:
*Wang, K., & Liang, S. (2009). Global atmospheric downward longwave radiation over land surface under all‐sky conditions from 1973 to 2008. Journal of Geophysical Research: Atmospheres (1984–2012), 114(D19).
*Wild, M., Grieser, J., & Schär, C. (2008 ). Combined surface solar brightening and increasing greenhouse effect support recent intensification of the global land‐based hydrological cycle. Geophysical Research Letters, 35(17).
*Prata, F. (2008 ). The climatological record of clear‐sky longwave radiation at the Earth's surface: evidence for water vapour feedback?. International Journal of Remote Sensing, 29(17-18 ), 5247-5263.
*Allan, R. P. (2006). Variability in clear‐sky longwave radiative cooling of the atmosphere. Journal of Geophysical Research: Atmospheres (1984–2012), 111(D22).
*Philipona, R., Dürr, B., Marty, C., Ohmura, A., & Wild, M. (2004). Radiative forcing‐measured at Earth's surface‐corroborate the increasing greenhouse effect. Geophysical Research Letters, 31(3).
Formal determination of CO2-temperature causality:
* Attanasio, A., Pasini, A., & Triacca, U. (2013). Granger Causality Analyses for Climatic Attribution. Atmospheric and Climate Sciences, 3, 515.
* Attanasio, A. (2012). Testing for linear Granger causality from natural/anthropogenic forcings to global temperature anomalies. Theoretical and Applied Climatology, 110(1-2), 281-289.
* Attanasio, A., Pasini, A., & Triacca, U. (2012). A contribution to attribution of recent global warming by out‐of‐sample Granger causality analysis. Atmospheric Science Letters, 13(1), 67-72.
* Kodra, E., Chatterjee, S., & Ganguly, A. R. (2011). Exploring Granger causality between global average observed time series of carbon dioxide and temperature. Theoretical and applied climatology, 104(3-4), 325-335.
* Verdes, P. F. (2005). Assessing causality from multivariate time series. PHYSICAL REVIEW-SERIES E-, 72(2), 026222.
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