The GEISA-2011 sub-database on Microphysical and Optical
Properties of Atmospheric Aerosols


1. Biermann, U.M., Luo, B.P., and Peter, Th., “Absorption Spectra and Optical Constants of Binary and Ternary Solutions of H2SO4, HNO3, and H2O in the Mid Infrared at Atmospheric Temperatures”, J.Phys.Chem. A 104, 783-793 (2000).

2. Carlson, T.N. and Benjamin ST.G., “Radiative heating rates for saharan dust”. J.Atmos.Sc. 193-213 (1980).

3. Clapp, M.L., Miller, R.E. and Worsnop, D.R., “Frequency-Dependent Optical Constants of Water Ice Obtained Directly from Aerosol Extinction Spectra”, J.Phys.Chem. 99, 6317-6326 (1995).

4. Dorsey, N.E., “Properties of ordinary water-substance in all its phases: water vapor and all the ices”, American Chemistry Society, Monograph Series, Reinhold Publishing Corp., New York, NY, 332-338 (1940).

5. Downing H.D., and Williams, D., “Optical constants of water in the infrared”, J.Geophys.Res., 80, 1656-1661 (1975).

6. Drummond, D. G. (1936) Absorption coefficients of crystalquartz in the infrared, Proc. Roy. Soc. (London)-Series A, 153:328-338.

7. Eldridge, J.E. and Palik, E.D., “Sodium Chloride”, in “Handbook of Optical Constants of Solids”, Edited by E.D. Palik, Academic Press, Inc., Orlando, FL, 775-793 (1985).

8. Fenn, R.W., Clough, S.A., Gallery, W.O., Good, R.E., Kneizys, F.X., Mill, J.D., Rothman, L.S. and Shettle, E.P.,”Optical and infrared properties of the atmosphere”, Chapter 18 in Handbook of Geophysics and the Space Environment, Edited by A.S. Jursa, Air Force Geophysics Laboratory, Hanscom AFB, MA (1985).

9. Gray, D. C., “American Institute of Physics Handbook”, McGraw-Hill, New York, NY, 1963, 2nd Edition.

10. Hale, G.M. and Querry, M.R., “Optical constants of water in the 200 mm to 200 µm wavelength region”, Appl.Opt.,12, 555-563 (1973)

11. Hummel, J.R., Shettle, E.P. and Longtin, D.R., “A New Background Stratospheric Aerosol Model for Use in Atmospheric Radiation Models”, AFGL-TR-88-0166, Air Force Geophysics Laboratory, Hanscom AFB, MA, August (1988).

12. Kou L., Labrie D., and Chylek P., “Refractive indices of water and ice in the 0.65 to 2.5 micron range”, Appl.Opt., 32, 3531-3540 (1993).

13. Longtin, D.R., Shettle, E.P., Hummel, J.R. and Pryce, J.D., “A Wind Dependent Desert Aerosol Model: Radiative Properties”, AFGL-TR-88-0112, Air Force Geophysics Laboratory, Hanscom AFB, MA, April 1988.

14. Niedziela, R.F., Norman, M.L., de Forest, C.L., Miller, R.E. and Worsnop, D.R., “A Temperature and Composition-Dependent Study of H2SO4 Aerosol Optical Constants Using Fourier Transform and Tunable Diode Laser Infrared Spectroscopy”, J.Phys.Chem. A, 103, 8030-8040 (1999).

15. Norman, M.L., Qian J., Miller, R.E., Worsnop, D.R., “Infrared complex indices of supercooled liquid HNO3/H2O aerosols”, J.Geophys.Res. 104, 30571-30584 (1999).

16. Norman, M.L., Miller, R.E. and Worsnop, D.R., “Ternary H2SO4/HNO3/H2O Optical Constants: New Measurements from Aerosol Spectroscopy under Stratospheric Conditions”, J.Phys.Chem. A, 106, 6075-6083 (2002).

17. Palmer K.F. and Williams, D., “Optical constants of sulfuric acid: Application to the clouds of Venus”, Appl.Opt., 14, 208-219 (1975).

18. Philipp, H. R., “Silicon dioxide (SiO2), type-(crystalline)”, in “Handbook of Optical Constants of Solids”, Edited by E. D. Palik, Academic Press, Inc., Orlando, FL, 719-747 (1985).

19. Querry, M.R., and Tyler, I.L., “Reflectance and complex refractive indices in the infrared of aqueous solutions of nitric acid”, J.Chem.Phys. 72, 2495-2499 (1980).

20. Ray, P. S., “Broadband complex refractive indices of ice and water”, Appl.Opt., 11,1836-1844 (1972).

21. Remsberg E.E., Lavery D., and Crawford B., “Optical constants for sulfuric and nitric acids”, J.Chem. and Engin.Data, 19, 263-255 (1974).

22. Richwine, L.J., Clapp, M.L., Miller, R.E. and Worsnop, D.R., “Complex refractive indices in the infrared of nitric acid trihydrate aerosols”, Geo.Res.Lett. 22, 2625-2628 (1995).

23. Shettle, E.P. and Fenn, R.W., “Models for the Aerosols of the Lower Atmosphere and the effects of Humidity Variations on their Optical Properties”, AFGL-TR-79-0214, 20 Sept 1979, ADA085951.

24. Sokolik, I.N., A. Andronova, and T.C. Johnson, “Complex refractive index of atmospheric dust aerosols”, Atmos. Env., 27A, 2495-2502 (1993).

25. Spitzer, W. G. and Kleinman, D. A. (1961) Infrared lattice bands of quartz, Phys. Rev., 121:1324-1335.

26. Tisdale, R.T., Glandorf, D.L., Tolbert, M.A. and Toon O.B., “Infrared optical constants of low temperature H2SO4 solutions representative of stratospheric sulfate aerosols”, J.Geophys.Res. 103, 25353-25370 (1998).

27. Toon, O.B., Pollock, J.B. and Khare, B.N., “The optical constants of several atmospheric aerosols species: ammonium sulfate, aluminum oxide and sodium chloride”, J.Geophys. Res., 81, 5733-5748 (1976).

28. Toon O.B., Tolbert M.A., Koehler B.C., Middlebrook A.M., and Jordan J., “The infrared optical constants of H2O-ice, amorphous nitric acid solutions, and nitric acid hydrates”, J.Geophys.Res., 99, 25631-25654 (1994)

29. Twitty, J.T. and Weinman, J.A., “Radiative properties of carbonaceous aerosols”, J.Appl.Meteor., 10, 725-731 (1971).

30. Volz F.E., “Infrared refractive index of atmospheric aerosol substances”, Appl.Optics, 11, 755-759 (1972a).

31. Volz, F.E., “Infrared absorption by atmospheric aerosol substance”, J. Geophys. Res., 77, 1017-1031 (1972b).

32. Volz F.E., “Infrared optical constants of ammonium sulfate, Sahara dust; volcanic pumice and flyash”, Appl.Optics., 12, 564-568 (1973).

33. Warren S.G., “Optical constants of ice from the ultraviolet to the microwave”, Appl.Opt., 23, 1206-1225 (1984).