Geoscience Reference
In-Depth Information
References
Aiken, G., McKnight, D., Harnish, R., and Wershaw, R. (1996), Geochemistry of aquatic
humic substances in the Lake Fryxell Basin, Antarctica.
Biogeochemistry
,
34
(3),
157-188.
Akagi, J., Zsolnay, A., and Bastida, F. (2007). Quantity and spectroscopic properties of soil
dissolved organic matter (DOM) as a function of soil sample treatments: Air-drying
and pre-incubation.
Chemosphere
,
69
, 1040-1046.
American Public Health Association, American Water Works Association, and Water
Pollution Control Federation (1965).
Standard Methods for the Examination of Water
and Wastewater Including Bottom Sediments and Sludges
. New York: American Public
Health Association, Inc.
Baker, A. (2001). Fluorescence excitation emission matrix characterization of some sew-
age-impacted rivers.
Environ. Sci. Technol
.,
35
(5), 948-953.
Baker, A. (2002). Fluorescence properties of some farm wastes: Implications for water
quality monitoring.
Water Res
.,
36
(1), 189-195.
Baker, A. and Genty, D. (1999). Fluorescence wavelength and intensity variations of cave
waters.
J. Hydrol
.,
217
(1-2), 19-34.
Baker, A. and Bolton, L. (2000). Speleothem organic acid luminescence intensity ratios: a
new palaeoenvironmental proxy.
Cave Karst Sci
.,
27
, 121-124.
Baker, A., Genty, D., and Smart, P. (1998). High-resolution records of soil humification
and paleoclimate change from variations in speleothem luminescence excitation and
emission wavelengths.
Geology
,
26
(10), 903-906.
Beggs, K.M.H., Summers, R.S., and McKnight, D.M. (2009). Characterizing chlorine oxi-
dation of dissolved organic matter and disinfection by-product formation with fluores-
cence spectroscopy and parallel factor analysis.
J. Geophys. Res
.,
114
(G4), G04001.
Bu, X., Wang, L., Ma, W., Yu, X., Mcdowell, W.H., and Ruan, H. (2010). Spectroscopic
characterization of hot-water extractable organic matter from soils under four differ-
ent vegetation types along an elevation gradient in the Wuyi Mountains.
Geoderma
,
159
, 139-146.
Cannavo, P., Dudal, Y., Boudenne, J.-L., and Lafolie, F. (2004). Potential for fluorescence
spectroscopy to assess the quality of soil water-extracted organic matter.
Soil Sci
.,
169
(10), 688-696.
Chen, Y., Senesi, N., and Schnitzer, N. (1977). Information provided on humic substances
by E
4
/E
6
ratios.
Soil Sci. Soc. Am. J
.,
41
(2), 352-358.
Coble, P. (1996). Characterization of marine and terrestrial DOM in seawater using excita-
tion-emission matrix spectroscopy.
Mar. Chem
.,
51
(4), 325-346.
Corvasce, M., Zsolnay, A., D'Orazio, V., Lopez, R., and Miano, T. (2006). Characterization
of water extractable organic matter in a deep soil profile.
Chemosphere
,
62
(10),
1583-1590.
Cory, R. and McKnight, D. (2005). Fluorescence spectroscopy reveals ubiquitous presence
of oxidized and reduced quinones in dissolved organic matter.
Environ. Sci. Technol
.,
39
(21), 8142-8149.
Cory, R.M., McKnight, D.M., Chin, Y.-P., Miller, P., and Jaros, C.L. (2007). Chemical
characteristics of fulvic acids from arctic surface waters: Microbial contributions and
photochemical transformations.
J. Geophys. Res. Biogeochem
.,
112
(G4), G04S51.
Cory, R.M., Miller, M.P., McKnight, D.M., JGuerard, J.J., and Miller, P.L. (2010). Effect
of instrument-specific response on the analysis of fulvic acid fluorescence spectra.
Limnol
.
Oceanogr. Meth
.,
8
, 67-78.
