Geoscience Reference
In-Depth Information
Guo, L.D. and Santschi, P.H. (1997). Composition and cycling of colloids in marine envir-
onments.
Rev. Geophys
.,
35
(1), 17-40.
Hefner, K.H., Fisher, J.M., and Ferry, J.L. (2006). A multifactor exploration of the photo-
bleaching of Suwannee River dissolved organic matter across the freshwatersaltwater
interface.
Environ. Sci. Technol
.,
40
(12), 3717-3722.
Henderson, R.K., Baker, A., Murphy, K.R., Hamblya, A., Stuetz, R.M., and Khan, S.J.
(2009). Fluorescence as a potential monitoring tool for recycled water systems: A
review.
Water Res
.,
43
(4), 863-881.
Hosse, M. and Wilkinson, K.J. (2001). Determination of electrophoretic mobilities and
hydrodynamic radii of three humic substances as a function of pH and ionic strength.
Environ. Sci. Technol
.,
35
(21), 4301-4306.
Hudson, N., Baker, A., Reynolds, D.M., Carliell- Marquet, C., and Ward, D. (2009).
Changes in freshwater organic matter fluorescence intensity with freezing/thaw-
ing and dehydration/rehydration.
J. Geophys. Res. Biogeosci
., 114, G00F08,
doi:10.1029/2008JG000915
Huguet, A., Vacher, L., Saubusse, S., Etcheber, H., Abril, G., Relexans, S., Ibalot, F., and
Parlanti, E. (2010). New insights into the size distribution of fluorescent dissolved
organic matter in estuarine waters.
Org. Geochem
.,
41
(6), 595-610.
Kaiser, K. and Guggenberger, G. (2000). The role of DOM sorption to mineral surfaces in
the preservation of organic matter in soils.
Org. Geochem
.,
31
(7-8), 711-725.
Kieber, R.J., Zhou, X.L., and Mopper, K. (1990). Formation of carbonyl compounds from
UV-induced photodegradation of humic substances in natural waters: Fate of riverine
carbon in the sea.
Limnol. Oceanogr
.,
35
(7), 1503-1515.
Kieber, R.J., Hydro, L.H., and Seaton, P.J. (1997). Photooxidation of triglycerides and
fatty acids in seawater: Implication toward the formation of marine humic substances.
Limnol.Oceanogr
.,
42
, 1454-1462.
Kieber, R.J., Willey, J.D., Whitehead, R.F., and Reid, S.N. (2007). Photobleaching of
chromophoric dissolved organic matter (CDOM) in rainwater.
J. Atmos. Chem
.,
58
(3),
219-235.
Kong, L. and Ferry, J.L. (2003). Effect of salinity on the photolysis of chrysene adsorbed
to a smectite clay.
Environ. Sci. Technol
.,
37
(21), 4894-4900.
Korshin, G.V., Kumke, M.U., Li, C.W., and Frimmel, F.H. (1999). Influence of chlorination
on chromophores and fluorophores in humic substances.
Environ. Sci. Technol
.,
33
(8),
1207-1212.
Koussai, A.M. and Zika, R.G. (1990). Light-induced alteration of the photophysical prop-
erties of dissolved organic matter in seawater. 1. Photoreversible properties of natural
water fluorescence.
Nether. J. Sea Res
.,
27
(1), 25-32.
Kowalczuk, P., Cooper, W.J., Whitehead, R.F., Durako, M.J., and Sheldon, W. (2003).
Characterization of CDOM in an organic-rich river and surrounding coastal ocean in
the South Atlantic Bight.
Aquat. Sci
.,
65
(4), 384-401.
Kowalczuk, P., Durako, M.J., Young, H., Kahn, A.E., Cooper, W.J., and Gonsior, M. (2009).
Characterization of dissolved organic matter fluorescence in the South Atlantic
Bight with use of PARAFAC model: Interannual variability.
Mar. Chem
.,
113
(3-4),
182-196.
Kujawinski, E.B., Del Vecchio, R., Blough, N.V., Klein, G.C., and Marshall, A.G. (2004).
Probing molecular-level transformations of dissolved organic matter: Insights on
photochemical degradation and protozoan modification of DOM from electrospray
ionization Fourier transform ion cyclotron resonance mass spectrometry.
Mar. Chem
.,
92
(1-4), 23-37.
