Geoscience Reference
In-Depth Information
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 excitation-emission matrix characterization of river waters
impacted by a tissue mill effluent.
Environ. Sci. Technol
.,
36
(7), 1377-1382.
Baker, A. and Genty, D. (1999). Fluorescence wavelength and intensity variations of cave
waters.
J. Hydrol
.,
217
, 19-34.
Baker, A. and Lamont-Black, J. (2001). Fluorescence of dissolved organic matter as a nat-
ural tracer of groundwater.
Groundwater
,
39
, 745-750.
Baker, A. and Curry, M. (2004). Fluorescence of leachates from three contrasting landfills.
Water Res
.,
38
, 2605-2613.
Baker, A., and Inverarity, R. (2004). Protein-like fluorescence intensity as a possible tool
for determining river water quality.
Hydrol. Process
.,
18
(15), 2927-2945.
Baker, A., Smart, P.L., Edwards, R.L., and Richards, D.A. (1993). Annual banding in a
cave stalagmite.
Nature
,
364
, 518-520.
Baker, A., Barnes, W.L., and Smart, P.L. (1997). Stalagmite drip discharge and organic
matter fluxes in Lower Cave, Bristol.
Hydrol. Process
.,
11
, 1541-1555.
Baker, A., Mockler, N.J., and Barnes, W.L. (1999). Fluorescence intensity variations of
speleothem forming groundwaters: implications for palaeoclimate reconstruction.
Water Resourc. Res
.,
35
, 407-413.
Baker, A., Inverarity, R., Charlton, M., and Richmond, S. (2003). Detecting river pollution
using fluorescence spectrophotometry: Case studies from the Ouseburn, NE England.
Environ. Pollut
.,
124
(1), 57-70.
Baker, A., Inverarity, R., and Ward, D. (2005). Catchment-scale fluorescence water quality
determination.
Water Sci. Technol
.,
52
(9), 199-207.
Baker, A., Bolton, L., Newson, M., and Spencer, R.G.M. (2008). Spectrophotometric prop-
erties of surface water dissolved organic matter in an afforested upland peat catch-
ment.
Hydrol. Process
.,
22
, 2325-2336.
Bari, A. and Farooq, S. (1985). Measurement of wastewater treatment efficiency by fluores-
cence and UV absorbance.
Environ. Monit. Assess
.,
5
(4), 423-434.
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
, G04001.
Bieroza, M., Baker, A., and Bridgeman, J. (2009a). Relating freshwater organic matter
fluorescence to organic carbon removal efficiency in drinking water treatment.
Sci.Tot.
Environ
.,
407
(5), 1765-1774.
Bieroza, M., Baker, A., and Bridgeman, J. (2009b). Exploratory analysis of excitation-
emission matrix fluorescence spectra with self organizing maps as a basis for deter-
mination of organic matter removal efficiency at water treatment works.
J. Geophys.
Res. Biogeosci
.,
114
, G00F07.
Bieroza, M.Z., Bridgeman, J., and Baker, A. (2010). Fluorescence pectroscopy as a tool for
determination of organic matter removal efficiency at water treatment works.
DWES
,
3
, 63-70.
Bieroza, M.Z., Baker, A., and Bridgeman, J. (2011a). Assessment of low pH coagulation
performance using fluorescence spectroscopy.
J. Environ. Engng
.,
137
(7), 596.
Bieroza, M.Z., Baker, A., and Bridgeman, J. (2011b). New data mining and calibration
approaches to the assessment of water treatment efficiency.
Adv. Eng. Software
,
44
,
126-135.
Black, A.P., and Christman, R.F. (1963). Characteristics of coloured surface waters.
J. Am.
Water Works Assoc
.,
55
(6), 753-770.
