Persulfate for the Disinfection of Ballast Water Dani Miles CMOP Intern, Summer 2010
-
Upload
lillith-bond -
Category
Documents
-
view
22 -
download
2
description
Transcript of Persulfate for the Disinfection of Ballast Water Dani Miles CMOP Intern, Summer 2010
1
Persulfate for the Disinfection of Ballast Water
Dani MilesCMOP Intern, Summer 2010
Mentor: Paul Tratnyek
2Project Overview:
PurposeTo test the effectiveness of a potentially new method to treat
ballast water for the prevention of spread and establishment of invasive species in coastal margins.
ObjectivesStability studies of persulfate in aqueous solutions:
Develop a quick and reliable method for determining persulfate concentrations.
Systematic observation of persulfate decay versus key variables.
Examine persulfate decay in natural water samples.
3Background: Ballast Water Treatments
Initiatives and Treatments Offshore Ballast Exchange (IMO). Physical: filtration, UV light, heat. Chemical: chlorine, hydrogen
peroxide, peracetic acid, and other oxidants.
Treatment Disadvantages Costly and harmful by-products.
Advantages of Persulfate Already applied to ground water. Potent oxidant. Inexpensive. Safe sulfate by-product.
4Methods: Persulfate Spectroscopy
Colorimetric Method: Established method for assays
of general oxidative activity. Oxidation of colorless iodide (I-)
forms yellow iodine (I2).
Effectiveness: Not selective to oxidants. Successful in many water types. Very dilute persulfate (μM). Requires large quantities of KI. Efficient with a flow-through
spectrometer, Gilford Stasar III.
Figure 1. Ultraviolet and visible absorption spectra of primary reagents.
Figure 2. Calibration curves for DI, Instant Ocean and natural water samples.
5 Results: Persulfate Decay
Water samples: Deionized water Instant Ocean (30 g/L salts) Natural sample (Newport) Sulfate solution (28 mM)
Simulation conditions: Temperatures:
60, 70, and 80˚ C
Initial Concentrations: 10, 5, and 1 mM persulfate
Figure 3. Persulfate decay curves in un-buffered aqueous solutions at 60˚ C. Water type is indicated by color, and initial concentrations are shown by marker shape. Curves are fit to data as first order decay.
6Results: Temperature Effects
Figure 4. Natural log of rate constants for first order decay of persulfate in un-buffered aqueous solutions. Temperature is indicated by color, solvent is shown on the bottom axis, and initial concentrations are given in the legend.
Observations: Faster decay at higher
temperatures. Slower decay than
predicted values. Slower decay in ionized
waters, but reduced effectat high temperatures.
Differentiation between initial persulfate concentrations at 60˚C.
Saline waters with and without organic matter exhibit similar kinetics.
7Conclusions: Persulfate
Completed Studies: Observation of temperature, water type and initial
concentration effects. Analyzing the influence of salinity and the sulfate ion. Comparing river and estuary water samples. Investigating solutions exposed to solid iron.
Summary: Temperature is the primary variable governing
persulfate stability. Increased salinity or ionic strength slows decay. Persulfate exhibits a long lifetime as an active oxidant
in aqueous solutions.
8Future Studies:
Examining effectiveness for disinfection: Fluorescent stains and flow cytometry. Observing persulfate at seawater temperatures. Determining optimal dose. The effect of metal ballast tanks. The effect of pH. Comparisons to current oxidative treatments
and regulations:
9Special Thanks
Paul Tratnyek Jim Nurmi Tawyna Peterson Jason Righter Paul Lim Tratnyek Lab
Needoba Lab Marisa Frieder Vanessa Green CMOP NSF-STARS