Pa. Hacker et al., PRODUCTION AND REMOVAL OF ASSIMILABLE ORGANIC-CARBON UNDER PILOT-PLANT CONDITIONS THROUGH THE USE OF OZONE AND PEROXONE, Ozone: science & engineering, 16(3), 1994, pp. 197-212
Pilot-plant studies were conducted in two source waters to determine t
he effects of predisinfection with ozone alone and with a combination
of hydrogen peroxide and ozone (PEROXONE) on the production of assimil
able organic carbon (AOC) compounds. Colorado River water (CRW) and St
ate project water (SPW) from Northern California were treated with ozo
ne alone at applied dosages ranging from 1 to 4 mg/L and with PEROXONE
at hydrogen peroxide/ozone (H2O2/O3) ratios of 0.05, 0.10, 0.20, and
0.30. Ozonation of CRW with applied dosages of 1.0, 2.0, and 4.0 mg/L
increased AOC concentrations from 70 mug C/L to 275, 350, and 224 mu C
/L, respectively. Ozonation of SPW with an applied dosage of 4.0 mg/L
elevated AOC concentrations from 70 to 522 mug C/L. In most cases, app
lication of PEROXONE at an H2O2/O3 ratio of 0.05 increased production
of AOC by up to 100% in comparison with the use of ozone alone; howeve
r, there was no clear relationship between PEROXONE ratios and AOC con
centrations. Subsequent filtration through biologically active, dual-m
edia anthracite/sand filters reduced AOC concentrations to levels that
were lower than or equal to source - water AOC levels. Continuous chl
oramination at a dosage of 1.5 mg/L across the filters decreased AOC r
emoval efficiency by 80%, indicating that biological activity is requi
red for AOC reduction. Changing the application points of ozone from p
refiltration to post-filtration resulted in at least threefold AOC inc
reases over influent values for both source waters. Similar AOC increa
ses were observed when the treatment process was altered to include bo
th prefiltration and post-filtration ozone application. This indicates
that even after biological filtration, there may be sufficient organi
c material remaining to produce AOC upon ozone or PEROXONE disinfectio
n.