For YE estuary sediment, the reduci

For YE estuary sediment, the reducible fraction was the dominant
phase for Cu, Zn, Pb and Cr, except for the residual fraction. It can be
shown that these tracemetals are easily co-precipitatedwith Fe/Mnoxides
in the estuarine environment (Laing et al., 2009). We presumed
that the Fe/Mn oxide precipitation was related with the mixture of
fresh and salty water, which changed the geochemical properties of
suspended particulate and reduced the co-precipitation of metals and
oxides (Hochella et al., 2005). YE estuary sediments included more of
the residual fraction (F4) of Cr and the oxidizable fraction of Cd than
those from other areas, but a similar partitioning pattern with NJ river
sediment, indicating some successive characteristics from the river
(Qi et al., 2010).
Trace metals in TL lake sediment showed diverse partitions. The
reducible phases of Cd and Cr showed a high proportion comparing to
those in other areas. Zinc showed a relatively high F4 proportion and
Cd showed a relatively low F4 proportion, due to material inputs from
different rivers (cover rural or urban) (Huang, 2001; Xu et al., 2001).
The high stable phases of Zn and Cr may be the contribution from
ambient soils (Yin et al., 2008). These distribution patterns of metal
forms imply more sources of sediments in Taihu Lake.
3.5. Metal fractions and risk code assessment
The ecologic risk assessment of sediments based on the total metal
content is questionable because the bioavailability of metal largely
depends on its speciation. Many research reports have confirmed that
the metal phases influence the toxicity for organism in the aquatic
system, especially for the acid extractable fraction (Kwon and Lee,
2001; Liu et al., 2008).
The risk assessment code (RAC) is determined based on the percentage
of the total metal content that is present in the first metal fraction
(% F1), where binding is weak and the metals pose a greater risk.
When the RAC is less than 1%, the sediment is of no risk to the aquatic
environment. Percentages of 1–10% reflect low risk, 11–30% medium
risk, and 31–50% high risk. Above 50%, the sediment poses a very high
risk, and is considered dangerous for the aquatic organism (Jain, 2004;
Singh et al., 2005).
Fig. 4 showed the RAC results of sediments in three areas. The
RAC values of metals in NJ river sediment were in the order of Cd
N Pb N Zn N Cu N Cr. Cadmium showed a high risk (33.5–45.1%) in sediment
samples. Lead showed a medium–high risk (15.0–32.8%), which
was obviously related with traffic emission. Zinc showed a medium
risk (14.7–19.4%) in NJ river sediments. But for Cu and Cr, the RAC
values were in the low risk ranges (1–10%) because the samples with
the lowest risks occurred in those locations departing from the big
city (N1 and N15), indicating a significant effect of urban materials on
heavy metals of sediments.
The RAC values of metals in YE river sediment and TL lake sediment
decreased with Cd N Pb N Cu N Zn N Cr. The RACs of Cd and Pb in YE
estuary sediments revealed a medium–high risk (14.6–41.4%) and a
low–medium risk (7.9–27.7%) respectively, indicating a lower risk
comparing to NJ river sediment. But Cu and Zn showed a low–medium
risk (3.9–18.1%, 5.1–20.2%). They revealed a relatively risk in riverward
sediments (Y1–Y11). Cadmium showed a medium–high risk in TL lake
sediment (RAC 23.4–44.0%), but Pb was in the low risk range except
for one sample (T16–10.8%). Copper and Zn of TL lake sediment
displayed low–medium risks (3.3–18.9%, 2.3–16.6%). The lowest
risk of heavy metals in TL lake sediment was Cr, which was similar
with sediments in other areas. Samples with higher risks were located
in the northern lake, showing an effect of industrial discharge in