Sedimentation Processes in Buffalo Bay, Mercury Bay

The primary aim of this study was to investigate the sedimentation processes within Buffalo Bay, particularly within and adjacent to the Whitianga tidal inlet, in order to ascertain reasons for the shoaling at both the inlet, and the identified shallow zone around Pandora Rock. Abstract from thesis: Comparison of historic bathymetries suggests the ebb delta and ebb discharge channel of the Whitianga tidal inlet are rapidly accreting and the ebb tidal discharge channel is gradually migrating northeast towards Whakapenui Point. Accretion rates of up to 25 cm y-1 were calculated in the ebb delta and inlet discharge channel area between 1979 and 1995 and aerial photo comparisons suggest the ebb delta area had increased by 400 % between 1990 and 2002. Results of the hydrodynamic and sediment transport modelling suggest the rapid accretion in the ebb delta vicinity is likely to be caused by a combination of catchment estuary inputs, which are deposited on the ebb tide as the ebb flow decelerates over the ebb delta, and inputs that have been moved south along Buffalo Beach by flood currents and an eddy that forms landward of the ebb tidal discharge. Residual tidal velocities further suggest a deposition zone in the ebb delta vicinity resulting from opposing currents and the deceleration of currents. Hydrodynamic modelling results indicate the isolated shallow zone around Pandora rock appears to be caused by a transient eddy in the southern section of Buffalo Bay. The eddy is formed by the ebb tidal discharge from the inlet. Accretion probably occurs in the centre of the eddy which moves north as the ebb tide progresses. Results obtained from a current meter and sediment trap deployed in northern Buffalo Bay suggest suspended sediment transport is minimal in northern Buffalo Bay, only occurring with large wave activity. Results of the hydrodynamic and sediment transport modelling further demonstrate that this area experiences low flow velocities, and has little interaction with the rest of Buffalo Bay. The minimal sediment input to this area, combined with the occasional erosion of the seafloor, primarily by wave activity, is thought to have resulted in long term erosion of northwestern Buffalo Bay between 1938 and 1979. Although the beach and nearshore is eroding, it is likely the addition of sediment would act to stabilise this section of eroding beach. Renourishment material could be provided by the ebb delta, the southern tip of Buffalo Bay or the isolated sandbar northeast of the inlet entrance.

Comparison of bothymetric data and calculation of accretion rates. Hydrodynamic sediment transport model. Data collected on water level and currents - 10 sites in Mercury Bay over two deployments. Current meter and sediment trap deployment in northern Buffalo Bay.

Buffalo Bay and Whitianga Estuary mouth.

Hydrographic charts analysed from 1979-2002. Investigation undertaken 2005-2006. Instrument deployments: 22/11/2005 - 30/12/2005 and 21/03/2006 - 02/05/2006.

Aerial photo analysis (1944. 1990, 1995, 2002) of Buffalo Beach and inlet. Depth/wave and current data collected: S4ADW and Dobie instruments - 10 sites spread over 2 deployments. Sediment traps deployed. Modelling using MIKE3.

Completeness: Data from S4 at Round Island didn't include depth. S4 in Harbour faulty so only Dobie information.

Appendices on CD in back of thesis.

Master of science thesis. Understanding of coastal processes, sediment transport and hazards in Mercury Bay.

Thesis freely available in Univerity of Waikato Library. Full electronic access from University catalogue. No confidentiality.

Study completed.