Hussein A. M. Al-Zubaidi scite author profile

Since the late nineteenth century, channel depths have more than doubled in parts of New York Harbor and the tidal Hudson River, wetlands have been reclaimed and navigational channels widened, and river flow has been regulated. To quantify the effects of these modifications, observations and numerical simulations using historical and modern bathymetry are used to analyze changes in the barotropic dynamics. Model results and water level records for Albany (1868 to present) and New York Harbor (1844 to present) recovered from archives show that the tidal amplitude has more than doubled near the head of tides, whereas increases in the lower estuary have been slight (<10%). Channel deepening has reduced the effective drag in the upper tidal river, shifting the system from hyposynchronous (tide decaying landward) to hypersynchronous (tide amplifying). Similarly, modeling shows that coastal storm effects propagate farther landward, with a 20% increase in amplitude for a major event. In contrast, the decrease in friction with channel deepening has lowered the tidally averaged water level during discharge events, more than compensating for increased surge amplitude. Combined with river regulation that reduced peak discharges, the overall risk of extreme water levels in the upper tidal river decreased after channel construction, reducing the water level for the 10-year recurrence interval event by almost 3 m. Mean water level decreased sharply with channel modifications around 1930, and subsequent decadal variability has depended both on river discharge and sea level rise. Channel construction has only slightly altered tidal and storm surge amplitudes in the lower estuary. Plain Language SummaryDredging for navigation has deepened harbors and estuaries around the world, altering circulation patterns and tidal water levels. In the Hudson River estuary, channel construction for ports in New York Harbor and Albany more than doubled channel depths in some regions. Major dredging began in the late 1800s, so to characterize associated changes in the hydrodynamic conditions, we analyzed archival water level records and navigational charts back to that period. Water level records from Albany show that channel construction reduced the effects of friction such that the tide now amplifies in the upper estuary, more than doubling the tidal amplitude compared with before dredging. The lower friction also allows storm surge from the coast to travel farther landward. However, major flooding in the upper tidal river historically was mainly due to river discharge events, and the deeper channel allows for more effective conveyance of flood waves. Thus, despite the increases in tides and storm surge, the risk of flooding in the upper estuary decreased with construction of the navigational channel. The Hudson provides a well-documented example of how multiple anthropogenic factors can significantly influence physical processes in extensively modified estuaries. Key Points:• Archival records over the past 150 years show that the tidal amplitu...

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Raw landfill leachate treatment using an electrocoagulation process with a novel rotating electrode reactor

Naje¹,

Ajeel²,

Ali

et al. 2019

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In this work, landfill leachate treatment by electrocoagulation process with a novel rotating anode reactor was studied. The influence of rotating anode speed on the removal efficiency of chemical oxygen demand (COD), total dissolved solids (TDS), and total suspended solids (TSS) of raw landfill leachate was investigated. The influence of operating parameters like leachate pH, leachate temperature, current, and inter-distance between the cathode rings and anode impellers on the electrocoagulation performance were also investigated. The results revealed the optimum rotating speed is 150 rpm and increasing the rotating speed above this value led to reducing process performance. The leachate electrocoagulation treatment process favors the neutral medium and the treatment performance increases with increasing current intensity. Furthermore, the electrocoagulation treatment performance improves with increasing leachate temperature. However, the performance reduces with increasing inter-electrode distance.

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Comparison of a 2D and 3D Hydrodynamic and Water Quality Model for Lake Systems

Al-Zubaidi¹,

Wells²

2018

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Analytical and field verification of a 3D hydrodynamic and water quality numerical scheme based on the 2D formulation in CE-QUAL-W2

Al-Zubaidi

Wells

2018

Journal of Hydraulic Research

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A new 3D hydrodynamic model was developed to simulate water quality transport in surface waterbodies. The governing equations are the continuity equation, free surface equation, momentum equation, and transport equation. The 2D numerical scheme of CE-QUAL-W2 was expanded in three dimensions and modified to solve for the free surface elevation. A time splitting technique was employed to solve the momentum and transport equation. The numerical formulation of the 3D scheme used a novel solution, which resulted in a tri-diagonal matrix form for solving the free surface equation rather than a more computationally intensive penta-diagonal matrix solution. In addition, the hydrodynamic and water quality equations were solved at the same time step in order to allow feedback between water quality and hydrodynamics. The verification of the model hydrodynamics and temperature was performed by comparing the model predictions to known analytical solutions and field data from Lake Chaplain, Washington, USA. There was good agreement of the solution of the hydrodynamic equations to analytical solutions and field data.

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