TY - JOUR
T1 - Free Long-Wave Transformation in the Nearshore Zone through Partial Reflections
AU - Contardo, Stephanie
AU - Lowe, Ryan J.
AU - Dufois, Francois
AU - Hansen, Jeff E.
AU - Buckley, Mark
AU - Symonds, Graham
PY - 2023/3
Y1 - 2023/3
N2 - Long waves play an important role in coastal inundation and shoreline and dune erosion, requiring a de-tailed understanding of their evolution in nearshore regions and interaction with shorelines. While their generation and dissipation mechanisms are relatively well understood, there are fewer studies describing how reflection processes govern their propagation in the nearshore. We propose a new approach, accounting for partial reflections, which leads to an analytical solution to the free wave linear shallow-water equations at the wave-group scale over general varying bathymetry. The approach, supported by numerical modeling, agrees with the classic Bessel standing solution for a plane sloping beach but extends the solution to arbitrary alongshore uniform bathymetry profiles and decomposes it into incoming and outgoing wave components, which are a combination of successively partially reflected waves lagging each other. The phase lags introduced by partial reflections modify the wave amplitude and explain why Green’s law, which describes the wave growth of free waves with decreasing depth, breaks down in very shallow water. This reveals that the wave amplitude at the shoreline is highly dependent on partial reflections. Consistent with laboratory and field observations, our analytical model predicts a reflection coefficient that increases and is highly correlated with the normalized bed slope (bed slope rela-tive to wave frequency). Our approach shows that partial reflections occurring due to depth variations in the nearshore are responsible for the relationship between the normalized bed slope and the amplitude of long waves in the nearshore, with direct implications for determining long-wave amplitudes at the shoreline and wave runup.
AB - Long waves play an important role in coastal inundation and shoreline and dune erosion, requiring a de-tailed understanding of their evolution in nearshore regions and interaction with shorelines. While their generation and dissipation mechanisms are relatively well understood, there are fewer studies describing how reflection processes govern their propagation in the nearshore. We propose a new approach, accounting for partial reflections, which leads to an analytical solution to the free wave linear shallow-water equations at the wave-group scale over general varying bathymetry. The approach, supported by numerical modeling, agrees with the classic Bessel standing solution for a plane sloping beach but extends the solution to arbitrary alongshore uniform bathymetry profiles and decomposes it into incoming and outgoing wave components, which are a combination of successively partially reflected waves lagging each other. The phase lags introduced by partial reflections modify the wave amplitude and explain why Green’s law, which describes the wave growth of free waves with decreasing depth, breaks down in very shallow water. This reveals that the wave amplitude at the shoreline is highly dependent on partial reflections. Consistent with laboratory and field observations, our analytical model predicts a reflection coefficient that increases and is highly correlated with the normalized bed slope (bed slope rela-tive to wave frequency). Our approach shows that partial reflections occurring due to depth variations in the nearshore are responsible for the relationship between the normalized bed slope and the amplitude of long waves in the nearshore, with direct implications for determining long-wave amplitudes at the shoreline and wave runup.
KW - Dynamics
KW - Gravity waves
KW - Ocean
KW - Shallow-water equations
KW - Wind waves
UR - http://www.scopus.com/inward/record.url?scp=85148331546&partnerID=8YFLogxK
U2 - 10.1175/JPO-D-22-0109.1
DO - 10.1175/JPO-D-22-0109.1
M3 - Article
AN - SCOPUS:85148331546
SN - 0022-3670
VL - 53
SP - 661
EP - 681
JO - Journal of Physical Oceanography
JF - Journal of Physical Oceanography
IS - 3
ER -