TY - JOUR
T1 - Scale-dependent perspectives on the
geomorphology and evolution of beachdune
systems
AU - Walker, Ian J.
AU - Davidson-Arnott, Robin G.D.
AU - Bauer, Bernard O.
AU - Hesp, Patrick A.
AU - Delgado-Fernandez, Irene
AU - Ollerhead, Jeff
AU - Smyth, Thomas A.G.
PY - 2017/4/23
Y1 - 2017/4/23
N2 - Despite widespread recognition that
landforms are complex Earth systems with
process-response linkages that span
temporal scales from seconds to millennia
and spatial scales from sand grains to
landscapes, research that integrates
knowledge across these scales is fairly
uncommon. As a result, understanding of
geomorphic systems is often scaleconstrained
due to a host of
methodological, logistical, and theoretical
factors that limit the scope of how Earth
scientists study landforms and broader
landscapes.
This paper reviews recent advances in
understanding of the geomorphology of
beach-dune systems derived from over a
decade of collaborative research from
Prince Edward Island (PEI), Canada. A
comprehensive summary of key findings is
provided from short-term experiments
embedded within a decade-long
monitoring program and a multi-decadal
reconstruction of coastal landscape
change. Specific attention is paid to the
challenges of scale integration and the
contextual limitations research at specific
spatial and/or temporal scales imposes.
A conceptual framework is presented that
integrates across key scales of
investigation in geomorphology and is
grounded in classic ideas in Earth surface
sciences on the effectiveness of formative
events at different scales. The paper uses
this framework to organize the review of
this body of research in a ‘scale aware’
way and, thereby, identifies many new
advances in knowledge on the form and
function of subaerial beach-dune systems.
Finally, the paper offers a synopsis of how
greater understanding of the complexities
at different scales can be used to inform
the development of predictive models,
especially those at a temporal scale of
decades to centuries, which are most
relevant to coastal management issues.
3 / 7
Models at this (landform) scale require an
understanding of controls that exist at
both ‘landscape’ and ‘plot’ scales.
Landscape scale controls such as sea level
change, regional climate, and the
underlying geologic framework essentially
provide bounding conditions for
independent variables such as winds,
waves, water levels, and littoral sediment
supply. Similarly, a holistic understanding
of the range of processes, feedbacks, and
linkages at the finer plot scale is required
to inform and verify the assumptions that
underly the physical modelling of beachdune
interaction at the landform scale.
AB - Despite widespread recognition that
landforms are complex Earth systems with
process-response linkages that span
temporal scales from seconds to millennia
and spatial scales from sand grains to
landscapes, research that integrates
knowledge across these scales is fairly
uncommon. As a result, understanding of
geomorphic systems is often scaleconstrained
due to a host of
methodological, logistical, and theoretical
factors that limit the scope of how Earth
scientists study landforms and broader
landscapes.
This paper reviews recent advances in
understanding of the geomorphology of
beach-dune systems derived from over a
decade of collaborative research from
Prince Edward Island (PEI), Canada. A
comprehensive summary of key findings is
provided from short-term experiments
embedded within a decade-long
monitoring program and a multi-decadal
reconstruction of coastal landscape
change. Specific attention is paid to the
challenges of scale integration and the
contextual limitations research at specific
spatial and/or temporal scales imposes.
A conceptual framework is presented that
integrates across key scales of
investigation in geomorphology and is
grounded in classic ideas in Earth surface
sciences on the effectiveness of formative
events at different scales. The paper uses
this framework to organize the review of
this body of research in a ‘scale aware’
way and, thereby, identifies many new
advances in knowledge on the form and
function of subaerial beach-dune systems.
Finally, the paper offers a synopsis of how
greater understanding of the complexities
at different scales can be used to inform
the development of predictive models,
especially those at a temporal scale of
decades to centuries, which are most
relevant to coastal management issues.
3 / 7
Models at this (landform) scale require an
understanding of controls that exist at
both ‘landscape’ and ‘plot’ scales.
Landscape scale controls such as sea level
change, regional climate, and the
underlying geologic framework essentially
provide bounding conditions for
independent variables such as winds,
waves, water levels, and littoral sediment
supply. Similarly, a holistic understanding
of the range of processes, feedbacks, and
linkages at the finer plot scale is required
to inform and verify the assumptions that
underly the physical modelling of beachdune
interaction at the landform scale.
KW - Beaches
KW - Foredunes
KW - Sand dunes
KW - Coastalgeomorphology
KW - Aeolian geomorphology
KW - Sediment transport
KW - Airflow dynamics
KW - Computational fluid dynamics
KW - Coastalerosion
KW - Sand
UR - https://doi.org/10.1016/j.earscirev.2017.04.011
U2 - 10.1016/j.earscirev.2017.04.011
DO - 10.1016/j.earscirev.2017.04.011
M3 - Article (journal)
SN - 0012-8252
VL - 171
SP - 220
EP - 253
JO - Earth-Science Reviews
JF - Earth-Science Reviews
ER -