culture
the distinction between English-speaking
geomorphologists (process, geotechnical, quantitative, applied) versus
other scientific cultures (e.g. mapping, climatic, soil in Europe)
time
geomorphic processes have occurred throughout earth
history and are expressed in the sedimentary structures, however
geomorphology as a discipline is the study of late Cenozoic landforms
(Tertiary and Quaternary Epochs)
geomorphologists study of landscape evolution at
longer than human lifespans but very much shorter than the entire
geologic record
explanation is nearly always of past evolution rather
than prediction of future change
space
similarly the spatial domain is limited to the
sub-continental scale (submarine studies are part of oceanography)
large-area studies are in the realm of physiography,
regional geomorphology, denudation chronology, climatic geomorphology and
mega-geomorphology
process
geomorphologists (especially English-speaking) focus
on exogenic processes
they rely on geological principles (i.e. plate
tectonics, isostasy) for the interpretation of endogenetic landforms
morphology and sediments
whereas the study (description, measurement, modelling
over time and space) of morphology is uniquely geomorphological,
investigation of internal structure overlaps with sedimentology,
Quaternary geology/stratigraphy, and soil science
soil
over most of the earth's surface, the dominant
physical processes are pedological (soil-forming rather than land-forming
processes)
however there is considerable overlap among soils,
weathering, erosion, sedimentation and topography (catenas), and the ages
of buried soils and geomorphic history
thus there is much to be learned at the interface of
pedology and geomorphology and soil geomorphology is an undervalued field
of study
morphology
based on the idea that the measurement and
classification of shapes will provide insight into the evolution of
landforms (similar for looking at the texture and structure of sediments)
stems largely from work of hydrologists (especially
R.E. Horton) working on drainage networks, and geographers (especially
A.N. Strahler) working on slopes and drainage basins, starting with the
quantitative revolution in geography
initially most data were extracted from maps, but now
remote sensing, GIS and DTM (military work in the 60's), offer great
potential for morphometric analysis with high resolution over large areas
(possibly even detecting changes in form over time)
climatic geomorphology
based on the idea that there are recognizable sets of
landforms and geomorphic processes associated with different climatic
regimes
significant methodology in French and German
geomorphology
characterized by emphasis on classification and
orphological studies and a lack of process research and theoretical
foundation
applies best to extreme climates (deserts, glacial,
periglacial) and provides poor explanation of structural and polygenetic
landscapes (i.e., in response to climatic change)
process geomorphology
the dominant approach in English geomorphology over
the past several decades
mesoscale, statistical, emphasis on temporal and
spatial variation in process rates
dominated by field studies where rates of transfer of
water, wind, ice and sediment are used to infer geomorphic processes in
lieu of direct observation
thus active (high-energy) landscapes (badlands,
mountains, beaches, periglacial landscapes) have attracted much research
in the past several decades
contemporary geomorphic theory has developed over the
past several decades as a conceptual framework for process geomorphology
geotechnical science (engineering geomorphology)
a by-product of process geomorphology as more
knowledge is required about material properties and the detailed
mechanics of processes
relies heavily on, and moves geomorphology towards,
civil engineering (soil and rock mechanics)and soils science
problems with scale linkage and thus generalization
from the laboratory to landforms and landscapes
applied geomorphology
application of geomorphology to contemporary
environmental and social problems (making geomorphology relevant)
includes aspects of process geomorphology,
geotechnical science, environmental studies, resource management, soil
conservation, hazards studies
typical of most research in public institutions
focus on human timescales and not necessarily at
timescales of landform evolution, thus it either draws geomorphologists
away from questions central to the discipline or requires considerable
thought about time scale linkages
Conclusion
the dominance of process and applied geomorphology (and
thus geotechnical studies), created a focus on the site scale, and neglect
of regional synthesis
we have gone beyond the mesoscale (and thus landscape
models) into the realm of engineers
geomorphologists have tended to align themselves with
engineers or geophysicists or sedimentologists rather then with colleagues
in their own discipline causing fragmentation, lack of connection to the
academic roots in geography, lack of focus on the primary goal:
explanation of the evolution of landscapes (see Baker and Twidale, 1993;
Ritter, 1988)
Terminology
besides the use of mathematics to express theory, ideas
and philosophy are expressed in native (spoken) language
natural (everyday) language is flexible and dynamic,
but therefore also ambiguous
natural language is too ambiguous for some disciplines
(e.g. math, logic) so they create their own languages
scientific definitions have to be precise
words used to represent constructs (e.g. apple) are
defined in terms of classification (apple is a fruit)
words used to represent concepts (e.g. stress) are
defined relative to other concepts which collectively comprise laws and
theory
the most theoretical disciplines have the most
rigorously defined terminology; the development of theory in geomorphology
is constrained by imprecise terminology
scientific language has the weaknesses of natural
language (ill-defined, misused, misunderstood, ambiguous, changing
terminology), plus the listener may not be aware of a term if he/she does
not subscribe to the same philosophy methodology: "each theoretical
view of geomorphology has created its own language" and views become
reinforced by virtue of a unique vocabulary
does the content of thought (words) influence the
thinking process; contemporary view: the structure of a language
influences perceptions of reality
there should be separate terminology for description
and interpretation because these are separate stages of the scientific
method
however genetic classification of landforms is common
and thus terms use to describe landforms convey their origin
(interpretation)
thus a scientific approach to geomorphology is not
well-supported by the use of existing terminology
problems with existing terminology:
morphogenetic terms: include an interpretation of
origin
landforms are often polygenetic (e.g., slope
processes on a landform of tectonic or glacial origin)
descriptive terms are more specific (less scope) and
thus less subjective (interpretive)
e.g.,
peneplain: the ultimate stage of the cycle of erosion
surface, alluvial fan, till versus diamicton
inadequately defined terms
with standard definitions, terms are used differently
by different schools of geomorphologists
e.g. ,nivation:
uncertain number of weathering and transport processes affected by snow
solifluction: may or may not be applied to permafrost
(gelifluction); Anderson (1906) working in the Falkland Islands did not
refer to permafrost in the original definition standard definition of landform; in reference books
it is either not defined (Goudie, et al., 1985, Encyclopaedic
Dictionary of Physical Geography) or defined in a general way in terms of
shape ("consistency of form", "the relative position of
points on an outline or external surface")
but geomorphologists usually think of a landform as
having both distinct shape and internal structure
evolving terms
the evolution of terminology reflects a compromise
between the need to revise or create concepts and the limited ability of
human beings to learn and memorize terminology
therefore, new terms are introduced and adopted only
when existing terms are inadequate
as terminology evolves, meanings change or terms
develop more than one meaning so that their use has to be explained,
which is contrary to the purpose of scientific terminology (shorthand)
e.g. ,periglacial:
originally "next to glaciers", now also used in the sense of
conditions that exist near glaciers
morphogenetic terms are subject to redefinition or
multiple use as the origins of landforms are re-evaluated, e.g. ,drumlins
(molding of drift or subglacial meltwater flood?)