ited levees
>and-7 image,
r. The light
e and near-
are typical
c matter: In
1 floodplain
1-5 image of
to the dark
s and bare
re white on
res, basins,
3 partly as
of 1974 and
indicate an
n both visi-
lectromagne-
for highly
t, sediments
areas might
1 floodplain
ant organic
ly buried by
3nly as dark
contain high
in the lower
s with time
ours on both
E different
entification
'Odplain the
3 pattern on
r on that of
3 colours of
etated long
light-grey
nd dark co
rn the large
L change of
a boundary
The basins
Lble images,
mages while
e channels,
d that fine
sins of the
tg the large
er distance
iplain some
the Meghna
i vegetation
miform dark
' images of
>pearance of
.cally indi-
sat and clay
:ir location
¡ist of "mud
and between
ituated far
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and a few
de channels
ometry. The
erent years
ndition. As
e played an
e composite
1 and river
flooding by
r than min-
wet basins
A - tidal floodplain
B - river floodplain
C - composite floodplain
Figure 3. Drainage pattern map
of Bangladesh delta area
Landsat image
Figure 4b. Embroidery floodplain landscape
Landsat image
far from active river channels. Moreover, rainwater
flooding can only redistribute the finest sediments
in the direction of low basins while leaving the
relatively coarser ones such as sand and silt at the
place where they were deposited by river or tidal
flooding. According to differences in colour on
both visible and near-infrared images of different
years the composite floodplain is subdivided into
smalle units as peat, thin clay cover over peat,
thin sand-silt cover over peat, sandy-silty deposits
and swamp deposits.
Peat: The largest part of the composite floodplain
appears black and dark grey on the 1974 band-7 im
age. On the band-5 image, however, the black areas
also appear black while dark grey areas are lighter,
medium grey in colour. The black areas are also
black on the band-7 image of 1975. The black colours
on both images of different years are typical for
very wet peat materials. These black areas must
correspond to the lower parts of the composite
floodplain where thick layers of peat could devel
op.
Due to differences in moisture content and vegeta
tion cover at different times, peat areas do not
appear with the same shape and size on images of two
years. However, the real boundary of peat areas can
be drawn by comparing the near-infrared images of
these two years.
Thin clay cover over peat: The finest clay accumu
lates in the lowest parts of the floodplain. The
areas around and between the peat layers appear
medium grey on band-5 and dark grey on band-7 images
of 1974. The clay materials normally show similar
colours on visible and near-infrared images. When
clay is highly saturated, as was the case during the
1975 recording, it appears black and blackish on
near-infrared images just like the peat layers. By
comparing the near-infrared images of 1974 and 1975
the boundary of clay deposits, which possibly cover
parts of the peat layers, can be drawn.
Thin sand-silt cover over peat: The areas in the
Southeast and in the North of the composite flood-
plain appear light grey on band-5 and medium grey on
band-7 images of 1973 and 1974. These colours indi
cate that the materials are coarser and less satu
rated than clay accumulations. These areas, which
are at the boundary with tidal and river flood-
plains, might consist of sandy-silty sediments part
ly transported and spread over the peat area by a
few tidal and river creeks, and partly accumulated
through rainwater flooding.
Thick sandy-silty deposits: A few small areas in
between the black coloured peat layers can be easily
distinguished by their light grey colour on band-5
and band-7 images of 1973 and 1974. The light colour
indicates the presence of sandy-silty deposits.
These areas, possibly having thick sandy-silty sedi
ments, form relatively higher lying places in the
lower parts of the composite floodplain.
Swamp deposits: Small areas in the Chitra and
Madhumati River floodplains appear black in colour
and similar in size and shape on band-7 images of
1973 and 1974. On the band-5 images of the same
years, however, the same areas are dark grey. These
colours are a typical indication of highly saturated
peat, organic matter and clay materials. Considering
the relations of these areas with the respective
rivers, however, they are covered possibly mainly by
water, organic matter and clay than by peat. They
can be identified as "swamp deposits".
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