BioRisk ey 55-68 (2009) RAC Ra mama eit ats
doi: 10.3897/biorisk.3.19 RESEARCH ARTICLE BioRisk

www.pensoftonline.net/biorisk Biodiversity & Ecosystem Risk Assessment

Habitat mapping project of the proposed Iraqi
Marshlands National Park area

Nabeel A. Abdulhasan

Nature Iraq, Sulaimani, Iraq

Corresponding author: Nabeel A. Abdulhasan (nabeel.abdulhassan@natureiraq.org)

Academic editors: F Krupp, I. Weidig | Received 15 March 2009 | Accepted 14 December 2009 | Published 28 December 2009

Citation: Abdulhasan NA (2009) Habitat Mapping Project of the Proposed Iraqi Marshlands National Park Area. In:
Krupp F, Musselman LJ, Kotb MMA, Weidig I (Eds) Environment, Biodiversity and Conservation in the Middle East.
Proceedings of the First Middle Eastern Biodiversity Congress, Aqaba, Jordan, 20-23 October 2008. BioRisk 3: 55-68.
doi: 10.3897/biorisk.3.19

Abstract

New ecological surveys in support of the creation of the proposed Iraqi Marshlands National Park were
undertaken by Nature Irag in June 2008 at the Central Marshes in southern Iraq. Surveys that occurred
in two focal areas - Al Chibaish Marsh (10 sites) and Abu Zirig Marsh (two sites) - were supported by a
preliminary land cover survey in November 2007. Satellite images from 2007 for the Central Marshes
were acquired to support creation of maps. The “Iraqi Marshlands Habitat Classification System” based
on vegetation types has been developed to inventory habitats in these marshlands and to develop a meth-
odology for application elsewhere in Iraq. Six habitat classes (inland running water, river or canal; inland
standing water; marsh vegetation; desert; woodlands; and herbaceous vegetation) are included in this clas-
sification system, each of which is divided into several subclasses. The dominant habitat subclasses in the
Central Marshes study area are: (1) rooted submerged vegetation, (2) helophytic vegetation (reed bed or
reed mace bed), (3) free-floating vegetation, (4) terrestrial vegetation-shrub, (5) unvegetated river or canal,
(6) unvegetated desert, and (7) flooded communities. This paper constitutes a review of the progress in

developing this habitat classification system that remains under development.

Keywords

Habitat mapping, Iraqi marshlands, marshland restoration

Copyright N.A.Abdulhasan. This is an open access article distributed under the terms of the Creative Commons Attribution License, which per-
mits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

56 Nabeel A. Abdulhasan/ BioRisk 3: 55—68 (2009)

Introduction

The Government of Iraq is currently considering the establishment of a new National
Park in a portion of the Central Marshes of southern Irag. A “Draft Management Plan
for the Central Marsh National Park, Iraq” has been developed (New Eden Group
2008). To assist in this planning process, a baseline habitat survey was deemed to be es-
sential. Thus, in 2007 Nature Irag with the financial support of the Italian Ministry of
Environment, Land and Sea initiated a project to identify, survey and map habitats in
the area of the proposed park in collaboration with the Iraq Ministry of Environment.
This habitat project is also related to other projects that Nature Iraq is carrying out
(such as the completion and implementation of a Management Plan for the Hawizeh
Marsh, Iraq’s first Wetland of International Importance designated under the global
Ramsar Convention in 2007; Rubec 2008). This paper discusses the national park
habitat mapping project.

The classification of vegetation types is usually achieved through the grouping of
similar types of vegetation according to logical criteria (Sayre et al. 2000). One of the
first attempts to classify marsh habitats was Warming (1909) in his book “Oecology of
Plants” which identified two major types of wetland depending on plant communities:
Saline swamp (with halophytic vegetation) and freshwater swamp. Mader (1991, cited
in Tiner 1999: 258) emphasized that classification should be: (1) Flexible, general, and
of wide geographic applicability in order to allow for the prediction of distribution
patterns over a range of environmental situations; (2) professionally credible, prefer-
ably through experimental validation; (3) based on concepts that are understandable
by non-technical people; (4) logical, consistent, and objectively quantifiable so as to
function within in empirical computer-operated information system; and (5) designed
and documented so that regular professional staff can, with nominal training, use the
system to identify and map field sites.

Adaptation of the European Nature Information System (EUNIS) habitat clas-
sification (Davies et al. 2004) was chosen as the model for classification of habitats
in this project. The EUNIS habitat types are classified hierarchically (Davies et al.
2004). Other habitat classification systems are also organized hierarchically and con-
tain descriptions of the classified units (FGDC 1996, Grossman et al. 1998). Thus, the
Nature Iraq team chose to establish Iraq's classification scheme based on vegetation in
addition to other criteria and emulate the experience in the references noted here. ‘The
Italian partners helped in developing the Iraqi project by assisting with training in the
use of the EUNIS system. After field testing, modifications were undertaken to make
it more applicable in Iraq’s marshlands.

Vegetation is the focal issue in this habitat study of a key area of Iraq’s southern
marshlands due to the importance of plants as food and shelter for people and wildlife.
This is supported by the economic value of many aquatic plants as food or in manufac-
turing and their role in cleaning water, and because these plants often are indicators of
hydrological and environmental conditions at the sites.

Habitat mapping project of the proposed Iraqi Marshlands National Park area 57

In the last few decades at various times (and again in 2008 due to drought), there
has been a significant reduction in the water levels in this area of southern Iraq, which
has led to a deterioration in water quality and changes in the distribution and status
of the biodiversity of the region. Monitoring of the impact of these variations in water
conditions has become critical to the marsh restoration efforts in Iraq.

Thus, one of the goals of this project is to improve the monitoring of the Iraqi
marshlands. Remote sensing and satellite imaging technology, it was hoped, should
improve the efficiency of monitoring field trips and reduce associated cost. Ground-
truth field data was essential to developing the classification scheme and to map the
habitats. Later, it was also felt that the level of effort to deliver the overall project
could be reduced if the satellite images indicated that there was significant change in
the study sites and the overall proposed national park area. To carry out this project,
the work was divided into three steps: S(I) Discussions and planning; (II) land cover
survey; and (III) description and definition of habitats.

Step I included discussions between Nature Iraq, Italian and other international
experts about how to carry out the project and what was needed to achieve it. Step
I also included the preparation of a work plan, definition of needs and the training
of staff. Step II was supported by an initial field trip in November 2007 designed to
identify land cover classes in the Central Marsh of the Al Chibaish Marsh area (CM)
and the Abu Zirig Marsh area (AZ). For Step III in June 2008, sites were identified as
habitats of specific species and described according to water quality, sediments, birds,
fish, benthic macroinvertebrates, zooplankton and phytoplankton, plants and habitat
characteristics and their status. The “Iraqi Marshlands Habitat Classification System”
is gradually being refined, but currently remains provisional.

Additional surveys supporting Step III will cover the environmental parameters
that can give Nature Iraq an indication of the environmental or economic values of
each habitat subclass. This information will help decision-makers to prepare plans for
ongoing marsh restoration and conservation of those sites that are important from
an environmental point view, such as the National Park in the Central Marshes and
Ramsar sites in Iraq.

Objectives

This project has three objectives:

— To survey and obtain specific data that can support Nature Iraq projects;

— ‘To use standard criteria for describing the status of the marshes in terms of vegeta-
tion cover, water quality and biodiversity; and

— ‘To facilitate conservation of these sites.

58 Nabeel A. Abdulhasan/ BioRisk 3: 55—68 (2009)

Materials and methods
Study area

The ground-truth field surveys focused on describing the ecological characteristics and
habitat structure at representative sites. All selected sites were within the proposed
Central Marshes National Park area and were distributed between the Al Chibaish
Marsh area and Abu Zirig Marsh area. Table 1 includes the names, codes and GPS
coordinates of each habitat survey site. The exploratory field trip conducted in Novem-
ber 2007 was the starting point of the project. By using satellite images from 2006,
an initial land cover survey and water quality study was conducted for nine candidate
survey sites in these marshes. There is also data from previous surveys in August 2007
for all of Iraq’s southern marshlands and their adjacent areas (Abdulhassan 2007). The
most recent survey was in June 2008 (by using another satellite image from 2007) and
some of the results of this work are presented in this paper. Twelve sites were surveyed
from the 14to 18 June 2008, ten of which were in Al Chibaish Marsh area and two
were in Abu Zirig Marsh area.

Satellite image processing
Remote sensing has long been identified as a technology capable of supporting the

development of habitat maps over large areas. Satellite images contain a information
regarding land and water characteristics and the application of digital image process-

Table 1. Site names and nodes, and GPS coordinates at Al Chibaish (CM) and Abu Zirig (AZ) for the
14 to 18 June 2008 habitat survey.

Area GPS soordinates

enn Name of site Site code No. Nelacinide E longitude
Al Baghdadia HAB-CM-5 47 0 52.5 31 2 50.6
Al Baghdadia HAB-CM-10 47 2 13.0 31 2 21.0
Um Lilo HAB-CM-11 47 2 16.9 31 1 28.7
Core area HAB-CM-12 46 31 4 S02
Core area HAB-CM-25 46 ai a 49.2
Core area HAB-CM-26 46 Bil 9 44.4

Abu Zirig | Close to Al-Fuhood Town HAB-AZ-1 46 46 30.1 30 59 4.8
Close to Al-Fuhood Town HAB-AZ-3 46 0 Siero)

Habitat mapping project of the proposed Iraqi Marshlands National Park area 59

ing allows for the extracting of data from a digital image very effectively. In the work,
remote sensing activities allowed for survey of the extension and the distribution of
the land cover classes of marshes and to ability to analyze the development of wetland
vegetation.

A first map of the Central Marshes was created on the basis of SPOT satellite im-
ages acquired in July 2006. The pre-processing of SPOT satellite data has included
radiometric calibration and atmospheric effect correction (dark object subtraction).
Image interpretation and analysis of vegetation indices allowed for the spectral analy-
ses of surfaces and the characterization of the different land cover classes. Then, su-
pervised image classification allowed the creation of detailed land cover maps at the
scale of 1:50,000.

In a second phase of the work, ASTER satellite images acquired in July 2007 were
processed to obtain updated maps of the study area. The same techniques of image
pre-processing and supervised classification used for the SPOT images were applied.
The monitoring survey ground-truthing gave parameters necessary to refine and vali-
date the land cover classification obtained from the remote sensing analysis. ‘The final
products, based on the “Iraqi Marshlands Habitat Classification System”, are land-
cover maps at the scales of 1:50,000 and 1:100,000 (see Fig. 1). It is expected that the
project can eventually permit effective, low-cost monitoring of these Iraqi marshlands
by applying remote sensing and satellite imaging technology.

Legend

= Habitat survey sites

: es National Park area

. | Land cover
- eI Dry lake

[waa] Dry marsh

cians Marsh vegetation high

| S| Marsh vegetation low

yf i ~ zz Marsh vegetation medium
-_ ||) Petccteat sutmerged vegetation

‘ | a) Permanent lake
:" aa . = Permanent lake (shallow)
> R.. Sparsely vegetated area
F =z Submerged vegetation

— =) Terrestrial vegetation

ee 7 [) wet son

7 See

*

all
es
3a

= i
Cc 2 ws. ¥

" bs ; BB ,
iq HAB_CM_13 e 3 & gs is @
oa

we gee

eHAB__CM_-5 HAB__CM__10~

HAB_CM_—11

Figure 1. Satellite-based land-cover classification of the Central Marsh (Al Chibaish and Abu u Ziti)

showing the selected survey sites (circled areas).

60 Nabeel A. Abdulhasan/ BioRisk 3: 55—68 (2009)

The Habitat Hectare Approach (HHA) for assessing habitat

In order to characterize vegetation classes and subclasses of high conservation priority
and to gather quantitative data on species richness, plot studies were used (as suggested
by Sayre et al. 2000). The number of plots at the site was determined by the range of dis-
tinct habitats defined in preliminary classifications of the sites (usually between one and
four habitat types). The HHA involves assigning a habitat score to a habitat zone that in-
dicates the quality of the vegetation relative to established benchmarks. This habitat score
can then be multiplied by the area of the habitat zone (in hectares) to determine the qual-
ity and quantity of vegetation (thus calculating “habitat hectares”). The components are
divided into two groups reflecting an assessment of both “site condition” and “landscape
context’. This is useful for habitat assessment and ground-truthing (DSE 2004). The
HHA method was applied in the ground-truthing exercises as a methodology to check
the classification of the land-cover classes resulting from remote sensing application. Due
to the broader complexity of the HHA method, only the determination of vegetation
cover from this method was applied within each hectare and without the scoring (Fig. 2).

Vegetation

Plant genera and species were identified using botanical keys (Townsend and Guest 1966,
1968, 1974, 1980a, 1980b, 1985). The descriptions of aquatic plants were checked us-
ing other Iraq-specific references (e.g. Al-Sa’ady and Al-Mayah 1983). Internet botanical
resources were also used to confirm the identification of some plant species (Google Im-
age Search 2008). Species were identified in the field where possible or collected in nylon
bags, pressed and transferred to the lab for identification with appropriate botanical
keys. These specimens are now preserved in Nature Iraq's herbarium in Sulaimani, Iraq.

Coordinates Coordinates

Coordinates Coordinates

Figure 2. Application of the Habitat Hectare Approach (HHA) method; field data sheet for describing
habitats (codes A-F indicate habitat classes).

Habitat mapping project of the proposed Iraqi Marshlands National Park area 61

Photographic records of fresh specimens were also used to aid identification. Percent
vegetation cover for each plant species found at each site was estimated (using the HAA
method) and used to calculate the total percentage vegetation cover for the whole site.

Results and discussion
Vegetation

The dominant vegetation type at each site was used as the basis for identifying the habitat
types. Some plant species were common and found at most of the sites while others were
restricted to one or two sites, but most of the identified plants are common in these Iraqi
marshes. Some species are native to Iraq such as Aeluropus lagopoides that exists near the
margins of the marshlands (Townsend and Guest 1968). Hydrilla verticillata is known to
be an invasive species in some parts of the world and may be a new exotic species in Iraq
as it was not mentioned in (Townsend and Guest 1985). Those authors listed only three
plant species belonging to Hydrocharitacea of which Aydrilla verticillata was not in-
cluded. It is possible that it was introduced during the period of great ecological change
that occurred with the drainage and later reflooding of the marshlands of southern Iraq
in the 1990s and after 2003. A noteworthy point about these plant communities is that
the reed growth probably expanded in the last few years because of the decrease in water
level (those species need a water depth of more than 2 m in the open water areas to avoid
reed expansion). This has led to the decrease of total open water area and the closing off
of many water passages due to the expansion of reeds. ‘Table 2 provides a listing of the
percentage vegetation cover at each of the 12 survey sites examined in June 2008.

Habitat classification system for the southern Marshlands of Iraq

Classification systems have been developed in order to divide habitats into groups with
similar features or functions. This is important in Iraq for identifying and describing
habitats in order to assess their biodiversity status and habitat functions and then estab-
lish conservation plans for Iraq's ecologically important habitats. As in many classifica-
tion systems, including the EUNIS (Davies et al. 2004), the classification developed
for Iraq’s habitats is organized hierarchically. It includes a description of the classes and
subclasses of habitats. This provisional Iragi system is modeled only partially on the
EUNIS system as some of the classes are chosen while others are not because they are
not applicable for Iraq’s marshlands. However, even the applicable parts were subjected
to some modifications to make them fit more readily with the uniqueness of Iraq’s
marshlands. For example, the class “permanent lake ice” that is used in the EUNIS
system, is excluded from Iraqi marshlands classification system because there is no such
habitat in the marshes of Iraq. Also, the class “permanent inland saline and brackish
lakes, ponds, and pools” was retained but under the subclass “salt water’.

62 Nabeel A. Abdulhasan/ BioRisk 3: 55—68 (2009)

Table 2. Vegetation cover (%) of each of 12 survey sites.

: 5 BS

| : S| R|R

Plant species = oj} es |
Aeluropus lagopoides
Alhagi graecorum

Ceratophyllum demersum
Chara sp.

Cressa cretica

Cynanchum acutum
Hydrilla verticillata

Myriophyllum sp.

*
WO

Sy)

= nn
af Nn

nt} * % 2
—
=p}

>

Najas marina

=| fei] | | fs] | [omen

i)
So
nN
Qo
So
Qo
So
nN
So
i)
So

Phragmites australis 50 | 50
Phoenix dactylifera

Potamogeton crispus

Potamogeton lucens ‘ 20 | ac 10
Potamogeton pectinatus PO | welO |, a 5 5 40

Potamogeton perfoliatus = sl

Salvinia natans 5 i ;
Schoenoplectus litoralis ‘ : 5 a al i
eee — eel ete :

Tamarix sp. i 20 20

Typha domingensis 20°°| 30. | -** |. 10 10 | 10 | 5 20 | 5 7

*

Vallisneria sp.

*Trace occurrence-detectable.

It is important to underscore that this is a provisional classification system that will
be modified in the future as more knowledge of Iraqi habitats is acquired. At this point,
it is divided into three major habitat categories: (1) Water, (2) marsh and (3) terrestrial
habitat. These three categories include six classes and each one of them is divided into
subclasses and, in some cases, secondary subclasses. Table 3 outlines the provisional
“Iraqi Marshlands Habitat Classification System” for the marshes of southern Iraq and
their associated surrounding terrestrial habitats.

Habitat Types

The proposed “Iraqi Marshlands Habitats Classification System” presented in Table 3 is
based on vegetation due to the ecological importance of vegetation communities and be-
cause vegetation is a result of the ecological conditions. Table 4 describes the specific habi-
tats seen within the study areas along with a basic site description of example study sites.

Habitat mapping project of the proposed Iraqi Marshlands National Park area 63

Table 3. Provisional “Iragi Marshlands Habitat Classification System”.

WATER
1. Inland running water, river or canal
1.1 Unvegetated rivers and canals
1.2 Submerged river and canal vegetation
1.3 Riparian vegetation
2. Inland standing water
2.1 Pond or lake — Unvegetated standing water
2.2 Unvegetated mudflat — Unvegetated mud, temporarily submerged and subject to water level
fluctuations
2.3 Flooded communities — Periodically or occasionally flooded land with phanerogamic
communities adapted to aquatic environments that are subjected to water level fluctuations and
temporary desiccation (Cyperus difformis, C. michelianus, C. laevigatus)
2.4 Aquatic communities — With aquatic vegetation communities formed by free floating
vegetation, rooted submerged vegetation or rooted floating vegetation
2.4.1 Free-floating vegetation — With floating vegetation communities (Lemna sp. pl.,
Salvinia natans, Spirodela polyrhiza) and Ceratophyllum demersum and Hydrocharis morsus-
ranae communities.
2.4.2 Rooted, submerged vegetation — Rooted submerged communities (Potamogeton sp. pl.,
Vallisneria spiralis, Myriophyllum sp., Najas sp. pl., Hydrilla verticillata)
2.4.3 Rooted, floating vegetation — Rooted formations with floating leaves (Mymphaea sp.
pl., Nuphar luteum, Nymphoides indica)
2.5 Salt water — — Saline ponds and lakes with phanerogamic communities
MARSH
3. Marsh Vegetation
3.1 Permanent Marsh
3.1.1 Helophytic vegetation
3.1.1.1 Reed bed (Phragmites australis beds)
3.1.1.2 Reed mace bed (Typha domingensis beds)
3.1.1.3 Schoenoplectus litoralis bed
3.1.1.4 Cladium mariscus vegetation —Cladium mariscus bed
3.1.2 Woody vegetation — Tree size formations with willow (Salix sp.) and poplars (Populus
sp.) within the marsh, excluding riparian treed formations having a linear structure
3.1.2.1 Riparian willow — Dominated by willow formations (Salix sp.)
3.1.2.2 Riparian poplar — Dominated by poplar formations (Populus sp.)
3.2 Brackish or saltwater marsh vegetation — Brackish or saline marshes with halophytic
vegetation
3.2.1 Salt pioneer swards — Pioneer communities growing on salt or brackish mudflat
(Salicornia sp. pl. community)
TERRESTRIAL HABITATS
4. Desert
4.1 Desert shrub
4,2 Unvegetated desert
4.3 Unvegetated saline lands
5. Woodlands
5.1 Woodland, forest and other wooded area
5.2 Shrub
6. Herbaceous vegetation
6.1 Grassland
6.2 Steppe
6.3 Sparsely vegetated land

64

Nabeel A. Abdulhasan/ BioRisk 3: 55—68 (2009)

Table 4. The habitat classes identified at each site with site description.

Central
March
CM

Types of habitat

2.4.2 Rooted submerged
vegetation

3.1.1.1 Helophytic
vegetation (reed bed)
3.1.1.2 Helophytic
vegetation (reed mace bed)
2.4.1 Free-floating
vegetation

General description of the site

This is an open water area that is adjacent to the road on
the east and surrounded by reed beds in the other directions;
there also are groups of reeds that are distributed randomly
inside the area. There are small groups of Typha sp. (reed
mace beds) and Schoenoplectus litoralis close to the road (in
the east side of area). The water is shallow. The open area is
covered by submerged plants and most of them are decayed
at the surface.

1.1 Unvegetated river and
canal

2.4.2 Rooted submerged
vegetation

3.1.1.1 Helophytic
vegetation (reed beds)
3.1.1.2 Helophytic
vegetation (reed mace beds)
2.4.1 Free-floating
vegetation

2.4.2 Rooted submerged
vegetation

3.1.1.1 Helophytic
vegetation (reed beds)

2.4.2 Rooted submerged
vegetation

3.1.1.1 Helophytic
vegetation (reed beds)
2.4.1 Free-floating
vegetation

Similar to Site CM-2 (thus an open water area with randomly
distributed reed groups). There is a road adjacent to the site
from the east and there are small 7ypha groups (on the east
side of the area). There are small areas beside the road where
submerged vegetation is absent and the water is deeper than
the rest of area. The submerged plants are more dense than
Site CM-2 but similarly decayed.

This is Lake is also known as a “Bargah”. It is a large open
water area with submerged vegetation and surrounded from
all directions by reeds (reed beds). There are small groups
of reed (known as “Tahala”) in the middle of the Bargah.

Fishing occurs in the area by nets and electroshock.

This is considered as an extension to Abu Sobatt canal, which
is an inlet to Al Baghdadia Lake (Bargah). This canal divides
the area into two sides (east and west) but the habitats are
the same on both sides of the canal. They have small open
water areas with a high density of submerged plants and
are surrounded by reeds and Typha from all directions. All
submerged plants are decayed on the surface of water. The
canal is bordered by a line of Typha followed by a line of reeds
on both sides. This is a water buffalo grazing area. There is
extensive fishing with nets in the moving water of the canal.

2.4.2 Rooted submerged
vegetation

3.1.1.1 Helophytic
vegetation (reed beds)
2.4.1 Free-floating
vegetation

2.3 Amphibious
communities

2.4.1 Free-floating
vegetation

3.1.1.1 Helophytic
vegetation (reed beds)
4.2 Unvegetated desert
6.3 Sparse vegetation

This open water area (known locally as “Bargah”) has
submerged vegetation in different densities. It is surrounded
on all sides by reeds beds and there are groups of reeds inside
the area of the Bargah. Most of the submerged plants are
decayed on the water surface. This area had been burned
before and the ground was brownish and included spots with
a low density of submerged plants.

A paved road divides this area into two sides: The west side is
an aquatic habitat with reed beds and a water passage close to
the road. There is also an area of high ground to the southwest
with terrestrial plants (Zamarix sp.) and aquatic plants (dry
Phragmites australis). The soil is wet indicating that this is a
seasonal marsh. ‘The east side includes three types of habitat,
(a)‘ in the northern portion are reed beds and reed mace beds;
(b)in the middle area is dry land without plants that is use by
the local people; and (c) in the southern portion is terrestrial
vegetation. This area includes high usage by water buffalo,
including breeding activity.

Habitat mapping project of the proposed Iraqi Marshlands National Park area 65

Central
March Types of habitat General description of the site
CM
3.1.1 Helophytic vegetation | ‘This is a dry area with a mix of terrestrial plants (to the
(reed beds) southwest) and aquatic plants (to the northwest and
4.1 Desert shrubs northeast). There is a small area that still contains some
2.4.1 Free-floating shallow water (5-20 cm depth). The area is considered a
vegetation seasonal marsh. There is a paved road adjacent to the area
on the west. There are many people who live along the
road and breed water buffalo. Note: The siting of this area
was determined by two coordinates to the west and the
description places it about 1 km toward the east.
5.1 Unvegetated desert This is a dry area (a seasonal marsh) with Phragmites that was
3.1.1 Helophytic vegetation | dry. It also has terrestrial plants (Zamarix sp. and Suaeda sp.).
(reed beds) There is a paved road to the east of area and as one moves
4.1 desert shrubs northward, the plant cover decreases and the area becomes
more desert-like.
3.1.1 Helophytic vegetation | This is a dry site (seasonally wet) that is located to the west of
(reed beds) a soil embankment that extends beside the area from north
4.1 desert shrubs to south. The entire area is covered by dry reeds with low
density intermixed with terrestrial vegetation (Zamarix sp.
and Suaeda sp.).
2.4.2 Rooted submerged The main part of this area is open water with rooted
vegetation submerged vegetation and surrounded by reed mace beds
3.1.1.2 Helophytic (Iypha domingensis) from the east and west. From the north
vegetation (reed mace beds) | there are reed beds. From the south, there is a small canal and
4.1 desert shrubs road. There are small soil embankments to the southeast of
2.4.1 Free-floating the area. The area is used for water buffalo grazing.
vegetation
Abu Zirig 1.1 Unvegetated riverand | The major habitat here is reed beds and there are small open
(AZ) canal water areas inside the reed beds. This area is adjacent to the

2.4.2 Rooted submerged
vegetation

3.1.1.1 Helophytic
vegetation (reed beds)
2.4.1 Free-floating
vegetation

1.1 Unvegetated river and
canal

2.4.2 Rooted submerged
vegetation

3.1.1.1 Helophytic

vegetation (reed beds)
2.4.1 Free-floating
vegetation

road on the south and to a soil embankment of the river that
is adjacent to the area and has openings that feed the marsh
with water from the river on the west side of the marsh. There
are date palm trees on the soil embankment. ‘This area is
considered a water buffalo grazing area; local people cut and
collect the reeds for water buffalo feeding and manufacturing

of goods. The area is close to Al Fuhood City.

This is a water passage (canal) with a depth of about 2 meters
and width of about 25—30 meters, bordered on both sides
by reeds that achieve heights of about 2—3 meters above the
water surface. The canal extends from north to south. There
are areas close to the reeds with dense and decayed submerged
plants, and there is a narrow area in the middle of an open,
moving water area devoid of plants and deeper than the rest
of canal. This area is used for breeding by some birds on the
submerged plants (the tops of these plants have emerged
above the water surface due to the decreasing water level).

66 Nabeel A. Abdulhasan/ BioRisk 3: 55—68 (2009)

Conclusions and recommendations

The study area and its 12 survey sites in the Central Marsh of Iraq, were set up to as-
sess the application in a real life situation of the Habitat Hectare Assessment (HHA)
methodology and to develop a practical classification system for Iraqi habitats based
on anticipated habitat classes that had been previously observed. A provisional hierar-
chical classification system, the “Iraqi Marshlands Habitat Classification System”, was
created to facilitate mapping these habitats into distinct units. Six habitat classes have
been identified, each of which is divided into several subclasses. However, the people
of the local communities in these marshes use specific terms to describe habitat types.
Two examples are “bargah” which means a pond or lake with unvegetated standing
water habitats, and “sibil” which means inland running water/river or canal. Efforts
are being made to associate these local names with the scientific categories that have
been identified so the classification system and maps becomes practical for local use.
This habitat classification system is still undergoing development and will be subjected
to further rigorous review.

The author urges consideration of the following recommendations that directly
consider plant diversity and the health of the habitats of the southern marshes of Iraq:

It is recommended that additional habitat survey work in other areas in Iraq be
initiated in order to verify the applicability of the provisional classification system and
its methodology.

In 2008, the Nature Iraq team observed that, in this area, water levels are still de-
creasing in addition to having on-going poor water quality conditions. To return to a
better state comparable to pre-1990 conditions (e.g. before drying of these marshes)
for both nature and the local people of the southern marshes of Iraq, it is recommend-
ed that Iraq should maximize the restoration of as much of the ecological character of
this area as possible.

Application of a standardized habitat classification is essential to monitoring of
the progress of this restoration effort. It is recommended that the provisional habitat
classification system discussed in this paper be completed and put into operational use
as soon as feasible.

The habitat types of greatest importance in restoration efforts will be those that
bring stability and economic value to the local communities. The area strongly needs
a permanent increase in the quantity of useable water to help restore habitats that are
critical to water buffalo for example, a mainstay of the local marsh people. Thus, it
is recommended that Iraq make all efforts to foster the restoration of its freshwater
sources that once flowed from the Euphrates River and the Tigris River.

Restoration of healthy habitats also requires improvement in water quality. It is
further recommended that the Government of Iraq should establish wastewater treat-
ment plants at the points of discharge in the cities that are located on the inlets of these
marshes and help to restore the hydrological regime. Increases of water quality and wa-
ter levels can likely assist in limiting the growth of reeds (such as Phragmites australis)
and help restore the ecological character of these marshes.

Habitat mapping project of the proposed Iraqi Marshlands National Park area 67

Finally, it is also recommended that stakeholders initiate training programs to re-
duce human disturbance and engage the local community in these restoration efforts
through education and awareness building about ecosystem health and the importance
of particular habitats.

Acknowledgements

Special thanks are extended to the local people who made this work easier by their
logistic support and to all Nature Iraq staff, in particular the habitat team. That
team includes: Mudafar A. Salim (birds), Muzher Shibel (macrophytes), Ghasak
S. Al Obaidi (phytoplankton), Suad Mohamed (phytoplankton), Mohamed Tagi
(macroinvertebrates), Ali Sadik (macroinvertebrates), Hussam J. Ali (water quality),
Haider A. Falih (laboratory testing), and Hussain Sh. Minjil (field assistant). Thanks
are also extended to Haider Abid (the initial project manager), and Nature Iraq’s
Italian partners including Mia Fant of Studio Galli Ingegneria Ltd. (SGI) in Italy,
the rest of the staff of SGI, and Medingegneria Ltd. for their advice and technical
assistance. We are also grateful to Clayton Rubec and Anna Bachmann for editorial
advice on earlier drafts of this paper. This project is funded by the Italian Ministry of
Environment, Land and Sea.

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