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Geography of Jordan
Geography of Jordan
Geography of Jordan
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31°00′N 36°00′E / 31.000°N 36.000°E / 31.000; 36.000

A map of Jordan.

Jordan is situated geographically in West Asia, south of Syria, west of Iraq, northwest of Saudi Arabia, east of Israel and the Palestinian territory of the West Bank. The area is also referred to as the Middle or Near East. Its territory covers about 91,880 square kilometres (35,480 sq mi).

Between 1950 and the Six-Day War in 1967, although not widely recognized, Jordan claimed and administered an additional 5,880 square kilometres (2,270 sq mi) encompassing the West Bank; in 1988 and with continuing Israeli occupation, King Hussein relinquished Jordan's claim to the West Bank in favor of the Palestinians.

Jordan's only coastline at its southern extremity, where nearly 26 kilometres (16 mi) of shoreline along the Gulf of Aqaba provides access to the Red Sea.


Area and boundaries

[edit]

Area:

  • total: 89,342 square kilometres (34,495 sq mi)
    • country rank in the world: 110th
  • land: 88,802 square kilometres (34,287 sq mi)
  • water: 540 square kilometres (208 sq mi)

Area comparative

  • Australia comparative: slightly more than 1/3 larger than Tasmania
  • Canada comparative: approximately ⁠1+1/4 times the size of New Brunswick
  • United Kingdom comparative: approximately 1/7 larger than Scotland
  • United States comparative: approximately the size of Maine
  • EU comparative: approximately the size of Portugal

Land boundaries:

  • total: 1,744 kilometres (1,084 mi)
  • border countries:

Coastline: 26 kilometres (16 mi)

  • note:
    • Jordan also borders the Dead Sea, for 50 kilometres (31 mi)

Maritime claims:

  • territorial sea:
    • nmi (5.556 km; 3.452 mi)

Elevation extremes:

Boundaries

[edit]
Borders of Jordan.

Except for small sections of the borders with Israel and Syria, Jordan's international boundaries do not follow well-defined natural features of the terrain. The country's boundaries were established by various international agreements and with the exception of the border with Israel, none was in dispute in early 1989.[citation needed]

Jordan's boundaries with Syria, Iraq, and Saudi Arabia do not have the special significance that the border with Israel does; these borders have not always hampered tribal nomads in their movements, yet for a few groups borders did separate them from traditional grazing areas and delimited by a series of agreements between the United Kingdom and the government of what eventually became Saudi Arabia) was first formally defined in the Hadda Agreement of 1925.[1]

Map of 1965 land swap between Jordan and Saudi Arabia

In 1965 Jordan and Saudi Arabia concluded an agreement that realigned and delimited the boundary. Jordan gained 19 kilometers of land on the Gulf of Aqaba and 6,000 square kilometers of territory in the interior, and 7,000 square kilometers of Jordanian-administered, landlocked territory was ceded to Saudi Arabia.[2] The new boundary enabled Jordan to expand its port facilities and established a zone in which the two parties agreed to share petroleum revenues equally if oil were discovered. The agreement also protected the pasturage and watering rights of nomadic tribes inside the exchanged territories.

Topography

[edit]
A satellite map of the Middle East with Jordan in the center.
A village near Al-Salt in the Balqa Governorate.
Wadi Rum in Southern Jordan.

The country consists mainly of a plateau between 700 metres (2,300 ft) and 1,200 metres (3,900 ft) meters high, divided into ridges by valleys and gorges, and a few mountainous areas. West of the plateau, land descents form the East Bank of the Jordan Rift Valley. The valley is part of the north-south Great Rift Valley, and its successive depressions are Lake Tiberias (Sea of Galilee; its bottom is about −258 metres (−846 ft)), Jordan Valley, the Dead Sea (its bottom is about −730 metres (−2,400 ft)), Arabah, and the Gulf of Aqaba at the Red Sea. Jordan's western border follows the bottom of the rift. Although an earthquake-prone region, no severe shocks had been recorded for several centuries.

By far the greatest part of the East Bank is desert, displaying the land forms and other features associated with great aridity. Most of this land is part of the Syrian Desert and northern Arabian Desert. There are broad expanses of sand and dunes, particularly in the south and southeast, together with salt flats. Occasional jumbles of sandstone hills or low mountains support only meager and stunted vegetation that thrives for a short period after the scanty winter rains. These areas support little life and are the least populated regions of Jordan.

The drainage network is coarse and incised. In many areas the relief provides no eventual outlet to the sea, so that sedimentary deposits accumulate in basins where moisture evaporates or is absorbed in the ground. Toward the depression in the western part of the East Bank, the desert rises gradually into the Jordanian Highlands—a steppe country of high, deeply cut limestone plateaus with an average elevation of about 900 meters. Occasional summits in this region reach 1,200 meters in the northern part and exceed 1,700 meters in the southern part; the highest peak is Jabal Ramm at 1,754 meters (though the highest peak in all of Jordan is Jabal Umm al Dami at 1854 meters. It is located in a remote part of southern Jordan). These highlands are an area of long-settled villages.

The western edge of this plateau country forms an escarpment along the eastern side of the Jordan River-Dead Sea depression and its continuation south of the Dead Sea. Most of the wadis that provide drainage from the plateau country into the depression carry water only during the short season of winter rains. Sharply incised with deep, canyon-like walls, whether flowing or dry the wadis can be formidable obstacles to travel.

The Jordan River is short, but from its mountain headwaters (approximately 160 kilometers north of the river's mouth at the Dead Sea) the riverbed drops from an elevation of about 3,000 meters above sea level to more than 400 meters below sea level. Before reaching Jordanian territory the river forms the Sea of Galilee, the surface of which is 212 meters below sea level. The Jordan River's principal tributary is the Yarmouk River. Near the junction of the two rivers, the Yarmouk forms the boundary between Israel on the northwest, Syria on the northeast, and Jordan on the south. The Zarqa River, the second main tributary of the Jordan River, flows and empties entirely within the East Bank.

A 380-kilometer-long rift valley runs from the Yarmouk River in the north to Al Aqaba in the south. The northern part, from the Yarmouk River to the Dead Sea, is commonly known as the Jordan Valley. It is divided into eastern and western parts by the Jordan River. Bordered by a steep escarpment on both the eastern and the western side, the valley reaches a maximum width of twenty-two kilometers at some points. The valley is properly known as Al Ghawr or Al Ghor (the depression, or valley).

The Rift Valley on the southern side of the Dead Sea is known as the Southern Ghawr and the Wadi al Jayb (popularly known as the Wadi al Arabah). The Southern Ghawr runs from Wadi al Hammah, on the south side of the Dead Sea, to Ghawr Faya, about twenty-five kilometers south of the Dead Sea. Wadi al Jayb is 180 kilometers long, from the southern shore of the Dead Sea to Al Aqaba in the south. The valley floor varies in level. In the south, it reaches its lowest level at the Dead Sea (more than 400 meters below sea level), rising in the north to just above sea level. Evaporation from the sea is extreme due to year-round high temperatures. The water contains about 250 grams of dissolved salts per liter at the surface and reaches the saturation point at 110 meters.

The Dead Sea occupies the deepest depression on the land surface of the earth. The depth of the depression is accentuated by the surrounding mountains and highlands that rise to elevations of 800 to 1,200 meters above sea level. The sea's greatest depth is about 430 meters, and it thus reaches a point more than 825 meters below sea level. A drop in the level of the sea has caused the former Lisan Peninsula to become a land bridge dividing the sea into separate northern and southern basins.

Climate

[edit]
A Köppen climate classification map of Jordan.
The countryside near Salt.
Snow in Amman.
Jordan is the seventeenth most water stressed country in the world.

The major characteristic of the climate is the contrast between a relatively rainy season from November to April and very dry weather for the rest of the year. With hot, dry, uniform summers and cool, variable winters during which practically all of the precipitation occurs, the country has a Mediterranean-style climate.

In general, the farther inland from the Mediterranean Sea a given part of the country lies, the greater are the seasonal contrasts in temperature and the less rainfall. Atmospheric pressures during the summer months are relatively uniform, whereas the winter months bring a succession of marked low pressure areas and accompanying cold fronts. These cyclonic disturbances generally move eastward from over the Mediterranean Sea several times a month and result in sporadic precipitation.

Most of the East Bank receives less than 120 millimeters (4.7 in) of rain a year and may be classified as a dry desert or steppe region. Where the ground rises to form the highlands east of the Jordan Valley, precipitation increases to around 300 millimeters (11.8 in) in the south and 500 millimeters (19.7 in) or more in the north. The Jordan Valley, lying in the lee of high ground on the West Bank, forms a narrow climatic zone that annually receives up to 300 millimeters (11.8 in) of rain in the northern reaches; rain dwindles to less than 120 millimeters (4.7 in) at the head of the Dead Sea.

The country's long summer reaches a peak during August. January is usually the coolest month. The fairly wide ranges of temperature during a twenty-four-hour period are greatest during the summer months and have a tendency to increase with higher elevation and distance from the Mediterranean seacoast. Daytime temperatures during the summer months frequently exceed 36 °C (96.8 °F) and average about 32 °C (89.6 °F). In contrast, the winter months—November to April—bring moderately cool and sometimes cold weather, averaging about 13 °C (55.4 °F). Except in the rift depression, frost is fairly common during the winter, it may take the form of snow at the higher elevations of the north western highlands. Usually it snows a couple of times a year in western Amman.

For a month or so before and after the summer dry season, hot, dry air from the desert, drawn by low pressure, produces strong winds from the south or southeast that sometimes reach gale force. Known in the Middle East by various names, including the khamsin, this dry, sirocco-style wind is usually accompanied by great dust clouds. Its onset is heralded by a hazy sky, a falling barometer and a drop in relative humidity to about 10 percent. Within a few hours there may be a 10 °F (5.6 °C) to 15 °F (8.3 °C) rise in temperature. These windstorms ordinarily last a day or so, cause much discomfort, and destroy crops by desiccating them.

The shamal, another wind of some significance, comes from the north or northwest, generally at intervals between June and September. Remarkably steady during daytime hours but becoming a breeze at night, the shamal may blow for as long as nine days out of ten and then repeat the process. It originates as a dry continental mass of polar air that is warmed as it passes over the Eurasian landmass. The dryness allows intense heating of the Earth's surface by the sun, resulting in high daytime temperatures that moderate after sunset.

Climate data for Amman
Month Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Year
Record high °C (°F) 23.0
(73.4) 		27.3
(81.1) 		32.6
(90.7) 		37.0
(98.6) 		38.7
(101.7) 		40.6
(105.1) 		43.4
(110.1) 		43.2
(109.8) 		40.0
(104.0) 		37.6
(99.7) 		31.0
(87.8) 		27.5
(81.5) 		43.4
(110.1)
Mean daily maximum °C (°F) 12.7
(54.9) 		13.9
(57.0) 		17.6
(63.7) 		23.3
(73.9) 		27.9
(82.2) 		30.9
(87.6) 		32.5
(90.5) 		32.7
(90.9) 		30.8
(87.4) 		26.8
(80.2) 		20.1
(68.2) 		14.6
(58.3) 		23.7
(74.66)
Daily mean °C (°F) 8.5
(47.3) 		9.4
(48.9) 		12.4
(54.3) 		17.1
(62.8) 		21.4
(70.5) 		24.6
(76.3) 		26.5
(79.7) 		26.6
(79.9) 		24.6
(76.3) 		21.0
(69.8) 		15.0
(59.0) 		10.2
(50.4) 		18.1
(64.6)
Mean daily minimum °C (°F) 4.2
(39.6) 		4.8
(40.6) 		7.2
(45.0) 		10.9
(51.6) 		14.8
(58.6) 		18.3
(64.9) 		20.5
(68.9) 		20.4
(68.7) 		18.3
(64.9) 		15.1
(59.2) 		9.8
(49.6) 		5.8
(42.4) 		12.5
(54.5)
Record low °C (°F) −4.5
(23.9) 		−4.4
(24.1) 		−3.0
(26.6) 		−3.0
(26.6) 		3.9
(39.0) 		8.9
(48.0) 		11.0
(51.8) 		11.0
(51.8) 		10.0
(50.0) 		5.0
(41.0) 		0.0
(32.0) 		−2.6
(27.3) 		−4.5
(23.9)
Average precipitation mm (inches) 60.6
(2.39) 		62.8
(2.47) 		34.1
(1.34) 		7.1
(0.28) 		3.2
(0.13) 		0.0
(0.0) 		0.0
(0.0) 		0.0
(0.0) 		0.1
(0.00) 		7.1
(0.28) 		23.7
(0.93) 		46.3
(1.82) 		245.0
(9.65)
Average precipitation days 11.0 10.9 8.0 4.0 1.6 0.1 0.0 0.0 0.1 2.3 5.3 8.4 51.7
Average relative humidity (%) 71.6 68.4 59.5 49.4 43.4 44.3 46.8 50.9 52.2 52.9 58.5 66.8 55.4
Average dew point °C (°F) 2.9
(37.2) 		3.5
(38.3) 		4.1
(39.4) 		5.1
(41.2) 		7.2
(45.0) 		10.6
(51.1) 		13.4
(56.1) 		14.6
(58.3) 		13.0
(55.4) 		9.6
(49.3) 		5.6
(42.1) 		3.4
(38.1) 		7.8
(46.0)
Mean monthly sunshine hours 179.8 182.0 226.3 266.6 328.6 369.0 387.5 365.8 312.0 275.9 225.0 179.8 3,289.7
Source 1: Jordan Meteorological Department[3]
Source 2: NOAA (sun 1961–1990),[4] Pogoda.ru.net (records)[5], Weather.Directory[6]
Ultraviolet index[7]
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Year
3 5 7 9 10 12 12 11 9 6 4 3 7.5

Resources and land use

[edit]
Phosphate mines in Jordan, east of the southerly Dead Sea

Natural resources: phosphates, potash, oil shale

Land use:

  • arable land: 2.41%
  • permanent crops: 0.97%
  • other: 96.62% (2012)

Irrigated land:

  • 788.6 square kilometres (304.5 sq mi) (2004)

Total renewable water resources:

  • 0.94 cubic kilometres (0.23 cu mi) (2011)

Freshwater withdrawal (domestic/industrial/agricultural):

  • total: 0.94 cubic kilometres (0.23 cu mi)/yr (31%/4%/65%)
  • per capita: 166 cubic metres (5,900 cu ft)/yr (2005)

Environmental concerns

[edit]
Main article: Environmental issues in Jordan

Droughts; occasional minor earthquakes in areas close to the Jordan Rift Valley

Environment – current issues: limited natural fresh water resources and water stress; deforestation; overgrazing; soil erosion; desertification

Environment – international agreements:
party to: Biodiversity, Climate Change, Climate Change-Kyoto Protocol, Desertification, Endangered Species, Hazardous Wastes, Law of the Sea, Marine Dumping, Ozone Layer Protection, Wetlands

See also

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Geography of Jordan

View on Grokipedia
from Grokipedia
The geography of spans approximately 89,342 square kilometers in the , northwest of and between to the east and to the west, with additional borders shared with to the north and to the south. Its terrain is dominated by a high desert plateau averaging 600 to 900 meters in elevation, interrupted by rugged highlands in the west rising to over 1,200 meters and the deep , which includes the Dead Sea—the lowest point on Earth's surface at about 430 meters below . This varied topography transitions eastward into the expansive , encompassing dramatic sandstone formations in areas like , while the western escarpment features more temperate uplands conducive to limited agriculture. 's climate is predominantly arid subtropical, with hot, dry summers and mild winters, though the western highlands experience a Mediterranean influence with rainfall up to 600 millimeters annually during the November-to-April , contrasting sharply with the near-rainless eastern deserts receiving less than 200 millimeters. Natural features such as the , which delineates much of the western boundary, and endorheic basins exacerbate , a defining challenge amplified by the country's reliance on aquifers and amid regional aridity. Significant mineral deposits, including phosphates and in the Negev-like southern regions, underpin , while flash floods in wadis and occasional seismic activity along the highlight dynamic environmental processes.

Location and Extent

Geographical Coordinates and Area

Jordan occupies a strategic position in the , with its approximate geographic center at 31°00′N 36°00′E. The country's territory spans latitudes from approximately 29°12′N at its southernmost point near to 33°22′N in the north, and longitudes from 34°52′E in the west to 39°12′E in the east. This positioning places Jordan in the northern and eastern hemispheres, encompassing diverse terrain from the to the eastern desert plateaus. The total area of Jordan measures 89,342 km² (34,495 sq mi), ranking it 110th globally by land area. Of this, land accounts for 88,802 km², while inland water bodies cover 540 km², primarily including portions of the Dead Sea and smaller reservoirs. These figures exclude maritime claims and disputed territories, reflecting the kingdom's predominantly arid, landlocked character except for its brief 26 km coastline on the . Jordan's compact size belies its geopolitical significance, as its area is roughly comparable to that of or the U.S. state of .

Borders and Neighboring Countries

Jordan is bordered by to the north, to the northeast, to the east and south, to the southwest, and the Palestinian territories of the to the west. The total length of its land boundaries measures 1,744 km. These borders, largely established during the post-World War I Mandate period and adjusted through subsequent agreements, enclose Jordan's territory in the arid region. The border lengths are as follows: with , 379 km; , 179 km; , 731 km; , 307 km; and the , 148 km. The Jordan- boundary was formalized by a 1984 agreement, ratified by Jordan but awaiting full Iraqi confirmation. The Israel- border, running along the , the Dead Sea, and into the Wadi Araba, was precisely demarcated following the 1994 signed on , which resolved prior ambiguities from lines. While no active territorial disputes persist, the borders face challenges from cross-border , particularly Captagon drugs from and security threats amid regional instability. Jordan maintains strict controls, including restricted zones near the Syrian frontier. Key crossings include the with the and Jaber with , facilitating trade and passage under monitored conditions.

Maritime Access and Coastline

Jordan maintains a limited maritime presence through its 26-kilometer coastline along the northern , part of the , which constitutes the country's only seaboard and averts complete landlock status. This coastal strip, situated in the extreme southwest, borders to the west across the gulf and to the south, with the terrain transitioning abruptly from arid desert plateaus to the sea. The itself extends approximately 160 kilometers northward, narrowing to as little as 5 kilometers in places, constraining navigable access and influencing regional maritime dynamics. The Port of , Jordan's exclusive seaport at the gulf's northern terminus, underpins national trade logistics as the primary conduit for imports and exports. Operated by the Aqaba Development Corporation with 12 specialized terminals across 32 berths, it processes over 36 million tons of annually, encompassing containers, dry bulk (such as phosphates and for export), liquid bulk (including derivatives), and general . Its deep-water harbor, connected to inland networks via highways and rail, positions it as a regional hub, handling roughly 70% of Jordan's foreign trade volume and supporting economic zones like the for and . Maritime jurisdiction includes a territorial sea of 3 nautical miles from the baseline, with boundaries in the delineated by a 1996 agreement with establishing an equidistant line. Jordan asserts rights over an , though its extent remains circumscribed by the gulf's geography and overlapping claims from adjacent states (, , ), limiting offshore resource exploitation primarily to fisheries and potential hydrocarbons.

Physical Geography

Topography and Major Landforms

Jordan's topography encompasses a varied shaped by tectonic activity and , featuring three primary physiographic zones aligned north-south: the in the west, the upland plateau in the center, and the arid Badia to the east. The , part of the Great Rift system, forms a deep depression averaging 1,200 to 2,000 meters below surrounding plateaus, with steep escarpments rising abruptly eastward. Central highlands, including the and Balqa regions, consist of folded ridges and dissected plateaus at elevations of 600 to 1,000 meters, incised by wadis such as and Wadi Hasa that create dramatic canyons. The eastern Badia region comprises a monotonous and plateau sloping gently from about 900 meters near the highlands to 600 meters at the borders, sparsely vegetated and featuring occasional outcrops from ancient lava flows. The lowest point in Jordan, and on Earth's land surface, is the Dead Sea at approximately -431 meters, where hypersaline waters accumulate in the rift's terminal basin due to endorheic drainage. The highest elevation, Jabal Umm ad Dami at 1,854 meters, rises in the southern Hisma highlands near the Saudi border, part of a rugged massif remnant from erosion. In the southeast, exemplifies erosional landforms, with towering jebels up to 1,750 meters, nabkhas dunes, and incised valleys formed by episodic flash floods sculpting and strata over millions of years. These landforms reflect Jordan's position astride the Arabian Plate's northwestern margin, where the Dead Sea Transform fault system drives ongoing in the rift and uplift in adjacent blocks, contributing to seismic activity and differential patterns observed in exposed strata from to ages. Mean national stands at 812 meters, underscoring the dominance of mid-altitude plateaus amid extremes.

Geological Formation and Structure

Jordan's geological structure is primarily shaped by its position on the northeastern margin of the Arabian Plate, adjacent to the African Plate along the fault system, a major left-lateral strike-slip boundary active since approximately 25-20 million years ago during the Oligo-Miocene. This tectonic regime has produced the , extending from the northward through the Wadi Araba and depression, characterized by pull-apart basins, horst blocks, and associated seismicity. The DST accommodates northward motion of the Arabian Plate at rates of 0.5-1.0 cm per year relative to the Sinai subplate. The tectonic history of Jordan encompasses three main phases: an early phase of stable platform sedimentation from the onward, a Syrian Arc phase involving to Eocene folding and thrusting due to convergence with the Eurasian Plate, and the dominant phase linked to rifting and DST development. During the phase, thick sequences of sandstones, such as the Salib Formation's pebbly sandstones deposited on alluvial plains, overlie basement rocks exposed in southern areas like . strata include widespread limestones and dolomites forming plateaus, while volcanism produced Neogene-Quaternary basalts in northern Jordan, erupted amid extensional stresses in the DST zone. Structurally, Jordan features a mosaic of fault-bounded blocks, with the flanked by uplifted shoulders like the Jordan Highlands to the west and the Trans-Jordan Plateau to the east. Syrian Arc-related anticlines and synclines deform carbonates in central and eastern regions, influencing aquifers and oil traps, though commercial hydrocarbons remain limited. In the south, Nubian aquifers extend from crystalline basement, while iconic features like the sandstone monoliths of result from differential erosion of Disi and Umm Ishrin formations within fault-controlled valleys. Seismic activity persists along the DST, with historical events like the 1033 CE earthquake underscoring ongoing tectonic strain.

Hydrography and Water Bodies

Jordan's hydrography is dominated by the , the country's principal perennial surface watercourse, which flows southward along the western border from the Yarmouk River confluence to the Dead Sea, spanning approximately 200 kilometers within Jordanian territory. The river originates from multiple springs in , , and , with its basin covering 43,200 square kilometers shared among Jordan, , , , and . Historical annual flow reached 1.3 billion cubic meters, but upstream diversions have reduced Jordan's share to about 200 million cubic meters per year as per the 1994 peace treaty with . The Yarmouk River, rising in and forming part of the northern border, serves as the 's main tributary, contributing seasonal flows influenced by Syrian dams. The terminates in the Dead Sea, a hypersaline terminal lake shared with and the , situated at an elevation of approximately 430 meters below , marking Earth's lowest land-based water body. With a maximum depth of 304 meters and averaging 34.2% as of , the Dead Sea lacks outlet and experiences rapid level decline of about 1 meter per year due to reduced inflow and . Its hydrographic isolation results from the Jordan Rift Valley's tectonic structure, where high exceeds precipitation and inflow. Ephemeral wadis constitute the bulk of Jordan's internal drainage network, channeling flash floods from rainfall into the or directly to the Dead Sea during winter storms. Major wadis include , Wadi Hasa, Wadi Karak, Wadi Yabis, and Wadi al-Arab, with flows highly variable and totaling under 100 million cubic meters annually on average. These intermittent streams carve deep canyons but contribute minimally to sustained due to the arid and porous . Groundwater forms the backbone of Jordan's water bodies, stored in 12 major aquifer basins overlying limestone, sandstone, and basalt formations deposited over millions of years. Key systems include the non-renewable Disi sandstone aquifer in the south, the Amman-Wadi Es Sir carbonate aquifer in the highlands, and the basalt aquifer in the northeast, collectively holding 80% of exploitable groundwater. Renewable groundwater recharge is estimated at around 600 million cubic meters per year, but extraction exceeds this by 50-100%, leading to declining levels and intrusion in coastal areas.

Climate Patterns

Climatic Classification and Zones

Jordan's climate falls primarily within the arid category of the Köppen-Geiger classification, dominated by hot desert (BWh) conditions that cover the vast majority of the country's 89,342 square kilometers, with smaller areas of hot semi-arid (BSh), cold semi-arid (BSk), and cold desert (BWk) subtypes influenced by and proximity to the Mediterranean. These classifications reflect low relative to high potential evapotranspiration, with over 90% of the land receiving less than 200 mm annually, rendering most regions hyper-arid to arid by standards (AI < 0.20 for hyper-arid, 0.20-0.50 for arid). The country divides into three main climatic zones aligned with physiographic features: the Jordan Rift Valley, the western highlands plateau, and the eastern desert (Badia). In the Jordan Valley, situated below sea level along the western border, subtropical-like conditions prevail with extreme summer heat often surpassing 40°C, mild winters averaging 19–22°C, and erratic winter rainfall of 100–300 mm concentrated in brief events, exacerbated by high evaporation rates that amplify aridity despite slightly higher totals. The highlands plateau, rising to 600–1,000 meters in the northwest and center, supports semi-arid Mediterranean influences with cooler temperatures (winter lows of 9–13°C, summer highs around 30°C) and more reliable precipitation of 250–600 mm per year, decreasing southward, enabling limited agriculture but still within BSh/BSk boundaries due to seasonal dryness. The expansive eastern desert plateau, comprising over half the territory, exemplifies BWh aridity with scant rainfall under 50 mm annually, diurnal temperature swings from over 40°C daytime highs to near-freezing nights in winter, and frequent dust storms driven by low and sparse . These zones transition gradually eastward from semi-arid to full , with topographic barriers like the highlands blocking moist Mediterranean air masses, causally reinforcing the east-west gradient observed in long-term records. Overall, 92.2% of qualifies as arid or semi-arid, underscoring vulnerability to independent of human factors.

Seasonal Variations in Temperature and Precipitation

Jordan displays marked seasonal contrasts in and , shaped by its Mediterranean-influenced northwest and arid southeastern expanses. Summers, spanning June through September, feature intense heat with average daily highs of 30–40°C (86–104°F) nationwide, peaking above 40°C (104°F) in the and southern deserts like ; nighttime lows remain mild at 18–25°C (64–77°F). Precipitation during this period is virtually absent, typically under 1 mm per month, as the region falls under persistent subtropical high pressure inhibiting moisture influx. Winters, from December to February, bring cooler conditions and the bulk of annual rainfall, driven by cyclonic storms from the Mediterranean. In central highlands around , average highs range from 12–15°C (54–59°F) and lows from 4–5°C (39–41°F), with frost and rare snowfall possible at elevations above 800 meters; southern lowlands experience milder highs near 20°C (68°F) but sharper diurnal swings. Monthly averages 50–65 mm in the northwest, accounting for 70–80% of yearly totals, though eastern deserts receive scant amounts under 10 mm. Transitional seasons of spring (March–May) and autumn (September–November) exhibit moderating temperatures, with highs declining from 25–30°C (77–86°F) in spring to 20–25°C (68–77°F) in autumn, alongside irregular showers totaling 10–40 mm monthly in wetter zones. Precipitation gradients intensify seasonally: northern uplands may accumulate 400–600 mm annually, concentrated in winter bursts that recharge aquifers, while Aqaba's coastal south logs under 50 mm total, with summer evaporation rates exceeding 2,000 mm yearly amplifying aridity. The table below summarizes average monthly conditions for , representative of the central plateau:
MonthAvg. High (°C)Avg. Low (°C) (mm)
January12463
February13562
March17743
April221014
May27145
June30170
July32190
August32190
September30171
October261311
November19925
December14550
Data reflect long-term averages, with interannual variability tied to El Niño-Southern Oscillation influences on winter tracks. Instrumental records indicate that Jordan's mean annual temperature has exhibited a warming trend since the early , with a rate of approximately 0.3°C per decade observed from 1961 onward. Minimum temperatures have risen faster than maximums, with annual minimum increases ranging from 0.4°C to 2.8°C since the , contributing to fewer frost days and extended growing seasons in higher elevations. This warming is most pronounced in regions, where heatwave frequency has increased, as evidenced by a rise in days exceeding 25°C by about 3 per decade in agricultural zones. Precipitation trends over the 1901–2010 period show a general decline of 5–20% across most of , based on analyses from regional institutions, though some highland and eastern Badia areas experienced minor increases of 5–10%. Annual totals, concentrated in winter months, have become more variable, with extended dry spells and reduced reliability in the semi-arid north and Mediterranean-influenced west. These patterns align with broader regional variability, influenced by factors such as the , but the long-term downward trajectory exacerbates aridity in a already receiving less than mm annually on average outside the . In recent decades (2000–2025), warming has accelerated, with maximum daily temperatures rising by roughly 0.66°C per decade, leading to more frequent and compounded water stress. has continued to decline, with national averages dropping to 89 mm in 2024 from higher levels in prior years, marking one of the driest periods on record amid successive . This has resulted in increased consecutive dry days and heightened intensity, particularly affecting and , as documented in meteorological station data and regional assessments. While year-to-year fluctuations persist due to teleconnections like El Niño, the overarching shift toward hotter, drier conditions underscores Jordan's vulnerability in an arid baseline .

Natural Resources

Mineral and Fossil Fuel Deposits

Jordan possesses substantial reserves of , estimated at approximately 1 billion metric tons, positioning the country as the seventh-largest globally in phosphate reserves. Phosphate extraction is dominated by the state-owned Jordan Phosphate Mines Company (JPMC), which operates four major mines, including the Eshidiya Mine that accounted for 65% of national production at 6 million metric tons of in 2019. These deposits, primarily located in central and southern regions such as Al-Abiad, Al-Hasa, and Al-Shidiya, support significant exports and contribute to the mineral sector's 7.6% share of GDP in 2019. Potash reserves, extracted from the Dead Sea through solar evaporation, rank Jordan twelfth worldwide, with production focused on high-quality potassium salts used in fertilizers. The Arab Potash Company operates the primary facilities, yielding millions of tons annually for export. Other notable mineral deposits include , , , dolomite, kaolin, and salt, with bromine exports derived from Dead Sea brines supporting industrial applications. Conventional reserves in are minimal, with proved oil at 1 million barrels and slightly exceeding that volume as of 2014. However, unconventional deposits are extensive, with over 70 billion tons of proven subsurface reserves equivalent to more than 7 billion tons of oil, concentrated in central regions like the and Sultani areas. The Attarat Oil Shale Power Plant, operational since 2021, utilizes these resources for , though production costs remain high compared to imported fuels. Exploration and development efforts continue to address energy import dependence, with viewed as a strategic domestic alternative despite environmental and economic challenges.

Water Availability and Management

Jordan possesses among the world's lowest renewable freshwater resources, with approximately 61 cubic meters available annually as of 2023, classifying it as experiencing absolute under the international threshold of 500 cubic meters . This scarcity stems primarily from the country's arid , limited averaging 111 mm annually nationwide, and geographic constraints, including dependence on shared transboundary rivers like the and Yarmouk River, which contribute only about 246 million cubic meters (MCM) of yearly. Groundwater from 28 major aquifers supplies around 234 MCM annually but faces severe overexploitation, with extraction rates exceeding safe yields by up to 160% in some basins, leading to declining water tables and intrusion of . To augment conventional sources, Jordan relies on non-conventional supplies, including desalinated and treated reuse. efforts, such as the planned plant on the , aim to provide up to 300 MCM annually by 2040, though current contributions remain minimal at under 5 MCM. Treated from 31 plants yields 186 MCM yearly, with 90% reused primarily for , offsetting freshwater demands in , which consumes 51% of total water use. Despite these measures, per capita availability is projected to drop below 40 liters per day by 2100 under baseline scenarios incorporating to 11 million and climate-induced reductions in . Water management is governed by the Ministry of Water and Irrigation through the National Water Strategy 2023–2040, which emphasizes integrated resources management, demand-side efficiency, and supply diversification. Key policies include metering to curb losses (currently 40–50%), subsidized tariffs for conservation incentives, and restrictions on agricultural abstraction to prioritize urban and industrial needs. The Third National Water Master Plan integrates surface and modeling for allocation, while projects like the Disi Conveyance System from southern s supply 110 MCM annually to , though sustainability concerns persist due to fossil aquifer depletion. Transboundary agreements, such as the 1994 Israel-Jordan peace treaty allocating Yarmouk flows, remain critical but are strained by upstream diversions and droughts.
Water SourceAnnual Volume (MCM)Primary UseNotes
Surface Water246Multi-sectoralShared rivers; variable due to precipitation and treaties
Groundwater234Agriculture (majority)Overexploited; salinization risks
Treated Wastewater186 (90% reused)IrrigationExpanding reuse to reduce freshwater pressure
Desalination<5 (projected 300 by 2040)Urban supplyRed Sea focus; energy-intensive
Challenges include inefficient use in (low-value crops like bananas), refugee influxes straining urban supplies, and variability exacerbating deficits, with success hinging on enforcement and international aid for .

Land Use and Ecosystems

Patterns of Land Utilization

Jordan's land utilization patterns are predominantly shaped by its arid climate and topographic variations, with over 88% of the total land area classified as , , or barren terrain primarily utilized for extensive by nomadic and semi-nomadic herders. accounts for approximately 11.5% of the land area as of 2021, encompassing arable fields, permanent crops, and permanent pastures, though actual cultivation is limited by . Of this, constitutes about 2% of the total land area, focused on rainfed production in the northern and western highlands, while permanent cropland, mainly orchards and vineyards, occupies around 1%. Irrigated agriculture, critical for higher-value crops like vegetables and fruits, is concentrated in the , which comprises roughly 5.6% of the country's agro-climatic zones but supports about 30% of cultivated land through surface and irrigation covering approximately 76,000 hectares. Rainfed farming, which dominates around 80% of the cropped area, relies on variable precipitation in the uplands for crops such as and , but yields are low and susceptible to . Permanent pastures, making up the bulk of at about 8.6%, sustain sheep and herding across semi-arid steppes, with traditional mobility patterns adapting to sparse vegetation. remains minimal at under 1% of land area, confined to scattered woodlands in higher elevations. Urban land use is limited to roughly 1-2% of the territory but is densely concentrated in the northern highlands around , , and , where and influxes have driven sprawl, encroaching on arable fringes and straining infrastructure. Desert regions in the east and south are largely unutilized except for phosphate mining, military reservations, and emerging projects, reflecting low population densities and harsh conditions that preclude intensive development. These patterns underscore a reliance on imported and water-efficient practices, with ongoing shifts toward protected areas and sustainable management to counter degradation from and .
Land Use CategoryPercentage of Total Land Area (approx. 2021)Primary Utilization
Agricultural Land11.5%Cropping and grazing
Arable2%Rainfed cereals
Permanent Crops1%Orchards, vineyards
Permanent Pasture8.5%Livestock herding
Forest<1%Conservation
Other (Desert, Urban, Barren)~87%Grazing, mining, urban centers

Biodiversity and Habitat Distribution

Jordan's reflects its position at the convergence of four biogeographic realms—Mediterranean, Irano-Turanian, Saharo-Arabian, and Sudanian—resulting in a mosaic of habitats ranging from semi-arid woodlands and riparian corridors to hyper-arid deserts and coastal marine environments. These habitats support approximately 2,622 species, representing about 1% of global , with roughly 100 endemics primarily confined to escarpments and systems where edaphic conditions foster unique adaptations. diversity includes 77-83 mammal adapted to terrestrial and semi-aquatic niches, 425-436 species (many migratory), 102 herpetofaunal taxa (predominantly reptiles), and limited freshwater fish (15 species) alongside over 1,000 marine species in the . However, 103 species are globally threatened, with mammals exhibiting the highest vulnerability due to and pressures. Habitat distribution correlates strongly with topographic and climatic gradients: northern highlands (elevations 500-1,500 m) host Mediterranean maquis and deciduous woodlands dominated by Quercus calliprinos (Palestine oak) and Pistacia palaestina, covering fragmented patches totaling less than 1% of land area and supporting higher floral density (up to 231 species per study quadrat in protected reserves). Central rift valley zones, including the Jordan River basin and Dead Sea vicinity, feature saline-tolerant halophytes and riparian thickets of Tamarix spp. and Populus euphratica, which sustain wetland-dependent herpetofauna and migratory avifauna. Eastern Badia steppe and southern desert expanses, comprising over 90% of Jordan's 89,342 km², are characterized by xeric shrublands with Artemisia and Zygophyllum dominants, interspersed with acacia (Acacia tortilis and A. raddiana) savannas totaling 2.3% of land; these arid habitats harbor desert-adapted mammals like the Arabian oryx (Oryx leucoryx) and sand cat (Felis margarita), though floral diversity plummets to sparse annuals reliant on episodic flash floods. Marine habitats at Aqaba, with coral reefs and seagrass beds, boost overall diversity via endemic echinoderms and mollusks (20% endemism rate). Endemic and range-restricted species underscore habitat specificity: floral endemics cluster in wadis of Dana and Mujib reserves, while faunal endemics like the bream (Acanthorutilus jordani) are restricted to freshwater drainages, and reptiles such as Acanthodactylus ahmaddisii (Jordanian fringe-fingered lizard) occupy sandy substrates in the southeast. BirdLife-designated Important Bird Areas, including Azraq wetlands and Yarmouk forests, concentrate breeding endemics and passage migrants, with conservation efforts targeting these hotspots amid -driven range contractions. Overall, gradients decline southward and eastward with increasing , where annual below 200 mm limits perennial vegetation to <5% cover, emphasizing the role of protected areas (covering ~10% of land) in preserving relict habitats against degradation.
Habitat TypeKey VegetationDominant FaunaDistribution
Mediterranean WoodlandsQuercus calliprinos, spp.Small mammals, resident birdsNorthern highlands (, Yarmouk)
Riparian/Wetlands, Herpetofauna, migratory waterbirds, Azraq Oasis
Xeric Shrublands/DesertsZygophyllum, spp.Desert ungulates, reptilesEastern Badia, southern wadis ()
Marine/CoastalSeagrasses, coralsFish, invertebrates

Environmental Dynamics

Key Challenges from and Human Activity

Jordan's geography is dominated by , with over 90% of its territory classified as or semi-desert, leading to chronic where annual renewable freshwater resources per capita stand below 75 cubic meters, well under the international threshold of 500 cubic meters. This natural constraint is intensified by recurrent droughts and limited , averaging less than 200 mm annually in most regions, restricting surface water availability to rivers like the and Yarmouk, which are heavily shared and depleted upstream. aquifers, such as the Disi, face at rates exceeding recharge by up to 160%, causing declining water tables and salinization that render sources unusable for and drinking. Human activities exacerbate these arid conditions through rapid , reaching over 11 million by 2023 including refugees, which has driven demand to surpass supply by approximately 500 million cubic meters annually. Urbanization, particularly in and , has spurred unplanned sprawl since the , increasing impervious surfaces, straining infrastructure, and promoting inefficient use in expanding settlements that encroach on arable lands. Agricultural practices, accounting for 50-60% of consumption despite contributing only 3-5% to GDP, involve over-irrigation with low-efficiency methods like flood systems, accelerating soil salinization and degradation across rain-fed highlands where cultivation without erodes topsoil. Desertification affects up to 70% of 's land, driven by combined with unsustainable , , and , resulting in reduced vegetation cover, , and heightened flood risks during rare heavy rains. , a key economic activity in central and southern regions, consumes substantial —up to 25% of local supplies in mining areas—while generating waste rocks that scar landscapes, release heavy metals like and into soils and waters, and contribute to dust affecting air quality and nearby communities. These anthropogenic pressures, absent rigorous enforcement of conservation, amplify natural 's toll, threatening and stability in a already importing 95% of its food needs.

Resource Exploitation Impacts and Mitigation Efforts

Phosphate mining, a cornerstone of 's , generates substantial environmental impacts including large volumes of rock that occupy land and pose hazards when discarded, alongside degradation from stripping and removal of phosphate-rich layers. The process consumes approximately 20 million cubic meters of freshwater annually, primarily , exacerbating scarcity in a already facing acute stress. Dust emissions, and release, and heavy metal contamination such as and further pollute air, , and , while elevated radioactivity in areas like Russifa heightens risks including potential cancer incidence. Extraction of and other minerals from the Dead Sea by the Jordanian Arab Potash Company contributes to the basin's declining water levels, which have dropped over 1 meter annually due in part to industrial pumping for evaporation ponds that facilitate mineral precipitation. This activity, combined with broader diversions, has led to waste accumulation at rates of 0.2 meters per year across approximately 140 square kilometers of ponds shared with , fostering formation and disruption. Overexploitation of aquifers, driven by agricultural and industrial demands, has depleted resources beyond safe yields since the late 1980s, degrading and contributing to and reduced recharge rates. Planned development poses additional risks, including heightened water consumption, air emissions from combustion, and potential contamination, though full-scale exploitation remains limited. Mitigation efforts by the Jordan Phosphate Mines Company (JPMC) include adherence to local and international environmental standards, with initiatives to reduce CO2 emissions by 30,000 metric tons through strategic operational shifts. Waste rock repurposing for concrete aggregates addresses and disposal issues, while rehabilitation projects employ water-efficient methods to separate from . Jordan's National Water Master Plan (2023-2040) promotes resilience via improved management, investments, and curbing illegal extractions to combat . For the Dead Sea, collaborative restorative actions have been proposed, though projects like the Red Sea-Dead Sea conduit remain stalled, limiting broader reversal of extraction-driven declines. Regulatory frameworks aim to enforce sustainable practices, yet enforcement gaps persist amid economic pressures from resource dependence.

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