Hydrogeology of Mozambique: Difference between revisions

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!colspan="4"| Sedimentary - Cretaceous-Tertiary
!colspan="4"| Sedimentary - Cretaceous-Tertiary
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|Mazamba Formation; Jofane Formation; Inhaminga Formation; Mangulane Formation; Mapai Formation
|Mazamba Formation; Jofane Formation; Inhaminga Formation; Mangulane Formation; Mapai Formation; Sena Formation; Lupata Group (Mazambulo Formation; Tchazica Formation)
||Largely Tertiary (Palaeogene-Neogene)
||Cretaceous (Tchazica Formation of Lupata Group is Jurassic) and Tertiary (Palaeogene-Neogene)
||Mazamba Formation, Neogene - arkosic sandstones, in part conglomeratic
||Mazamba Formation, Neogene - arkosic sandstones, in part conglomeratic
Jofane Formation, Neogene - sandstone and conglomeratic sandstone members, locally silicified. The Cabe Member comprises calcarenite, conglomerate and quartzite.
Jofane Formation, Neogene - sandstone and conglomeratic sandstone members, locally silicified. The Cabe Member comprises calcarenite, conglomerate and quartzite.
Inhaminga Formation, Neogene - Sandstone
Inhaminga Formation, Neogene - sandstone
Mangulane Formation, Palaeogene - Sandstone and limestone
Mangulane Formation, Palaeogene - sandstone and limestone
Sena Formation, Cretaceous - conglomerate and minor sandstone (including a thorium sandstone member), with a basal conglomerate member
Lupata Group, Jurassic-Cretaceous: Monte Mazambulo Formation - conglomeratic sandstone; Tchazica Formation - sandstone and conglomerate.


The Tertiary saw the formation of two separate Cenozoic sedimentary basins in the southeast and northeast of Mozambique:
 
The Cretaceous-Tertiary saw the formation of two separate Cenozoic sedimentary basins in the southeast and northeast of Mozambique:


The Southern or Mozambique Sedimentary Basin covers much of the southeast of Mozambique, and about 32% of the country as a whole, reaching a maximum width of 440km.
The Southern or Mozambique Sedimentary Basin covers much of the southeast of Mozambique, and about 32% of the country as a whole, reaching a maximum width of 440km.
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The Northern or Rovuma Sedimentary Basin extends along a narrow outcrop from the Tanzanian border south to Ilha de Mozambique, and has a maximum onshore width of 120km.  
The Northern or Rovuma Sedimentary Basin extends along a narrow outcrop from the Tanzanian border south to Ilha de Mozambique, and has a maximum onshore width of 120km.  


Both sedimentary basins were subject to several marine transgressions, the main one of which occurred in UPper Cretaceous and Tertiary. The sedimentary sequences are characterized by predominately continental series of arkosic sandstones in the western parts of the basins and mainly marine and transitional series in the coastal parts.
Both sedimentary basins were subject to several marine transgressions, the main one of which occurred in Upper Cretaceous and Tertiary. The sedimentary sequences are characterized by predominately continental series of arkosic sandstones in the western parts of the basins and mainly marine and transitional series in the coastal parts.


||Post-Karoo sedimentation was largely controlled by the development of the East African Rift System and related tectonic events. The Tertiary saw subsidence along deep N-S oriented troughs along the axis of the Mozambique Channel, in which sedimentation occurred. The sedimentary rocks are sometimes intensely faulted, but only slightly folded, with slightly developed arched structures. The best developed rift valleys are the Chire-Urema and the Funhalouro-Mabote grabens (the latter is part of the larger Mazunga Graben).
||Post-Karoo sedimentation was largely controlled by the development of the East African Rift System and related tectonic events. The Tertiary saw subsidence along deep N-S oriented troughs along the axis of the Mozambique Channel, in which sedimentation occurred. The sedimentary rocks are sometimes intensely faulted, but only slightly folded, with slightly developed arched structures. The best developed rift valleys are the Chire-Urema and the Funhalouro-Mabote grabens (the latter is part of the larger Mazunga Graben).
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!colspan="4"| Precambrian Basement Complex
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!colspan="4"| Geological Environment 3
|Archaean to Proterozoic
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||Many named groups and formations
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||The Precambrian Basement Complex occupies Manica, the western part of Sofala and almost the entire region north of the Zambeze. The formations of the northern part of Mozambique (a large part of the provinces of Zambezi, Nampula, Cabo Delgado and Niassa and the northern part of the province of Tete), comprise of high-grade metamorphic rock, forming part of the Mozambique Metamorphic Belt. This belt is dominated by gneiss and a gneiss-granite-migmatite complex with local meta sediments, charnockite series and a gabbro-anorthosite complex in the center of Tete province. In the Manica region (the Mozambican Province in the centre of the country, bordering Zimbabwe) one finds remnants of the Early Precambrian Zimbabwe Craton, dominated by greenschists.
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The Basement Complex includes many metamorphic and meta-igneous rock types, including granite, granofels, granodiorite, gneiss (including leucocratic gneiss, quartz-feldspar gneiss, orthogneiss, paragneiss, migmatitic paragneiss, granitic gneiss, calc-silicate gneiss, biotite-gneiss, mica gneiss, augen gneiss, magmatic gneiss and garnet gneiss), quartz diorite, tonalite, , gabbro, pyroxene diorite, garnet-sillimanite, metasiliciclastic sedimentary rocks, metagranite, hornblende gneiss, amphibolite, amygdaloidal andesitic lava, orthoquartzite, quartzite, arkosic quartzite, mafic metavolvanics including meta-tuff, siltstone, claystone, marble, meta-sandstone, muscovite-biotite schist, mica schist, arenaceous mica schist, migmatite, mylonite.
!colspan="4"| Geological Environment 3
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Revision as of 14:03, 29 July 2015

Africa Groundwater Atlas >> Hydrogeology by country >> Hydrogeology of Mozambique

Authors

Lucas Chairuca, National Directorate of Water, Mozambique

Arjen Naafs, WaterAid, UK

Ivo van Haren, WE Consult, Mozambique

Kirsty Upton and Brighid Ó Dochartaigh, British Geological Survey, UK


Geographical Setting

Map of Mozambique (For more information on the datasets used in the map see the geography resources section)

General

The Zambezi River divides Mozambique into two topographical regions: to the north, a narrow coastal strip gives way to inland hills and low plateaus; and further west to highland areas including the Niassa, Namuli or Shire, Angonia and Tete highlands and the Makonde plateau. To the south of the Zambezi River, the lowlands cover a larger area inland from the coast, rising to the Mashonaland plateau and Lebombo Mountains located in the deep south.

Estimated Population in 2013* 25,833,752
Rural Population (% of total) (2013)* 68.3%
Total Surface Area* 786,380 sq km
Agricultural Land (% of total area) (2012)* 63.5%
Capital City Maputo
Region Eastern Africa
Border Countries Malawi, South Africa, Swaziland, Tanzania, Zambia, Zimbabwe
Annual Freshwater Withdrawal (2013)* 884.2 Million cubic metres
Annual Freshwater Withdrawal for Agriculture (2013)* 78.0%
Annual Freshwater Withdrawal for Domestic Use (2013)* 19.2%
Annual Freshwater Withdrawal for Industry (2013)* 2.8%
Rural Population with Access to Improved Water Source (2012)* 35%
Urban Population with Access to Improved Water Source (2012)* 80%

* Source: World Bank


Climate

Mozambique has a tropical climate, with a general wet season (October to March) and dry season (April to September). However, local climate varies significantly according to altitude. The highest rainfall is in coastal areas, decreasing to the north and south. Annual precipitation varies from 500 to 900 mm across the country.

Rainfall time-series and graphs of monthly average rainfall and temperature for each individual climate zone can be found on the Mozambique Climate Page.


Average monthly precipitation for Mozambique showing minimum and maximum (light blue), 25th and 75th percentile (blue), and median (dark blue) rainfall Average monthly temperature for Mozambique showing minimum and maximum (orange), 25th and 75th percentile (red), and median (black) temperature Quarterly precipitation over the period 1950-2012 Monthly precipitation (blue) over the period 2000-2012 compared with the long term monthly average (red)

For further detail on the climate datasets used see the climate resources section.

Surface water

The country is drained by five principal rivers and several smaller ones. The largest and most important is the Zambezi River. There are four significant lakes: Lake Niassa (or Malawi), Lake Chiuta, Lake Cahora Bassa and Lake Shirwa, all in the north.









Surface Water Map of Mozambique (For more information on the datasets used in the map see the surface water resources section)

Soil

Soil Map of Mozambique (For map key and more information on the datasets used in the map see the soil resources section)

Land cover

Land Cover Map of Mozambique (For map key and more information on the datasets used in the map see the land cover resources section)


Geology

This section provides a summary of the geology of Mozambique. More detail can be found in the references listed at the bottom of this page. Many of these references can be accessed through the Africa Groundwater Literature Archive. The geology map on this page shows a simplified version of the geology at a national scale (see the Geology resources page for more details). The map is available to download as a shapefile (.shp) for use in GIS packages.

File:Mozambique Geology.png
Geological Environments
Key Formations Period Lithology Structure
Unconsolidated sedimentary
Coastal sand dunes; Alluvium; Interior aeolian sand dunes; Lacustrine limestones; Marine reef and bioclastic sediments; Sand sheets with local gravel Quaternary Almost 70% of the area underlain by sedimentary basins in Mozambique has a cover of unconsolidated sediment. This is very commonly a 5 to 10 m thick weathered layer of clayey sand, sometimes overlain by valley (alluvial) sand, aeolian sand, and rare colluvial deposits. Particular deposits are:

Coastal beach and dune sands.

Alluvium: alluvial sand, sandy soil, silt, gravel, lacustrine saline maud, pebble-bearing debris, estuarine and tidal flat sediment and back-barrier sediment.

Interior dune and red aeolian sand, including the Topuito Formation.

Lacustrine limestone.

Marine reef, coral and bioclastic sediment.

Sand sheets with local gravel.


Structure
Sedimentary - Cretaceous-Tertiary
Mazamba Formation; Jofane Formation; Inhaminga Formation; Mangulane Formation; Mapai Formation; Sena Formation; Lupata Group (Mazambulo Formation; Tchazica Formation) Cretaceous (Tchazica Formation of Lupata Group is Jurassic) and Tertiary (Palaeogene-Neogene) Mazamba Formation, Neogene - arkosic sandstones, in part conglomeratic

Jofane Formation, Neogene - sandstone and conglomeratic sandstone members, locally silicified. The Cabe Member comprises calcarenite, conglomerate and quartzite. Inhaminga Formation, Neogene - sandstone Mangulane Formation, Palaeogene - sandstone and limestone Sena Formation, Cretaceous - conglomerate and minor sandstone (including a thorium sandstone member), with a basal conglomerate member Lupata Group, Jurassic-Cretaceous: Monte Mazambulo Formation - conglomeratic sandstone; Tchazica Formation - sandstone and conglomerate.


The Cretaceous-Tertiary saw the formation of two separate Cenozoic sedimentary basins in the southeast and northeast of Mozambique:

The Southern or Mozambique Sedimentary Basin covers much of the southeast of Mozambique, and about 32% of the country as a whole, reaching a maximum width of 440km.

The Northern or Rovuma Sedimentary Basin extends along a narrow outcrop from the Tanzanian border south to Ilha de Mozambique, and has a maximum onshore width of 120km.

Both sedimentary basins were subject to several marine transgressions, the main one of which occurred in Upper Cretaceous and Tertiary. The sedimentary sequences are characterized by predominately continental series of arkosic sandstones in the western parts of the basins and mainly marine and transitional series in the coastal parts.

Post-Karoo sedimentation was largely controlled by the development of the East African Rift System and related tectonic events. The Tertiary saw subsidence along deep N-S oriented troughs along the axis of the Mozambique Channel, in which sedimentation occurred. The sedimentary rocks are sometimes intensely faulted, but only slightly folded, with slightly developed arched structures. The best developed rift valleys are the Chire-Urema and the Funhalouro-Mabote grabens (the latter is part of the larger Mazunga Graben).
Sedimentary - Mesozoic-Palaeozoic
Upper Karoo Group (Lualadzi Formation, Zumbo Formation), Magoe Formation Jurassic to Cretaceous Magoe Formation, Cretaceous - limestone and sandstone

Zumbo Formation, Upper Karoo Group, Triassic - sandstone and silicified sandstone Lualadzi Formation, Upper Karoo Group, Jurassic - red sandstone, locally silicified

The lower sequence of Karoo sedimentary rocks contains mainly very fine grained (largely mudstones), and sometimes contain carbonaceous beds. The upper sequence is more sandy.

Post-Cambrian crustal development was characterised by the break up of the supercontinent Gondwana. From Permian to Jurassic, rifts developed along the E-W trending Limpopo and Zambeze Belts, where deep troughs were filled with continental Karoo sediments, forming the Middle Zambeze Basin. In the north of Mozambique, the Maniamba Basin and smaller outcrops of Karoo sedimentary rocks form part of a larger Karoo basin in Tanzania.
Igneous
Karoo volcanic rocks and Post-Karoo largely intrusive igneous rocks, including the volcanic Movene Formation, Umbeluzi Formation (including Basalt Member), Rio Nhavudezi Formation, Bangomatete Formation, Rio Mazoe Formation; and intrusive igneous Gorongosa Suite and Rukore Suite Jurassic to Early Cretaceous The Karoo terminated with a period of intensive volcanic activity, dominated by basaltic and rhyolitic outflows, with the resulting rocks including basalt, rhyolite, andesite, tuff, ignimbrite and volcanic breccia. The volcanic sequence consists of a number of superposed lava flows, emerging from tension faults and fissures along the margins of the Basement Complex and along the widening Zambeze and Limpopo Basins. A line of outcrops is found along these margins, of which the Libombo Range in the southwest is the most important. The outcrops continue in a narrow strip to the north of the Zambeze. The basalt along the coast of Nampula province is considered to form part of the same system.

After Karoo volcanism, local igneous activities continued along borders of the East African Rift System and the Zimbabwe and Kaapvaal Cratons. The Post-Karoo igneous phenomena are dispersed and produced rocks with a wide variety of composition, genesis and age, including granite, syenite, gabbro, feldspar porphyry and mafic dykes. The late Jurassic to early Cretaceous batholith of the Serra da Gorongosa, consisting of gabbroic and granitic rocks, and the Middle Cretaceous alkaline lavas of the Lupata region are the most important features. More dispersed examples are the Cretaceous syenitic plutons of Milange, Chiperone and Derre and the carbonatite complexes and Upper Tertiary vents of basic to ultra-basic composition in the Sena region.

Precambrian Basement Complex
Archaean to Proterozoic Many named groups and formations The Precambrian Basement Complex occupies Manica, the western part of Sofala and almost the entire region north of the Zambeze. The formations of the northern part of Mozambique (a large part of the provinces of Zambezi, Nampula, Cabo Delgado and Niassa and the northern part of the province of Tete), comprise of high-grade metamorphic rock, forming part of the Mozambique Metamorphic Belt. This belt is dominated by gneiss and a gneiss-granite-migmatite complex with local meta sediments, charnockite series and a gabbro-anorthosite complex in the center of Tete province. In the Manica region (the Mozambican Province in the centre of the country, bordering Zimbabwe) one finds remnants of the Early Precambrian Zimbabwe Craton, dominated by greenschists.

The Basement Complex includes many metamorphic and meta-igneous rock types, including granite, granofels, granodiorite, gneiss (including leucocratic gneiss, quartz-feldspar gneiss, orthogneiss, paragneiss, migmatitic paragneiss, granitic gneiss, calc-silicate gneiss, biotite-gneiss, mica gneiss, augen gneiss, magmatic gneiss and garnet gneiss), quartz diorite, tonalite, , gabbro, pyroxene diorite, garnet-sillimanite, metasiliciclastic sedimentary rocks, metagranite, hornblende gneiss, amphibolite, amygdaloidal andesitic lava, orthoquartzite, quartzite, arkosic quartzite, mafic metavolvanics including meta-tuff, siltstone, claystone, marble, meta-sandstone, muscovite-biotite schist, mica schist, arenaceous mica schist, migmatite, mylonite.


Hydrogeology

This section provides a summary of the hydrogeology of the main aquifers in Mozambique. More information is available in the references listed at the bottom of this page. Many of these references can be accessed through the Africa Groundwater Literature Archive. The hydrogeology map on this page shows a simplified version of the type and productivity of the main aquifers at a national scale (see the Aquifer properties resource page for more details). The map is available to download as a shapefile (.shp) for use in GIS packages.

File:Mozambique Hydrogeology.png 


Unconsolidated

Named Aquifers General Description Water quantity issues Water quality issues Recharge

Sedimentary - Intergranular Flow

Named Aquifers General Description Water quantity issues Water quality issues Recharge

Sedimentary - Intergranular & Fracture Flow

Named Aquifers General Description Water quantity issues Water quality issues Recharge

Sedimentary - Fracture Flow

Named Aquifers General Description Water quantity issues Water quality issues Recharge

Basement

Named Aquifers General Description Water quantity issues Water quality issues Recharge


Groundwater Status

Groundwater quantity

Groundwater quality

Groundwater use and management

Groundwater use

Groundwater management

Groundwater monitoring

Transboundary aquifers

For further information about transboundary aquifers, please see the Transboundary aquifers resources page


References

The following references provide more information on the geology and hydrogeology of Mozambique. These, and others, can be accessed through the Africa Groundwater Literature Archive.

Geology: key references

A revised national geological map was published in 2008, as part of the Mineral Resources Management Capacity Building Project:

Republica de Mocambique - Ministerio dos Recursos Minerais – Direccao Nacional De Geologia. 2008. Carta Geologica Escala 1:1,000,000.

The Map Explanation has 4 volumes:

GTK Consortium. 2006. Carta Geologica Escala 1:1,000,000: Map Explanation, Volume 1. Describes the area south of the Save River

GTK Consortium. 2006. Carta Geologica Escala 1:1,000,000: Map Explanation, Volume 2. Describes the central part of Mozambique.

GTK Consortium. 2006. Carta Geologica Escala 1:1,000,000: Map Explanation, Volume 3. Describes the eastern-central part of Mozambique (Zambezi Province).

GTK Consortium. 2006. Carta Geologica Escala 1:1,000,000: Map Explanation, Volume 4. Describes the western-central part of Mozambique (Tete Province). Report_B6_f1_screen


Hydrogeology: key references

The main source of hydrogeological information for Mozambique is:

Ferro and Bouman / DNA. 1987. Explanatory Notes to the Hydrogeological Map of Mozambique: 1:1,000,000.

This map is largely based on the 1978 national geological map (Afonso 1987), and limited hydrogeological field data. The national geological map was updated in 2008 (see Geology: key references, above), but the 1987 national hydrogeological map has not yet been updated.


Other hydrogeological references are:

African Development Bank. 2002. Mozambique Water and Sanitation Sector Review. Prepared by SEED, May 2002.

African Development Bank. 2005. Rapid Assessment of Rural Water Supply and Sanitation. Mozambique Requirements for Meeting the MDGs, March 2005

British Geological Survey (BGS). 2002. Groundwater Quality: Mozambique.

DNA. 1999. Water resources of Mozambique.

Government of Mozambique (GOM). 1995. Política Nacional de Águas, Resolução do Conselho de Ministros nº 7/95 de 8 de Agosto, Boletim da República no. 34, 1ª Série de 23 de Agosto de 1995.

IWACO. 1986. Study of groundwater to supply Maputo.

Worldbank. 2007. Mozambique Country Water Resources Assistance Strategy: Making Water Work for Sustainable Growth and Poverty Reduction


The DNA (National Water Department), together with donors, particularly UNICEF, have carried out several drilling programs. Drilling reports from these programmes provide lithological information (typically simple but relatively accurate descriptions); borehole information (depth, location filters etc); and hydrogeological information (water levels, main water strikes, some water quality parameters). Proper pumping tests data are rare: most constant discharge tests were less than 1 hour, and in most cases only air-lift tests were done. This information from drilling programmes is not available in one report or single database: the DPOPH (Provincial Departments of Public Works and Housing) have databases with hydrogeological data per province.

Particular drilling programmes were:

ASNANI. 2004-2008. Executed by DNA and financed by ADB. Hundreds of boreholes drilled in Nampula and Niassa Provinces.

MCA (Millenium Challenge Account. 2008-2012. Hundreds of boreholes drilled in Nampula and Cabo Delgado Provinces.

UNICEF One Million Initiative. 2008-2012. Hundreds of boreholes drilled in the Tete, Manica and Sofala Provinces.


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Africa Groundwater Atlas >> Hydrogeology by country >> Hydrogeology of Mozambique