Electricity in Syria

Last updated

Electricity sector of Syria
Pylon transformer in Syria.jpg
Pylon transformer
Data
Installed capacity (2024)3500 MW (estimate) [1]
Electricity generation in Syria by source Electricity-prod-source-stacked Syria.png
Electricity generation in Syria by source

According to the International Energy Agency in 2022 almost all electricity was generated from oil and fossil gas, like energy in Syria. [2] But according to Anadolu Agency as of 2024 most generation is hydro. [3] In 2024 electricity grids needed war damage to be repaired. [4] As of 2024 generation by power stations in Syria cannot meet demand, resulting in power cuts and air pollution from small diesel generators. [5] As the country has plenty of sunshine solar power could be expanded. [6]

Contents

History

Pre-2011

In the 2000s, Syria's electric power system struggled to meet the growing demands presented by an increasingly energy-hungry society. Demand grew by roughly 7.5% per year during this decade, fueled by the expansion of Syria's industrial and service sectors, the spread of energy-intensive home appliances, and state policies (i.e. high subsidies and low tariffs) that encouraged wasteful energy practices. [7] [8] Syria's inefficient transmission infrastructure compounded these problems: In 2002, Electricity Minister Munib Saem al-Daher stated that 26% of the country's total electricity production was wasted in transmission, amounting to USD 57.7 billion in losses. [9] These factors together resulted in increasingly frequent power cuts, which in turn fueled public frustration. [10]

Throughout this period, the Syrian government sought to close the supply gap by investing in new electricity generation infrastructure. Investments moved away from oil-powered infrastructure and toward gas-fueled power plants, [11] reflecting Syria's declining domestic oil production, improved access to natural gas, and the superior efficiency of gas-fed combined cycle power plants. [7] New investments relied significantly on international technical expertise to execute projects, notably by the German firm Siemens, [12] but also by firms hailing from Iran, [13] India, [14] and elsewhere. They also relied on international financing, including from the European Investment Bank [15] and the Arab Fund for Economic and Social Development. [16]

Wartime disruption

The Syrian civil war wrought havoc on the country's electricity system, leading to increasingly frequent blackouts across the country, disruptions to all forms of economic activity, [17] and reports that electrical fires increased due to problems with the electrical grid. [18]

Infrastructural damage

Swathes of Syria's generation and transmission infrastructure were damaged or destroyed, due to a combination of bombardment by Syrian government forces, aerial attacks by the US-led international military intervention against the Islamic State, attacks by insurgent groups, and looting by armed factions. Between 2015 and 2017, violence and looting destroyed three major power plants, namely the Aleppo Thermal Station, Zayzoon in Idlib, and al-Taim in Deir Ezzor. Pre-war, these three plants had accounted for almost one-fifth of Syria's total generation capacity. In 2021, Syria's Ministry of Electricity estimated total losses to the electricity sector at USD 2.4 billion. [7]

Resource scarcity

In addition to infrastructural damage, war also left Syria with acute shortages of the fuel and water needed to power Syria's thermal and hydroelectric infrastructure. On one side, the Syrian government's loss of major oil and gas fields first to the Islamic State and then to the Autonomous Administration of North and East Syria contributed to extreme fuel scarcity and thus a reliance on imports, notably from Iran. [19] On the other, rising temperatures, diminished rainfall, and Turkish restrictions on the flow of the Euphrates River brought the latter's water levels to a crisis point, thus threatening the capacity of the three dams located along the Euphrates in Syria: namely the Tabqa Dam, Baath Dam, and Tishrin Dam. [20] [21] [22]

Expertise scarcity

Pre-2011, Syria relied heavily on foreign expertise to spearhead the most complex forms of investment in Syria's electrical sector, including repairing and installing generation infrastructure. After a decade of war, the combination of international sanctions and foreign exchange shortages had created major obstacles to bringing in foreign expertise. [7] To make matters worse, Syria's own pool of homegrown technical competence was reduced by a relentless brain drain [23] and devastating setbacks to the country's education sector. [24]

Sanctions

International sanctions against Syria further undermined Syria's electricity sector, including by barring foreign (i.e. European and Arab) entities from extending loans or implementing infrastructure projects and by straining Syria's ability to import fuel and spare parts. [7]

2021

A 2021 report by the European University Institute said:

"Before the 2011 conflict, Syria’s electricity infrastructure was barely functional. There were high production and transmission losses with frequent load shedding, especially in the summer. Syria had poor structural and performance indicators: power losses stood at nearly 26% and there were 43 days of power outage per year. Tariffs were low due to heavy government subsidies.

However, ten years of war has worsened matters considerably. Per capita consumption of state electricity is 15% of what it was in 2010. For instance, in the first half of 2021, Aleppo had ten-hours of rationing for every hour or half an hour of power; Damascus had, instead, five “dead” hours for one hour of electricity. The damage to the grid and substations can be fixed at reasonable rates with local expertise. This is not the case, though, with power generation plants. The conflict saw four of the 14 plants suffer serious damage, representing nearly 18% of the pre-war installed capacity nationwide. Two other plants near Hama and Damascus have also been damaged but have since been partially repaired.

In 2021, the Ministry of Electricity estimated the sector’s production and transmission reconstruction cost at USD 2.4 billion. Though difficult to quantify, indirect losses in lost output in other sectors due to electricity cuts are likely to be orders of magnitude higher. Firms in regime-held areas identify the interruption to essential services as their main obstacle to doing business.

Renewable energy use was falling even before the conflict, from 20% in the early 1990s to 5% as the conflict began. With the continued slowdown in water flow from Turkey and the failure to fix hydroelectric turbines, hydro sources contributed only 2% of public supply in 2020. While the government has made it easier for private investors to participate in the green electricity sector, especially wind and solar energy, their contribution remains negligible.

Despite much talk and numerous memoranda of understanding, very little of the production capacity has been repaired. The country’s two principal backers, Russia and Iran, have shown little appetite for following through on agreements due to the government’s inability to secure funding. The country’s most pressing need is not restoring its production capacity, but, rather, sourcing enough fuels to reach its existing potential and fixing the damaged grid. These electric-related problems are complex and regional politics, sanctions, and technical issues all play their part. But Syria’s current electricity crisis is, at base, financial." [7]

Interconnectors

There is interconnection with electricity in Turkey. [25]

Government

The Ministry of Electricity (Arabic: وزارة الكهرباء) is a department of the Government of Syria. [26] The ministry is responsible for managing the electric energy and renewable energy sector in Syria, and a number of governmental institutions and companies are affiliated to it.

Related Research Articles

<span class="mw-page-title-main">Renewable energy</span> Energy collected from renewable resources

Renewable energy is energy from renewable natural resources that are replenished on a human timescale. The most widely used renewable energy types are solar energy, wind power, and hydropower. Bioenergy and geothermal power are also significant in some countries. Some also consider nuclear power a renewable power source, although this is controversial. Renewable energy installations can be large or small and are suited for both urban and rural areas. Renewable energy is often deployed together with further electrification. This has several benefits: electricity can move heat and vehicles efficiently and is clean at the point of consumption. Variable renewable energy sources are those that have a fluctuating nature, such as wind power and solar power. In contrast, controllable renewable energy sources include dammed hydroelectricity, bioenergy, or geothermal power.

India is the third largest producer of electricity in the world. During the fiscal year (FY) 2023–24, the total electricity generation in the country was 1,949 TWh, of which 1,734 TWh was generated by utilities.

<span class="mw-page-title-main">Energy in Iran</span>

Energy in Iran is characterized by vast reserves of fossil fuels, positioning the country as a global energy powerhouse. Iran holds the world's third-largest proved oil reserves and the second-largest natural gas reserves as of 2021, accounting for 24% of the Middle East's oil reserves and 12% of the global total.

<span class="mw-page-title-main">Energy in Brazil</span>

Brazil is the 7th largest energy consumer in the world and the largest in South America. At the same time, it is an important oil and gas producer in the region and the world's second largest ethanol fuel producer. The government agencies responsible for energy policy are the Ministry of Mines and Energy (MME), the National Council for Energy Policy (CNPE), the National Agency of Petroleum, Natural Gas and Biofuels (ANP) and the National Agency of Electricity (ANEEL). State-owned companies Petrobras and Eletrobras are the major players in Brazil's energy sector, as well as Latin America's.

Brazil has the largest electricity sector in Latin America. Its capacity at the end of 2021 was 181,532 MW. The installed capacity grew from 11,000 MW in 1970 with an average yearly growth of 5.8% per year. Brazil has the largest capacity for water storage in the world, being dependent on hydroelectricity generation capacity, which meets over 60% of its electricity demand. The national grid runs at 60 Hz and is powered 83% from renewable sources. This dependence on hydropower makes Brazil vulnerable to power supply shortages in drought years, as was demonstrated by the 2001–2002 energy crisis.

Electricity in Pakistan is generated, transmitted and distributed by two vertically integrated public sector companies, first one being Water and Power Development Authority (WAPDA) responsible for the production of hydroelectricity and its supply to the consumers by electricity distribution companies (DISCOS) under the Pakistan Electric Power Company (PEPCO) being the other integrated company. Currently, there are 12 distribution companies and a National Transmission And Dispatch Company (NTDC) which are all in the public sector except Karachi Electric in the city of Karachi and its surrounding areas. There are around 42 independent power producers (IPPs) that contribute significantly in electricity generation in Pakistan.

<span class="mw-page-title-main">Electricity sector in Iraq</span>

Iraq's electricity generation primarily depends on fossil fuels. In 2021, natural gas was the largest source at 57.3% of the total, followed by oil at 36.7%. Renewable energy, mainly from hydroelectric power, contributed 5.9%. As of 2023, the 30 gigawatts (GW) of installed capacity cannot meet summer peak demand.

<span class="mw-page-title-main">Electricity sector in Bangladesh</span>

The utility electricity sector in Bangladesh has one national grid operated by Power Grid Company of Bangladesh with an installed capacity of 25,700 MW as of June 2022. Bangladesh's energy sector is not up to the mark. However, per capita energy consumption in Bangladesh is considered higher than the production. Electricity was introduced to the country on 7 December 1901.

Different methods of electricity generation can incur a variety of different costs, which can be divided into three general categories: 1) wholesale costs, or all costs paid by utilities associated with acquiring and distributing electricity to consumers, 2) retail costs paid by consumers, and 3) external costs, or externalities, imposed on society.

<span class="mw-page-title-main">Energy in Ukraine</span>

Energy in Ukraine is mainly from gas and nuclear, followed by oil and coal. Ukraine has a diversified energy mix, and no fuel takes up more than a third of the country’s energy sources. Most gas and oil is imported, but since 2015 energy policy has prioritised diversifying energy supply.

<span class="mw-page-title-main">Energy in Syria</span>

Energy in Syria is mostly based on oil and gas. Some energy infrastructure was damaged by the Syrian civil war. There is high reliance on fossil fuels for energy in Syria, and electricity demand is projected to increase by 2030, especially for industry activity such as automation. However, conflict in Syria has caused electricity generation to decrease by nearly 40% in recent years due to plant destruction and fuel shortages. Electricity access in daily life for Syrians has also been altered due to conflict. Electricity to residents of Syria is largely provided by private diesel generators, which is costly and limited in hours of use. Conflict has increased household electricity expenditures while also decreasing household income. Some households have since turned to solar energy as a supplementary source of energy, though high costs limit widespread adoption.

<span class="mw-page-title-main">Energy in Lebanon</span>

Energy in Lebanon is characterized by a heavy reliance on imported fuels, which has led to significant challenges in ensuring a stable and sufficient supply of electricity. The country’s energy sector has been severely affected by a combination of internal political instability, external conflicts, and systemic corruption. The reliance on imported energy, coupled with rising demand and frequent infrastructure failures, has led to an ongoing energy crisis. This crisis has been further exacerbated by the destructive effects of military conflicts involving Hezbollah, particularly the wars against Israel and the war in Syria, which have strained the country's infrastructure and economy.

<span class="mw-page-title-main">Energy in Turkey</span>

Energy consumption per person in Turkey is similar to the world average, and over 85 per cent is from fossil fuels. From 1990 to 2017 annual primary energy supply tripled, but then remained constant to 2019. In 2019, Turkey's primary energy supply included around 30 per cent oil, 30 per cent coal, and 25 per cent gas. These fossil fuels contribute to Turkey's air pollution and its above average greenhouse gas emissions. Turkey mines its own lignite but imports three-quarters of its energy, including half the coal and almost all the oil and gas it requires, and its energy policy prioritises reducing imports.

Energy in Sudan describes energy and electricity production, consumption and imports in Sudan. The chief sources of energy in 2010 were wood and charcoal, hydroelectric power, and oil. Sudan is a net energy exporter. Primary energy use in Sudan was 179 TWh and 4 TWh per million persons in 2008.

<span class="mw-page-title-main">Hydroelectricity in Turkey</span>

Hydroelectricity is a major source of electricity in Turkey, due to its mountainous landscape and many rivers. The country's main river basins are the Euphrates and Tigris. Over 700 hydropower plants have been built, and they make up about 30% of the country's electricity generating capacity. Annual generation varies greatly, and in rainy years lots of hydroelectric power can be generated. Government policies have generally supported building dams, but some are controversial in neighbouring countries, and some raise concerns about damage to the environment and wildlife.

<span class="mw-page-title-main">Renewable energy in Turkey</span>

Renewables supply a quarter of energy in Turkey, including heat and electricity. Some houses have rooftop solar water heating, and hot water from underground warms many spas and greenhouses. In parts of the west hot rocks are shallow enough to generate electricity as well as heat. Wind turbines, also mainly near western cities and industry, generate a tenth of Turkey’s electricity. Hydropower, mostly from dams in the east, is the only modern renewable energy which is fully exploited. Hydropower averages about a fifth of the country's electricity, but much less in drought years. Apart from wind and hydro, other renewables; such as geothermal, solar and biogas; together generated almost a tenth of Turkey’s electricity in 2022. Over half the installed capacity for electricity generation is renewables.

The electricity sector in Nigeria generates, transmits and distributes megawatts(MW) of electric power that is significantly less than what is needed to meet basic household and industrial needs. Nigeria has twenty-three (23) power-generating plants connected to the national grid with the capacity to generate 11,165.4 MW of electricity. These plants are managed by generation companies (GenCos), independent power providers, and Niger Delta Holding Company. In 2012, the industry labored to distribute 5,000 MW, very much less than the 40,000 MW needed to sustain the basic needs of the population. This deficit is also exacerbated by unannounced load shedding, partial and total system collapse and power failure. To meet demand, many households and businesses resort to purchasing generating sets to power their properties; this source of energy provided 6,000 MW in 2008. Nigeria has a chronic electricity shortage that has affected the country for many years. In 2022, its power grid collapsed twice in one week.

<span class="mw-page-title-main">Electricity in Turkey</span> Electricity generation, transmission and consumption in Turkey

Turkey uses more electricity per person than the global average, but less than the European average, with demand peaking in summer due to air conditioning. Most electricity is generated from coal, gas and hydropower, with hydroelectricity from the east transmitted to big cities in the west. Electricity prices are state-controlled, but wholesale prices are heavily influenced by the cost of imported gas.

<span class="mw-page-title-main">Hydroelectricity in China</span>

Hydroelectricity is currently China's largest renewable energy source and the second overall after coal. According to the International Hydropower Association, China is the worlds largest producer of hydroelectricity as of 2021. China's installed hydroelectric capacity in 2021 was 390.9 GW, including 36.4 GW of pumped storage hydroelectricity capacity, up from 233 GW in 2011. That year, hydropower generated 1,300 TWh of power, an increase of 68 TWh over 2018 when hydropower generated 1,232 TWh of power, accounting for roughly 18% of China's total electricity generation.

Denmark is a leading country in renewable energy production and usage. Renewable energy sources collectively produced 81% of Denmark's electricity generation in 2022, and are expected to provide 100% of national electric power production from 2030. Including energy use in the heating/cooling and transport sectors, Denmark is expected to reach 100% renewable energy in 2050, up from the 34% recorded in 2021.

References

  1. "Turkey ready to supply power to Syria and Lebanon, energy minister says". Reuters .
  2. "Syria - Countries & Regions". IEA. Retrieved 2024-12-21.
  3. "Opposition Syrian National Army liberates dam on Euphrates River from terrorist PKK/YPG". www.aa.com.tr. Retrieved 2024-12-21.
  4. "For Syria's Economy, the Way Forward Starts With Sanctions Relief". 2024-12-21. Archived from the original on 2024-12-21. Retrieved 2024-12-21.
  5. "Dark times: Syria struggles with increasingly longer power cuts". en.majalla.com. Retrieved 2024-12-21.
  6. "Turkey's energy hub ambitions have new momentum after Assad's fall". Chatham House – International Affairs Think Tank. 2024-12-17. Retrieved 2024-12-21.
  7. 1 2 3 4 5 6 Hatahet, Sinan; Shaar, Karam (2021-07-31). "Syria's Electricity Sector After a Decade of War: A Comprehensive Assessment". European University Institute. Retrieved 2021-11-23.
  8. "Demand for Electricity Rose 5.9 Percent in 2009". Syria Report. 8 March 2010. Retrieved 2021-11-23.
  9. "26 percent in power transmission network loss". Syria Report. 1 May 2003. Retrieved 2021-11-23.
  10. "Syria Continues to Face Severe Power Cuts". Syria Report. 24 August 2009. Retrieved 2021-11-23.
  11. "Syria to rely increasingly on gas power stations". Syria Report. 9 March 2002. Retrieved 2021-11-23.
  12. "Siemens, Koch clinch power plant expansion contract". Syria Report. 1 December 2003. Retrieved 2021-11-23.
  13. "Iran sets up electrical sub-stations in Syria". Syria Report. 17 December 2001. Retrieved 2021-11-23.
  14. "ABB India gets US$16.65 million Syria order". Syria Report. 24 December 2001. Retrieved 2021-11-23.
  15. "EIB to loan EUR 200 million for new Deir-ez-Zor Power Plant". Syria Report. 1 December 2005. Retrieved 2021-11-23.
  16. "Infrastructure brief : AFESD loans USD 100 million to Deir-ez-Zor power plant". Syria Report. 17 February 2006. Retrieved 2021-11-23.
  17. "Power cuts stall industrial revival in Syria's Aleppo". France 24. 2021-09-08. Retrieved 2021-11-23.
  18. "ثلاثة حرائق في دمشق وحلب بسبب تماس كهربائي". Enab Baladi (in Arabic). 2019-03-01. Retrieved 2021-11-23.
  19. Shaar, Karam. "The Syrian Oil Crisis: Causes, Possible Responses, and Implications". Middle East Institute. Retrieved 2021-11-23.
  20. Trew, Bel (2021-11-02). "Half of Syria has been displaced by war. Now record drought threatens millions more". The Independent. Retrieved 2021-11-23.
  21. Sala, Daniela; Laffert, Bartholomäus von; Mohammad, Shaveen (2021-11-10). "'Killing us slowly': dams and drought choke Syria's water supply – in pictures". The Guardian. ISSN   0261-3077 . Retrieved 2021-11-23.
  22. "Turkish dams threaten northeast Syria with ecological and economic blight". Syria Direct. 2020-08-11. Retrieved 2021-11-23.
  23. "Syria's brain drain – another twist to the country's crisis". The New Humanitarian. 2013-03-26. Retrieved 2021-11-23.
  24. "Syrian higher education system facing 'complete breakdown' after eight years of war – study". University of Cambridge. 2019-06-18. Retrieved 2021-11-23.
  25. "Turkish delegation in Damascus begins assessment of Syria's energy needs". www.aa.com.tr. Retrieved 2024-12-30.
  26. "Syrian Arab Republic – Ministry of Electricity". www.moe.gov.sy. Retrieved 2021-03-08.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.