Publications

Source: World Bank (2016)

Morocco’s domestic energy mix remains heavily dominated by fossil fuels, particularly on oil. Oil supplies over two-thirds of Morocco’s primary energy needs, followed by coal (16%), and biomass and waste (7%) (Figure 3). Coal dominates electricity generation with over 40% of total production, followed by oil and natural gas (Figure 4). Another 15% of power production is generated by renewable energy sources, primarily large hydropower owing to Morocco’s long-standing reliance on dams to help generate a share of its electricity. Renewable energy sources, primarily solar and wind power, have recently entered Morocco’s market, and contribute a rising share of the country’s electricity needs. Electricity generation from hydropower has nearly doubled and wind power tripled since 2002 (IEA, 2013b). Most future renewable projects are likely to be either solar or wind-related as Morocco has largely exploited its large hydroelectric potential to capacity.

Morocco’s options for renewable energy applications are far-reaching. The primary focus area of Moroccan policymaking is utility-style production. Morocco is already harnessing renewable energy and currently leads regionally in terms of installed capacity for non-hydro electricity. By the end of 2015, Morocco had around 800 MW of installed generation capacity for total wind and solar power, the largest in the Middle East and North Africa (Figure 6). The launch of Ouazazarte’s Nour I CSP plant in early 2016 should add considerably to this capacity, leaving Morocco far ahead as North Africa’s single largest producer of wind and solar energy. Morocco’s total production of renewable electricity output has subsequently risen sharply in recent years, doubling between 2012 and 2013 (Figure 7) alone with a further sharp rise expected for 2015/2016 for which no official data is yet available. 

Figure 6. Renewable energy capacity in the Middle East and North Africa, excluding Hydro, 2015

Source: Author based on data from IRENA (2016a)

Figure 7. Renewable electricity output (excl. Hydro) in selected Arab economies

Source: Author based on data from World Bank (2016)

Utility-scale deployment

Morocco has ambitious plans to further harness renewable energy sources more systematically, as part of the government’s plans to reduce its country’s dependency on imported fossil fuels from international markets. Formal plans include the installation of a total of 2GW of wind and 2GW of solar power generation capacity by 2020 – bringing renewable energy capacity in power generation to above 40% of the total energy mix (Ministry Delegate of the Minister of Energy, Mines, Water and Environment, 2014) and further cementing Morocco’s regional position as a leading producer of renewable energy in the MENA region. In addition, Morocco’s submission to the UNFCCC as part of its INDCs includes the objective to reach 50% of installed electricity generation capacity from renewable sources by 2025 (Kingdom of Morocco/UNFCCC 2015).

A particularly important role is in this context played by CSP technology, for which Morocco and North Africa offer a globally highly competitive location (CIF, 2009; Fraunhofer, 2016). Large-scale utility level investment into CSP in Morocco could in this context have significant benefits not only for CSP technology in North Africa, but globally in terms of helping accelerate global CSP deployment, thereby reducing technology costs through manufacturing economies of scale and learning effects. The World Bank’s 2009 Clean Technology Fund’s investment plan in North Africa specifically acknowledges this potential for significant deployment additions to be of significance beyond the region:

“CSP is a technology that is of particular interest to utilities, but with unexploited manufacturing scale economies: CSP could be cheaper relative to PV on a per kWh basis in most cases and is more scalable and more consistent with a centralized and dispatchable generation model. Its adoption and replication by utilities is therefore more assured. CSP is a relatively simple technology with few high-cost materials or proprietary components. If the demand for CSP is scaled up, then equipment costs can fall very substantially, since it has yet to benefit from cost savings that often come from manufacturing scale.” (CIF, 2009: 3)

This reasoning has also played a role in the allocation of significant financial resources through the Clean Technology Fund into CSP in Morocco, though this financing remains below potential in Morocco. Maximising this potential for Morocco will require a further, proactive policy of pursuing precisely this advantage, securing external finance for Morocco to become a demonstration case for CSP applications and cost down-driver for the technology.

Rooftop schemes

Another potent, though not yet overly explored area of renewable energy deployment in Morocco, is the use of solar PV for rooftop installations – both for the purpose of electricity generation and for solar water heating. Morocco’s solar resources are plentiful and suitable for solar PV, and the technology for rooftop installations is easily accessible, making schemes for the promotion of rooftop solar programmes, as used for instance in Europe (see Box 3 with background about the German model). Such schemes could be transferrable to Morocco’s context, for use in both urban and rural areas. Financial aid schemes such as government loans and technological assistance to rural communities could make the initial investment feasible for Morocco’s middle class, making the scheme feasible in quantitative terms.

Widespread home ownership in Morocco, including among lower income households and in rural areas, means incentive structures for feed-in-tariffs (FIT) could be high – with a loan scheme at hand and guaranteed FITs for households feeding surplus electricity production back into the grid, and in view of Morocco’s considerably higher solar irradiation intensity than in Germany, rooftop solar in Morocco could make long-term economic sense for many Moroccan households. Lower income homes, in turn, could be incentivised to install rooftop solar panels with the help of loans structured to account for their lower income – with realistic prospects for households to recover their initial investment eventually over time through FIT premiums and the lower cost of electricity.

Morocco’s electricity tariffs are high in the context of the Middle East and North Africa, at 2013 rates of US$0.122/kWh for intermediate consumption and US$0.167/kWh for higher consumption brackets comparable to lower-cost European electricity. At this rate, savings made in electricity bills through lessened grid consumption and the sale of surplus electricity generated into the grid, this could provide a viable alternative even to low-income Moroccan households to the current model; while a high uptake rate of PV rooftop installations can, as in the German case, contribute significantly towards national goals such as articulated through Morocco’s INDCs to the UNFCCC in December 2015 of boosting the country’s renewable energy capacity to 50% of the country’s electricity mix by 2025.

Off-grid opportunities

Solar and small-scale hydropower offers tremendous potential in Morocco to address electricity access in remote off-grid areas. Morocco’s rural electrification programme PERG (Programme d’Electrification Rurale Global) has since the 1990s shown tremendous results in providing rural communities that could not be connected to the country’s main grids with access to electricity (El-Katiri, 2014a, b). PERG has operated on the basis of chosing local solutions based on local contexts: the programme reviewed local conditions to assess the viability of alternative solutions such as photovoltaic generators, small hydro turbines, wind turbines, diesel generators, and hybrid systems. Over a period of 15 years, more than 35,000 villages and some 1.9 million rural households were electrified, lifting rural electrification rates to from as low as 18% in 1996 to 97 per cent by 2009 (Agence Française de Développement, 2013).

Solar, wind and hydro power offer real advantages to rural communities over exclusive reliance on conventional fuels, because the energy source itself is independent from access to transport roads, and hence outside help. Work accompanying similar schemes in Jordan revealed that many rural communities welcomed the introduction of cleaner and supposedly low-maintenance PV generators, which avoided the running costs associated with diesel fuel (Al-Soud and Hrayshat 2004: 593).

An additional benefit of renewable energy off-grid systems is that installation and maintenance can be trained among a local stock of people, helping locals learn new skills, and help maintain their local communities. For sure, variable renewables such as wind and solar power have limitations, most importantly their lack of 24-hour coverage. Hybrid systems using diesel generators as a backup solution has been one main response in the framework of PERG – using solar and wind power when possible while relying on conventional fuels when necessary. For rural communities in particular, there would also be plenty of potential for R&D within Morocco to explore more economic forms of electricity storage, including village-based mini-grids that run on the basis of concentrated solar power (CSP).

Green job creation

Diversifying into renewable energy technologies and associated R&D could also help promote Morocco as a “green” energy hub in the region – with potential for collaborative links both with Europe in the North and Sub-Saharan Africa in South. To promote and coordinate local R&D activity, Morocco established in 2011 a separate institution, the Institut de Recherche en Energie Solaire et en Energies Nouvelles (IRESEN). Separately, the Centre de Competence Changement Climatique du Maroc (4C Maroc) was more recently as a further specialised institution aimed to be a capacity-building and information sharing platform to forge Morocco’s climate plans –there is potential here for collaboration with neighbouring countries. This institutional landscape focused on clean energy and climate change mitigation is already now unique in both North and Sub-Saharan Africa, though it will now need to be followed up by capacity building and action plans.

Morocco’s demography is generally favourable to the aim of using renewable energy for local value chain and job creation. Its population of more than 33.8 million is young, with some 45% under the age of 25 (Haut-Commissariat Au Plan, 2016). Research and development (R&D) activities would hence be as feasible on practical grounds as would be, in principle, industrial-style manufacturing given the availability of both high-skilled and low-skilled Moroccan labour force to supply both industry strands. Spill-overs from systematic renewables deployment could also be expected for related sectors in Morocco such as construction, transportation, research and service industries (Marktanner and Salman, 2011; El-Katiri, 2014a).

Estimates by IRENA suggest the entire North Africa region could have the potential for around 16,000 jobs in renewable energy (2016: 11), a positive outlook given the comparably low new local job creation potential for conventional energy sources. An earlier World Bank study put the job creation potential significantly higher, at around 50,000 new local jobs for manufacturing components by 2025 in CSP component production alone between the five MENA economies Morocco, Algeria, Egypt, Tunisia and Jordan by 2025 in CSP component production alone (World Bank/ESMAP, 2011).

Maximising opportunities

Financing. To maximise its use of these resources and to take up the vast opportunity Morocco faces in green energy – in particular in Concentrated Solar Power (CSP) – Morocco will need to add further policy focus on the area, and work actively to secure finance options, including from external sources. One key priority area is the opening up of sufficient financing options for Morocco, particularly in the area of CSP at large scale, and in which Morocco has considerable potential to drive down technology costs globally if it is able to expand its CSP deployment in line with its potential.

A major potential source of finance for Morocco’s green energy programme, alongside other clean energy transitional measures will be the Green Climate Fund (GCF) as established by the parties to the UNFCCC at COP 16 in Cancun in 2010. The Paris Agreement that has been adopted by 196 parties to the UNFCCC in Paris in December 2015 recognized the importance of adequate and predictable financial resources for the implementation of developing countries’ climate mitigation and adaptation programmes (UNFCCC, 2016a). Importantly, the meeting also emphasized a range of climate-related activities that could further help broaden Morocco’s commitment to greener development, including tackling deforestation and forest degradation, conservation management, and encouraging the coordination of support from private, public, bilateral and multilateral resources (UNFCCC, Ibid).

Clean energy developments in Morocco may also benefit substantially from other external funding options. The Clean Development Mechanism (CDM) is one potential source of financing was designed under Article 12 of the Kyoto Protocol to assist specifically developing countries in emissions-reducing projects that are counted towards these countries’ set Kyoto targets. It is also the main source of funding for the Kyoto Protocol’s Adaptation Fund (AF) aimed to assist countries that are particularly vulnerable to the negative effects of climate change (UNFCCC, 2014). Problematic alone is that the CDM alone only covers a share of the total investment required – around 10% - and requires specific expertise (Hafner and Tagliapietra, 2013).

Capacity building. In addition to financial requirements, Morocco also faces a range of other challenges, including institutional capacity building. Key to leveraging on Morocco’s green potential within the institutional landscape in Morocco now will be the distribution of clear mandates, as well as a responsive mechanism of consulting, managing and implementing a legislative environment that proves conductive to the creation of innovative industries and R&D. A critical role within this framework will undoubtedly be played by the private sector, ranging from manufacturing to financing of project, installation, operation but also technology research. Managing this complex transition will require many institutions to work together transparently, ensuring credible investment decisions and accountability in the way public funds and foreign investment are channelled into new projects.

Cross-regional clean energy trade. Morocco would also offer itself within the North African context as a key trade partner with Europe, owing to its political stability. Having been largely spared by the political upheaval other parts of North Africa have experienced since the onset of political uprisings, the Arab Spring in Tunisia and later Egypt and Libya, Morocco also holds politically close relations with European member states. Trade agreements with Europe exist in other areas such as agricultural products and textiles, which are based on principally the same logic future agreements on solar energy could be based: lower cost production in Morocco, traded into the European Union to reduce costs for European customers as well.

Despite past difficulties, the reality remains that North African – including Moroccan – wind and solar power offers competitive advantages over those found in Europe. The OECD confirms that solar intensity in most of the countries in the MENA region is above that in France (OECD, 2013: 46). According to DLR data, Morocco’s technical potential for solar thermal electricity generation exceeds with around 20,151 TWh/yr the technical potential of Spain by a factor of twelve, and of Portugal by a factor of 46; Morocco’s economic potential at a DNI > 2,000 kWh/m²/yr is with 20,146 TWh/yr almost as high as its technical potential (DLR, 2005). And Morocco’s direct normal irradiance (NDI) rates are around 18% higher than those of Spain (DLR, Ibid), providing Morocco with an economic advantage over Southern Europe with regards to CSP potential in particular.

To facilitate trade, Morocco not only need clean investment finance, but also, and perhaps foremostly, equal-level market access to European utility markets. This is currently not the case, as the continuation of European policies such as subsidies for their domestic renewable energy producers protect European markets from potentially lower-cost competition from external markets such as North Africa. In the coming decade, exploring options for Europe to open its market to North African clean energy as part of its commitment to, for example, the principles of the UNFCCC and the Paris Agreement’s provisions to lower the EU’s greenhouse gas emissions footprint, could provide a major investment incentive into clean energy in North Africa – with or without the need for additional financial loans and aid packages. Furthering such investment systematically in the future could hence benefit both European and Moroccan climate and clean energy pledges.