1. Introduction
The global energy supply system faces problems such as price fluctuations, energy security, and environmental issues. Mankind will face two great crises soon. One is environmental pollution due to the combustion of fossil fuels, and the other is the increasing acceleration towards the depletion of these resources. The main reason for these problems is the significant contribution of fossil fuels to the composition of the energy basket. Fossil fuels currently account for more than 80% of the world’s energy supply [
1].
According to British Petroleum Company (BP) Energy Outlook in 2018, renewable energy will be the fastest-growing energy, increasing fivefold by 2040, thus providing about 14% of global primary energy in this future [
2].
At the same time, large oil companies, as a declining industry, are gradually facing potential prospects [
3].
As a strategic response to the potential for growth in the renewable energy sector and the increasing cost of hydrocarbon extraction, oil companies are increasingly active in the electricity and renewable energy sectors [
4]. Large oil companies are leading the way in developing new strategies to capture part of the fast-growing renewable markets, and while no doubt still struggling with the value of renewables, they can accurately counteract renewable energy in the face of oil developments. Moreover, evaluate the exact gas and time. Since this transfer, they have already made the first choices of capital allocation [
5].
Given that global warming, climate change, and widespread droughts are the most important threats to human life, the development of renewable energy combined with the rational use of fossil fuels seems to be a good solution. The main indicator for successful development and use of renewable energy is the possibility of competing with other forms of energy in terms of price and cost. This is especially important in developing countries, which have more limited financial resources than developed countries, and, therefore, the optimal allocation of financial resources is essential.
Annual investments in renewable energy have quadrupled to
$12 billion [
6]. From 2009 to 2013, the growth rate of pleasant energy production has increased sixfold, reaching 16 GW. In wind energy, growth has been 250% and has reached 121GW capacity. In total, renewable energy has grown by 75% to 1140 GW. The United States is a pioneer in investing in renewable energy with
$24 billion, and
$2 billion in renewable energy has been invested in developing countries over a four-year period by 2013 [
7]. To date, 73 countries have used renewable energy sources, 64 countries have reached a general policy for the use of renewable energy, and 45 countries have achieved an application for the use of renewable energy [
8].
There has been significant global growth in recent renewable energy capacity, mainly since late 2004, when it grew at an annual rate of 10 to 60 percent for many technologies [
9]. In fact, by the end of 2015, renewable energy support policies had been implemented in more than 146 countries [
10]. The GCC countries have set each of the targets for the deployment of renewable energy at the national or local level [
11]. To date, however, the deployment of renewable energy in the GCC has been minimal [
12]. Therefore, the stated goals should be supported by defined policies and regulations that reflect the regional context and, therefore, have the highest probability of achieving long-term goals [
13]. The policy framework for low-cost renewable energy, especially at the utility-scale, is being sold [
14]. The global average energy basket for the year 2015, the initial energy of the world, and the amount of investment for new energies in the world during 2011 to 2020 are shown in
Figure 1,
Figure 2 and
Figure 3.
Ghouchani et al. [
15] used cause and effect relationships to consider effects between barriers, identified barriers and solutions to improve the use of renewable energy in Iran. They analyzed the future trend of renewable energy in Iran to declare investment opportunities and examined three scenarios for analyzing renewable energy in Iran. Solaymani [
16] examined trends in energy demand, policies, and development of renewable energies and the causal relationship between renewable and non-renewable energies and economic growth using two methodologies. His results showed that renewable energy technologies currently do not have a significant and adequate role in the energy supply of Iran and also showed that there was a unidirectional causal relationship between economic growth to renewable and non-renewable energy use.
Afsharzadeh et al. [
17], in a review paper, answered three questions: why is renewable energy important for Iran at national and rural levels, how is renewable energy related to sustainable rural development, and what are the challenges in the promotion of renewable energy technologies in Iran. They concluded that although renewable energy had the potential for development in Iran’s rural areas due to environmental, social, and economic advantages, it could face some infrastructural, managerial, socio-cultural, and economic challenges. In another research, Fadai et al. [
18] reviewed the potentials of “renewable energies” (RE) in Iran and its current situation of RE related industries with an emphasis on achieving defined goals and objectives for the fourth national development plan, and also discussed the barriers and causes of non-achievement of these objectives.
As can be concluded from the literature review regarding the policies related to the penetration of renewable energies in Iran’s energy supply system, the aforementioned should be considered in the form of reasonable scenarios. On the other hand, in all of the previous studies, there was no integrated policy to overcome the high uncertainties in Iran’s renewable energy supply systems. Therefore, it would be much more difficult to design appropriate scenarios for utilizing renewable energy sources than for conventional fossil fuels. Investigating, recognizing, and managing uncertainties using scenario design is, therefore, an essential prerequisite for creating a long-term plan and future insights. In this study, we have tried to illustrate the alternative futures of this sector and to determine sustainable strategies for managing renewable energies in Iran using hypothetical planning.
It should be noted that the source of hydropower plants has long been used in Iran due to its many advantages and extremely high efficiency [
18]. In Iran, in 2020, fossil electricity accounted for more than 86% of the electricity supply basket, while the share of renewable energy in this year was low [
19]. Iran, in terms of not using its capacity in the ranking, is the first in the world. The question that arises here is why the share of renewable energy in Iran’s energy supply portfolio is low. The answer to this question requires identifying and examining factors such as issues related to technology, economics, and marketing. Therefore, in the present project, we first dealt with the technology and general principles related to different types of renewable energy, their position in the world and Iran were described, and then we examined the criteria and macro policies to determine their prioritization and necessity to use them.
3. Strategic Policies for Renewable Energy
Energy policy in recent years has become particularly important in terms of increasing the role of energy and the environment in the economic, political, and social activities of different societies [
42]. However, in the past, after the oil shock of 1973, in which the Arab countries producing crude oil closed the oil valves on the Western world, there has always been concern about the recurrence of such a situation in developed countries and in recent years in developing countries such as China and India have existed. Ensuring a secure and sustainable supply of energy as well as a demanding market with proper traction and growth is one of the main concerns of any country for its comprehensive development.
This would not be possible without energy policy at the level of industrial enterprises, local councils and municipalities, national governments, and the international level. A set of purposeful actions pursued by an actor or a group of actors in the face of a particular problem or issue is called policymaking [
43]. Energy policy is a framework of written and unwritten rules and practices that are generally developed over decades. In this context, mainly all levels of government in a country, as well as the private sector, are involved. The effects of economic, social, and political aspects of society, which are not necessarily related to energy at first glance, are discussed in interaction with energy. Energy policy seeks to improve the ways in which energy resources are produced or consumed [
44].
Thus far, energy has been viewed only from an engineering perspective and sometimes from an economic and technological perspective. Moreover, in the process, concepts such as optimization, efficiency, balance have been more important, and decision-making has been based on this. Recent advances in political science, social psychology, sociology, development economics, and environmental economics have given new energy to policymaking. In energy policy, a dynamic approach is considered instead of a static approach because policy variables are changing rapidly [
45].
As mentioned earlier, in recent years, due to the depletion of non-renewable energy sources, global warming, and environmental issues, the emphasis on renewable energy has increased. Given this global trend and the issues raised about the importance of renewable energy, there is a need to develop a strategy in this area. Government policies for the development of renewable energy can be divided into direct and indirect policies. Supportive policies for this type of energy, such as raising purchase tariffs, reducing taxes, and financing the construction of a renewable power plant, are among the direct policies of the government. Indirect policies are policies that increase the competitiveness of renewable power plants against fossil fuel power plants.
One of these policies is the liberalization of energy prices (the law on targeted subsidies) or the pricing of fuel delivered to power plants. Implementing energy carrier pricing policies can have a significant impact on the development of renewable energy plants by increasing the cost of electricity for fossil power plants. In addition to the economic parameters and the cost price of electricity generated, numerous other parameters are considered in policy-making decisions to prioritize and evaluate the justifiability of electricity with renewable energy, along with other options for electricity generation in a country.
Therefore, the need to form a robust strategy to fit these parameters is strongly felt. Due to the common concerns to respond to this need among different countries, the decision-making method of the two countries was studied in order to answer the basic questions raised in this field with the help of a comparative study and obtain a general strategy and policy. The purpose of some comparative studies is simply to describe two or more phenomena or situations by comparing their characteristics, while other comparative studies have purposes beyond description and involve judgment and evaluation and can include all types of comparative research, comparative studies, and classification studies. Include national and transnational levels.
For example, despite the huge fossil resources in Iran, is it reasonable to invest in the development of new energy in the current situation? If the answer is positive, what are the perspective of these energies and their share in the country’s energy basket? What are Iran’s technological priorities in the field of renewable energy, and what strategies should Iran adopt to develop these energies? To find the methodology for answering these questions, two sample countries from West Asia and Eastern Europe were selected. The reason for this choice was that in countries such as Iran, due to the huge resources of fossil fuels, the pace of movement towards renewable energy is not high.
In these two countries, issues such as the transparency and applicability of the methodology, the level of access to the fossil reserves of those countries, the importance of the environment for the people, the economic growth of the countries and GDP per capita are considered, which are very close to the criteria inside Iran. A common point in the study of both countries was the use of scenario planning method, which is due to the “importance of energy” and “uncertainty” about the future of energy. An overview of these scenarios in different countries, before examining the potentials and feasibility of resources within Iran, which will be explained in the following sections, gives a broad view of how a country policy to develop renewable energy, and finally makes conclusions and decisions easier for Iran.
First, the scenarios facing Saudi Arabia are presented and discussed (see reference [
46]) and are shown in
Figure 7. In this strategy, experts from both industry and academia with orientations in economics, environment, medicine, and politics were selected to participate in the survey, who identified three driving forces in this field. The scenarios were developed under these three drivers, a diagram of which can be seen in
Figure 7. The impulses obtained included access to fossil fuels, environmental responses, public awareness, and understanding of new energies. Expert opinions were obtained to identify the drivers in three steps.
In the first stage, general questions were asked about Saudi Arabia’s need for renewable energy and the role of this energy in the future. In the second stage, the answers were given feedback, and this time the experts were asked for more reasons for their opinions. In the third step, the final answer was obtained, and the drivers were identified. In addition, a preliminary design of the scenarios was prepared with the help of experts and finalized. After developing the scenarios, items such as the amount of fuel storage, the amount of land required, cost savings and its rate of return, as well as the potential of greenhouse gases in the space of each scenario, were compared with each other. The results of this comparison were made available to the decision-makers thus that they could choose the appropriate scenario or implement a combination of four scenarios according to the circumstances. The choice or non-choice of scenarios is based on the decision of policymakers.
Figure 8 shows the trajectory of this study.
The next country to study was Russia. The general guide to Russia’s energy movement is its energy strategies until 2020 and 2030 [
47].
By studying these strategies, Russia does not have a serious determination to expand renewable energy in the next ten years. In this country, energy planning is conducted regionally. Scenarios facing Saudi Arabia are shown in
Table 1.
The areas are grouped under the Russian Ministry of Energy, and the general direction of Iran’s movement is presented in a report entitled “Energy Strategy.” One of these regions is the Far East of Russia, which includes nine provinces. With the help of experts, 70 drivers were identified for the development of scenarios, which were divided into 11 groups. These 11 groups were the structure of the energy industry market in the Far East of Russia, decision-making and inclining the public and private sectors to renewable energy, coordination between different actors in this field, regional and national political factors, external energy market conditions, internal energy relationship. Moreover, the national economy and social development, national and regional priorities, and actions include energy policies, economic development, infrastructure and investment, technology development, and the state of natural resources. Then, these 11 groups were placed in two axes.
The vertical axis was “GDP growth and real international cooperation” which was designed in two directions. The horizontal axis was named “Focus on energy efficiency and superior technologies, wider use of new energy and use of natural gas.” This axis is also gathered in the Ministry of Energy, and the general direction of the country’s movement is prepared in a report entitled “Energy Strategy” and is approved by the President. One of these regions is the Far East of Russia, which includes nine provinces. With the help of experts, 70 drivers were identified for the development of scenarios, which were divided into 11 groups. These 11 groups are the structure of the energy industry market in the Far East of Russia, decision-making and inclining the public and private sectors to renewable energy, coordination between different actors in this field, regional, and national political factors, external energy market conditions, internal energy relationship.
And the national economy and social development, national and regional priorities and actions include energy policies, economic development, infrastructure and investment, technology development, and the state of natural resources. Then, these 11 groups were placed in two axes. The vertical axis was “GDP growth and real international cooperation” which was designed in two directions. The horizontal axis was named “Focus on energy efficiency and superior technologies, wider use of new energy and use of natural gas.” This axis was also designed in two directions of decentralization and concentration. Based on these two drivers, four scenarios were designed, which can be seen in
Figure 8. As can be seen from this diagram, the regional scenario is a suitable space for the development of renewable energies. In the national scenario, the movement takes place at a slower pace than the regional scenario, and as the past trend continues, there will be no significant development in the use of these energies. It is impossible not to focus on the expansion and development of renewable energy if there is a high growth of GDP. In the space of each scenario, the cases of energy demand and its increasing trend, from 2002 to 2030, the structure of energy demand (oil, hydro, gas), greenhouse gas emissions, and the cost of implementing each scenario were compared.
The result of this comparison is sent to the Ministry of Energy thus that decision-makers can choose the appropriate scenario based on these results. The general process of work can be seen in
Figure 9.
It is worth mentioning that the study of the structure of the renewable energy management system in these two countries is only for the purpose of obtaining new ideas and applying them in the process of designing the optimal structure of renewable energy in the country. Looking at the development of renewable energy in the two countries and considering the short history of activity in this field, an acceptable record should be attributed to the efforts of these countries. Comprehensive strategic plans for medium- and long-term goals have been formulated and implemented in these countries, and, therefore, a promising future can be seen in the development of all these clean resources ahead of these countries. However, what emerges from this study is that the level of utilization of these clean sources will be affected by the availability of fossil fuels and their price. On the other hand, these studies show that the continuation of serious political support for renewable energy is also of great importance for achieving the goals of the vision.
For many years, with the increase of human knowledge and understanding, the quality and status of life have always been improving and improving. The only Asian country that was partly associated with the economic growth of the nineteenth century and the early twentieth century was Japan. Recently, economic corridors have been concluded between Asian countries. The Sino-Pakistan Economic Corridor, for example, is a series of infrastructure projects currently under construction across Pakistan. Its economic value was initially $46 billion but has now reached $54 billion. The economic plan aims to rapidly modernize Pakistan’s infrastructure and strengthen its economy by building modern transportation networks, generating power plants, and creating special economic zones. With the launch of the China-Pakistan Economic Corridor projects, a lack of comprehensive foresight on future energy use has led to unfavorable economic and social consequences.
Therefore, it is necessary to comprehensively examine future energy demand and its determinants in order to be accompanied by appropriate political decisions in advance [
48]. Rare information is available on future energy forecasts for the China-Pakistan Economic Corridor for Pakistan as a whole and at the sector level [
49]. In the article, Khan et al. collaborated with the country’s specific experimental work by estimating future energy consumption and its savings potential by 2030 [
50]. Prose et al. made predictions of future energy consumption based on scenario analysis and Monte Carlo simulations [
51]. Investment in water, wind, and solar projects reflects the improvement of low carbon development scenarios in Pakistan [
52].
Preliminary work on energy saving potential involves estimating the stored energy supply curve. This method is used to assess the relationship between energy costs and potential savings of various conservation technologies [
53]. Basic work on the potential of energy saving using this method has been conducted by Fallahi et al. [
54]. In contrast, the index breakdown method is not considered a suitable method because it ignores price effects [
55]. However, this method has been used to calculate emission reduction potential for economies around the world [
56]. Scenario analysis has attracted a lot of attention in recent years in the analysis of energy consumption and its savings potential [
57].
Several scenario studies have been conducted to advise policymakers on the future energy system in line with public policy objectives [
58]. The scenario approach is a useful tool for presenting alternative results related to various decisions and strategies adopted in economics [
59]. Scenario analysis based on econometric models is considered as an appropriate technique in modeling energy demand in both the short and long term and explains past behaviors, future forecasts, and the effects of different policies in a single study make it possible [
60]. While dealing with energy demand modeling and forecasting, no single discipline offers a flawless approach. However, joint integration analysis has typically been used to estimate energy demand performance in recent articles [
61]. This review of articles also shows that scenario analysis and Monte Carlo simulations have been frequently used in articles to predict energy demand [
62].
6. Renewable Energy in Iran: Status and Potentials
Basically, renewable energy technologies in Iran are related to grid-connected power generation technologies [
66]. These technologies include offshore wind farms, medium and small hydropower plants, geothermal power, concentrated solar heat power, solar photovoltaics, and landfill gas (biomass energy). The following is a closer look at the potentials of various types of renewable energy in the country.
Briefly, more than three billion people live in rural areas of low- and middle-income countries. In most cases, rural households have high needs for energy, including cooking, lighting, heating, transportation, and telecommunications. The main purpose of Karami et al.’s study was to implement a conceptual model using renewable energy in rural areas of Iran [
67]. After determining the calculated values based on meteorological station data, IDW interpolation method was used in GIS software for the entire geographical area of the province. After surveying several areas and identifying potential classes, a village with sufficient potential for solar and wind energy (Kahkesh village) was selected, and then a field survey was conducted based on biomass resources. The needs of rural residents and the potential of rural renewable energy were examined by studying conceptual frameworks over a year. By dividing the energy value of the frameworks, the amount of energy savings can be calculated. Iran’s energy consumption basket is shown in
Figure 10.
6.1. Solar
Sunlight per day in more than two-thirds of the country is about 4.5 to 5.5 kWh/cubic meter. There are currently more than 2900 h, and, in some places, more than 3200 h of sunshine throughout the year in the country. The number of cloudy days behind the country throughout the country is less than five days a year, and the transparency of air in most parts of Iran is considered more than 60%. It is natural that using solar energy to supply hot water for consumption in our country will be cost-effective [
69].
Iran is one of the most talented regions for the construction of concentrated solar power plants in the Middle East, with an average direct radiation average of 5.5 kWh per square meter per day and about 300 bright sunny days per year [
70].
As shown in
Figure 11, the central and southern regions of Iran, such as the provinces of Yazd, Fars, Isfahan, and Kerman, with average daily direct radiation between 5.5 to 6.5 kWh per square meter per day, have high solar radiation.
In addition, according to a study by Marefati et al., Shiraz (the capital of Persia) is the best region in Iran to exploit the solar potential and establish centralized solar power plants [
72]. In the study of Hirbodi et al., the performance of centralized solar power plants, including parabolic systems and solar towers in the climatic conditions of southwestern Iran, has been technically and economically analyzed. The dry cooling place for concentrated solar power plants in the south-central regions of Iran has no justification due to its minor effects on technical and economic performance and due to the lack of water in such areas. The wet cooling system increases the annual water consumption by about 14 times but improves the technical and economic performance of the power plants by less than 4% and 5%, respectively.
Solar tower power plants have an annual power generation and a higher capacity factor and lower power level costs compared to parabolic power plants. Therefore, a 100-megawatt dry-cooling solar tower with 14 h of thermal energy storage and solar multiplier 3 is recommended as the most efficient option for exploiting the solar potential in the south-central regions of Iran [
73].
In the study of Shorabeh et al. [
74], with the aim of evaluating the technical, economic, and environmental dimensions of parabolic catchment plants and solar towers in the climatic conditions of southwestern Iran with an average of natural direct radiation of about 6 kWh per square meter per day. Based on the results, the optimal settings for the studied power plants are determined in relation to the economic-technical parameters. The 100-megawatt dry-cooled solar power plant, 14 h storage system, and 3.0 solar multiplier have been found to be among the most efficient settings in the weather conditions under investigation. For this concentrated solar power plant, the cost-balanced cost of electricity and solar-to-electricity efficiency was 11.3% per kilowatt-hour and 14.7%, respectively. In addition, the energy recovery time is about 15 months, reducing the annual carbon dioxide emissions by 399 kilotons and saving the annual fossil fuel 190 million cubic meters of natural gas [
75].
Until today, close to 500 KW of photovoltaic systems have been installed in Iran. More network-independent applications for telecommunication reporting stations, park and tunnel lights, intermediate telephones, border police stations and foresters’ stations, solar pumps for agricultural purposes, and rural homes in rural villages. The provinces are Yazd and Semnan. The only grid-connected application that has been installed thus far is a KW30 system in the Taleghan area, about 110 km from Tehran.
However, at present, there is no plan to install and operate a grid-connected photovoltaic system on a practical scale, either to power and amplify the grid, or for peak consumption times. Lack of familiarity of villagers with solar energy systems, costly creation of technical, scientific, and industrial potentials required for the implementation of these projects, instability in the process of current systems in the use of photovoltaic systems, and severe impact. One of the challenges of developing this type of energy is the reduction of allocated budgets.
The existence of 330 sunny days in Kerman is one of the main capacities of using local potentials for energy production in the country, which is being formed these days with government investments and domestic and foreign private sector. Iran is a good country to invest in solar energy, and due to the geographical location of Kerman and the number of sunny days, it has one of the most desirable places to develop solar energy projects. At present, it is possible to generate at least 2500 megawatts of electricity from the sun in Kerman, and with the investment of Afghans in Kerman, electricity can be generated in the province and transferred to the borders.
The 10 MW power plant in Kerman province in the Baft region was built on a 20-hectare land using specialized forces and fully localized equipment by the private sector, and today, 6 July 1998, it was connected to the country’s national electricity network. By exploiting the mentioned power plant, the emission of 9598 tons of environmental pollutants will be prevented, and water consumption will be reduced by 3060 cubic meters per year. The 10-megawatt power plant also saves 3.95 million cubic meters of natural gas annually in the country’s electricity generation process. Kerman province has the highest absorption of solar energy as one of the most potential provinces in the country, and thus far, 8 MW solar power plants with a total capacity of 48.7 MW have been built and put into operation in this province. In addition, thus far, 926 units of solar power plants with a capacity of 8228 kW have been installed in this province.
6.2. Wind
Iran has abundant wind resources. According to a wind map with the middle scale published in 2016, it is estimated that more than 10,000 MW of electricity generation from the wind farm in Iran. Average wind speed statistics in potential sites of wind farms in Iran the average wind speed situation in cities such as Khaf (Khorasan Razavi) is exceptional. Due to its special geographical location and being located in a low-pressure region compared to the high-pressure regions of the north and northwest, Iran in general in winter and summer in the direction of winds that blow in winter from the Atlantic Ocean and the Mediterranean Sea and Central Asia, which is located in the summer from the Indian Ocean and northwest to Iran. In Iran, 6500 MW wind energy potential has been identified, with such a capacity, 19,900 GWh of electricity can be generated [
76]. At present, there is a capacity to produce 660 kW wind turbines in Iran, which has reached the commercial stage. In the perspective of Iran’s electricity industry, at the end of the fifth five-year plan of the country’s industrial development, the estimated capacity of renewable energy power plants is about 2000 MW, most of which belongs to wind power plants [
77].
Some of the windy areas in Iran are difficult to cross, and there are special conditions for some meteorological stations installed, the distance between the towers is high, the challenge of buying parts and equipment from European countries due to the increase in the euro against the rial are the main challenges. They are in the wind power industry in Iran. In addition, other issues such as sanctions against Iran for importing some parts and raw materials are other problems in the development of this energy. Of course, recent cases are improving with the increasing rate of domestic production, which makes the future of this energy brighter. Atlas map of Iran’s wind speed is shown in
Figure 12.
6.3. Geothermal
Iran has favorable conditions for the formation of geothermal energy fields due to its location in the path of the earthquake belt and young volcanic activity. The existence of hot springs in the country proves this claim. Therefore, geothermal energy is one of the least expensive renewable energy options (in terms of production cost) for Iran. Unlike wind or solar, a geothermal power plant can provide baseload power and stability. Iran’s total geothermal potential is estimated at about 500 MW for instantaneous or single-phase steam cycles and up to 10 times higher for dual-cycle systems that require lower reservoir temperatures. However, the share of geothermal energy in the country’s energy composition for the next 10–20 years is less than 200 MW. This is almost the estimated potential of Sabalan region located in the northwestern region of Iran, where exploratory drilling studies and resource evaluation studies in this region were completed. Production wells are being drilled for a five-megawatt pilot plant. Exploratory drilling has started in the other three areas of Damavand, Khoy, Mako, and Sahand, and preliminary studies are underway in the other 10 areas.
Problems with opening letters of credit, sanctions on Iran for drilling goods and equipment, as well as weather conditions that in some cases cause delays in work are among the obstacles that face this type of energy. The distribution of different geothermal energy sources in Iran is shown in
Figure 13.
It is predicted that there are over 200 geothermal regions in our country, but they are not available in a codified and accurate form. Thus, we must move quickly in this area to make up for past delays thus that we do not lag behind the countries in the region in this area. Turkey is leading the way in the use of geothermal resources, as well as Saudi Arabia, which, such as Iran, has oil reserves but is considering using this energy and is preparing a geothermal atlas of their country. Recently, 12 geothermal zones were identified in west AzarBayjan.
6.4. Hydropower
Hydropower accounts for 13.8% of the national electricity generation and 4.98% of the total electricity generated in Iran. Hydroelectricity, on the other hand, accounts for about 19% of the total electricity generated in the world. Karun 3 hydropower plant with a capacity of 2280 MW of electricity and annual production of 4170 GWh is the largest hydropower plant in the country. At present, there is about 11.3 GW of hydropower generation capacity in the whole country. From 1387 to 1394, 5 to 13.5 GWh of hydropower energy has been produced in the country. Iran, with an average rainfall equal to one-third of the world average, is one of the arid and semi-arid countries in the world, and in addition, perhaps the most important reason for the establishment of dams in Iran is the inadequate temporal and spatial distribution of rainfall. This means, firstly, that a measure must be taken to store water for the time required for agriculture and drinking, and secondly, that it deviates significantly from the spatial standard of rainfall in the country.
Figure 14 shows the map of hydropower energy sources in Iran.
6.5. Biomass
The vast country of Iran is relatively rich in biomass resources. The use of biomass in Iran has traditionally been high before the wide distribution of petroleum products in 1338, but after the mentioned date, its use has decreased. The first digester of methane production in Iran was built in the Niazabad village of Lorestan in 1975. According to the results of the 1996 census, five percent of rural households used biomass resources for heating and cooking, respectively. Recently, a power plant with a nominal capacity of 650 kW has been inaugurated at the site of the old landfill in Mashhad with an initial investment of 15 billion rials. Biogas can be produced from animal waste available in Iran 8668 million cubic meters. Biogas can be produced from the mass of agricultural and forest wastes in Iran is 8.8 million cubic meters. Biogas from anaerobic treatment is about 200 million cubic meters. The biogas that can be produced from large food industries in the country is estimated at 280–80 million cubic meters per year. By exploiting the anaerobic digestion process of perishable waste, a total of 2.7 million cubic meters of biogas can be produced in the country per year. It can be seen that only from the above sources, on average, 9 million cubic meters of biogas can be extracted annually [
82].
Lack of encouragement of experts to localize resources and production of technical knowledge and the lack of a clear boundary between the activities of the public and private sectors are the main challenges for the development of biomass energy in Iran.
Hydrogen technology and fuel cell at present, hydrogen production projects are carried out by alkaline electrolysis and hydrogen storage methods, and by building fuel cell systems and connecting this complex to photovoltaic panels, the complete cycle of production, storage, and consumption of clean energy based on hydrogen is carried out. In any case, given that Iran is the second-largest source of gas, the development of this technology in the near future is predictable.
However, there are limited consultants, contractors, and competent supervisors in the field of hydrogen and fuel cell technologies, advanced technologies related to the production process, storage, and consumption of hydrogen, as well as problems arising from international sanctions from obstacles that have slowed the development of this technology.
Given the complex and evolutionary process of renewable energy development, it is essential to have a framework for its governance. Management of the transition to renewable energy can be conceptually divided into two stages, namely systemic analysis and policymaking. The article by Moalemi et al. focused on identifying the different methodological stages in the system analysis stage [
83]. These steps provide the necessary input for the second stage of policymaking by gaining a clear understanding of the current situation. In the first step, the boundaries of the transfer process are determined by specifying the unit of analysis and identifying the components and relationships of the system. In the second stage, to have a big picture of the evolution of the system, the dynamics of technology development over time are drawn. In the third stage, by comparing different approaches and choosing the most appropriate method, an approach for analysis and sustainability transfer policy is selected. Finally, all these methodological steps in the Iranian Fuel Cell Technology Development Program are used to demonstrate the practicality of the proposed conceptual framework in a real problem and provide insights for employees. The biomass and biogas energy sources of the country are shown in
Figure 15.
7. Conclusions
Regarding the lack of sufficient data in order to demonstrate comprehensive, integrated policies for the use of renewable energy supply systems in Iran, this study, using a review methodology, investigated current and future energy demands and existing renewable energy resource policies in Iran by employing the latest available data from the Ministry of Energy, Ministry of Petroleum and national laws and documents. Then, the strategic analysis estimated the direction of relationships among considered variables.
The experiences of different countries and the comparative studies conducted in the present project indicate that no single set of policies can successfully create a renewable energy industry in any country, both operationally and financially. However, it seems that many concerns such as the emission of pollution, especially carbon dioxide, access to resources, the cost of fossil fuels, security of supply, and the impact on foreign exchange have led to an environment of high interest in the development of renewable energy sources globally Arise.
Iran’s extractable gas resources are so vast that it is very difficult to justify the use of more expensive energy sources for the future. Resource depletion is not currently a challenge. However, in the near future, this decline may be particularly significant at the level of national policy, especially for oil. Perhaps for Iran, the decision to move towards the use of renewable energy sources is more than an absolute necessity, it is to diversify electricity generation.
Previous studies have shown that there are relatively rich sources of renewable energy in our country. However, for economic reasons and to ensure sufficient competition, it seems that the position of wind energy in Iran is higher than other renewable energy sources and has a higher priority in the short or medium term. The wind turbine market in Iran is far from the competitive pressures of wind turbine manufacturers and its domestic and foreign components, and the indirect transfer of technology through the exchange of human resources with other international wind energy institutions and enterprises does not exist or is very low. Wind turbine towers also seem to be supplied from within.
These two components together make up 25% of the value of a normal wind turbine, and this rate of domestic production is relatively high for the current size of the Iranian market. According to the analysis performed by SANA [
85], another 25%, which includes other equipment and parts, is also produced domestically. A total of 50% of domestic production is very high and close to the level reached by the first wind turbine manufacturing industries in Denmark and Germany. Of course, the technical and commercial risks are relatively high, even for high-volume production.
Having sufficient and appropriate expertise in the form of experienced engineers for the development of wind technology in the factory is necessary for all turbine factories and component manufacturers. It is also necessary to conduct wider planning for the construction of wind farms in the country with the help of experiences and information obtained from the implementation of pilot projects.
Concentrated solar-thermal power plants (CSPs) are much more expensive than other renewable energy sources and should be given less priority for short- or medium-term investment. Nevertheless, given Iran’s position in the CSP global solar belt, it may become the most important source of renewable energy in the long run. Therefore, Iran should continue the current plans for domestic manufacturers of CSP parts and equipment with the aim of reducing parts costs, improving current products, and expanding the types of parts produced.
Using solar energy to supply hot water to homes and industrial centers is one of the most cost-effective ways to use solar energy in oil-burning villages in Iran. For scattered users far from the grid who need relatively little power, photovoltaics is almost a competitive or low-cost technology. Photovoltaic has a strong and modular structure and requires little maintenance, and is, therefore, very suitable for remote rural users. For older users, it seems best to hybridize with wind or fossil fuels.
Due to the relatively longer duration of operation of geothermal projects compared to other renewable energy sources, the location of a large number of identified areas that require long transmission lines and very high investment costs provide limited contracting and development capacity for contractors. Internationally, in the short term, Iran should pursue a strategy of gradual development in this area, the primary goal of which is domestic capacity building. It is clear that high-temperature identified tanks relatively close to the grid connection points should be given priority in development and the development of tanks that are more suitable for dual-cycle power plants and require higher costs should be delayed.
In villages and small towns that are impassable and dilapidated, where energy delivery is not cost-effective, the construction of a biogas plant is preferable. For example, the southern regions of Khorasan and Sistan and Baluchestan, because the winds of the region are only 4 days and the sandstorm scratch the solar collectors, the development of wind and solar energy is not possible. In addition, the use of biogas energy is very useful and correct for the dense villages of the western regions of the country and the villages of the north of the country that have cold winters and are going through difficult conditions. The biggest obstacle to the commercial development of this industry in Iran is the conditions of landfills. As mentioned before, before any investment is made, basic activities must be conducted to upgrade all landfill sites to meet the requirements of health landfills. Unhygienic landfills that are not properly managed and do not collect treated fluids can contaminate the surrounding soil and groundwater aquifers and cause irreparable damage to public health.
Municipalities should be encouraged to implement and complete their landfills due to environmental issues and public health goals. On the other hand, sufficient information about the actual amount of waste in certain areas, waste composition, age, humidity, temperature, pH, and other necessary factors.
Assuming the abundance of natural gas supply in Iran, even though this technology consumes fossil fuels, the capacity of the fuel cell program in Iran’s work program is appropriate. Domestic natural gas markets can be significantly expanded by future applications of fuel cells in power generation and transmission. Today, natural gas passing through a reformer is the main source of hydrogen in most fuel cell installations.
Wind energy, solar energy, geothermal energy, biomass energy, and hydropower in our country have very good and non-polluting sources, each of which can provide us with very large amounts of energy. Therefore, it is hoped that policymakers in this field will take greater steps to support, encourage, and develop these clean resources in Iran.
Renewable energy has caused the employment of 43,450 people directly and indirectly in the country and the volume of non-governmental investment in this sector has reached more than 124,000 billion rials.
From July 2009 to the beginning of June 2016, three billion and 132 million kilowatt hours of energy was produced from renewable sources, which this amount of electricity generation from renewable energy could reduce the emission of about two million and 161 thousand tons of greenhouse gases.
In addition, this amount of new energy production has reduced 889 million cubic meters of fossil fuel consumption in Iran, which is one of the main causes of air pollution in the country, and more than 689 million liters of water has been saved.
Currently, 416 MW of renewable power plants are under construction in the country, and the installed capacity of the country’s new energy has reached 724 MW.
Thus far, 103 MW renewable power plants have been installed in the country and another 42 MW power plants are under construction.
A review of the figures in this section indicates that 44% of the country’s renewable power plants are solar, 40% wind, 13% small hydropower, 2% heat recovery, and 1% is biomass.
Soon, Iran will be able to supply a significant percentage of its electricity through renewable energy sources. Iran has a high climatic diversity and of the four types of climate in the world, four types are available in Iran, which has increased the potential for the use of renewable energy.