Solar energy in progress and future research trends
Introduction
Fresh water and energy are the two major commodities that furnish the fundamentals of every human activity for reasonable and good life quality. These two resources are intricately related to each other. In fact, during the early civilizations, water power has been employed as the major energy source. Solar energy is the most ancient source, and it is the root material for almost all fossil and renewable types. Special devices have been used for benefiting from the solar energy since time immemorial and such applications actually date back to before Christ. Energy is a continuous driving power for the social and technological prospective developments. Energy sources are vital and essential ingredients for all human transactions and without them human activities of all kinds will not be progressive at all. On one hand, the energy sources are limited and on the other hand, the population growth at present average rate of 2% inserts extra pressure on additional energy demands.
The oil crises of the 1970s led to a surge in research and development efforts that are dedicated to the development of solar energy alternatives. These efforts were strongly correlated with the fluctuating market price of energy, and suffered a serious setback as this price later plunged. The missing ingredient in such a process was a long-term perspective that hindered the research and development policies within the wider context of fossil and solar energy tradeoffs rather than reactions to temporary price fluctuations. The same events also gave rise to a rich literature on the optimal exploitation of natural resources, desirable rate of research and development efforts to promote competitive backstop technologies [139]. There is also vast literature on energy management in the light of atmospheric pollution and global warming processes [19], [36], [37], [59], [88], [89], [90], [91], [138], [139], [143].
Since the energy crisis in 1973, air pollution from combustion processes has caused serious damage and danger on the forests, monuments, human health as has been documented by official studies and yearly statistics. Many environmental damages including acid rains, and their forest damaging consequences, incurred economical losses in short, and especially, long-term durations. Hence, seemingly cheap energy inflicted comparatively very high expenses on the society. Fig. 1 shows three partners in such a social problem including material beneficiary, heat beneficiary and in between the third party who has nothing to do with these two major actors.
The climate change due to use of chloroflorocarbons (CFCs) is a major cause of imbalance and natural absorption of CO2 is another example as possible social costs from the energy use which are handed over to the future generations by today's energy consumers. Again the major source of climate change is the combustion of bad quality fossil fuels.
Today, the development scale of any country is measured by few parameters among which per capita energy consumption holds the most significant rank. In fact, most industrialized countries require a reliable, efficient and readily available energy for effective transportation, industrial, domestic and military systems. This is particularly true for developing countries especially those that do not possess reliable and sufficient energy sources. Importation of energy from other countries is expected to be one of the main items in the national budgets of many countries in an increasing manner in the future. However, recently many countries have launched projects to optimize, update and search for their internal energy resources, whatever are the availabilities.
Non-renewable energy resources are limited to cover all the foreseeable future energy consumptions of the world. As a whole electricity production based on fossil or nuclear fuels induce substantial social and environmental costs, whereas it would appear that the use of renewable energy sources involves far less and lower costs. There are a number of different energy cost categories born by third parties, which ought to be taken into consideration in the comparison of different energy resources and technologies. Hohmeyer [60] has given the following seven effective categories for consideration.
- 1.
Impact on human health:
1.1 short-term impacts like injuries,
1.2 long-term impacts like cancer, and
1.3 intergenerational impacts due to genetic damage.
- 2.
Environmental damage on:
2.1 crops and forests like flora,
2.2 cattle and fish like fauna,
2.3 global climate, and
2.4 materials.
- 3.
Long-term cost of resource depletion:
3.1 Structural macro-economic impacts like employment effects.
- 4.
Subsidies for:
4.1 research and development,
4.2 operation costs,
4.3 infrastructure, and
4.4 evacuation in cases of accidents.
- 5.
Cost of an increased probability of wars due to:
5.1 securing energy resources (like gulf war), and
5.2 proliferation of nuclear weapons.
- 6.
Cost of radioactive contamination of production equipment and dwellings after major nuclear accidents.
- 7.
Psycho-social cost of:
7.1 serious illness and death, and
7.2 relocation of population due to construction or accidents.
Economic growth and prosperity rely heavily on adequate energy supply at reasonably low costs [20]. Unfortunately, energy is the main source of pollution in any country on its way of development. It is well known, by now, that the SO2 emission from the fossil fuels is the main cause of acid rain as a result of which more than half the forests in the Northern Europe have already been damaged. On the global scale, increase in the emission rates of greenhouse gases and in particular CO2 represents colossal treat to the world's climate. Various theories and calculations in the atmospheric research circulations have already indicated that over the last half century, there appeared a continuously increasing trend in the average temperature value up to 0.5 °C. If this trend continues in the future, it is expected that in some areas of the world, there will appear extreme events such as excessive rainfall and consequent floods, droughts and also local imbalances in the natural climatic behaviors giving rise to unusual local heat and cold. Such events will also affect the world food production rates. In order to decrease degradation effects on the environment and atmosphere, technological developments are sought since 1973 oil crisis. It has been recently realized that renewable energy sources and systems can have a beneficial impact on the following essential technical, environmental, and political issues of the world. These are:
- 1.
major environmental problems such as acid rain, stratospheric ozone depletion, greenhouse effect and smog,
- 2.
environmental degradation,
- 3.
depletion of the world's non-renewable conventional sources such as coal, oil, natural gas,
- 4.
increasing energy use in the developing countries, and
- 5.
world population increase.
The use of conventional energy resources will not be able to offset the energy demand in the next decades but steady increase will continue with undesirable environmental consequences. However, newly emerging renewable alternative energy resources are expected to take increasing role in the energy scenarios of the future energy consumptions.
Oil rich countries do not have energy shortages as long as the fossil fuel resources are economic and available within the country. The net return from industrial material produced in a country is the reflection of energy consumption in an efficient way. Otherwise, burning fossil fuels without economic industrial return may damage any country in the long run, especially, with the appearance of renewable energy resources that are expected to be more economical, and exploitable in the long run. Fossil fuel reservoir availability steadily decreases at an unprecedented rate and hence, there are future non-sustainability alarms on the energy source. It is, therefore, necessary to reduce consumption rates even starting from today by partial replacements through the sustainable alternatives, such as solar energy. Solar energy is practically unlimited, environmentally clean and friendly. Unfortunately, for the time being large-scale fossil energy production is cheaper than the available solar alternatives as stated by Chakravorty et al. [18]. Parallel to the fossil energy exploitation and consumption technological advancements, solar energy consumption has also developed but to the level that for today such developments are marginal. Abundance and cheap exploitation of fossil fuels leave room only for technological developments, in order to reduce the environmental pollution. Researches and technological developments are concentrated on clean coal and oil technology rather than improving fossil fuel conversion efficiencies. There is hardly any study towards the reduction of fossil energy cost, but studies are directed rather to energy demand mitigation. Solar energy, on the other hand, has many prospects of future developments and technological renewals that are appropriate for research and development.
Especially, the oil crises in 1973s have led to a surge in solar energy research and development efforts. The rate of these developments is dependent on the fluctuating oil prices. Perhaps, the most significant side view was the individual and rivalry developments in fossil and solar alternatives rather than their joint exploitations.
Although an adequate supply of energy is a prerequisite of any modern society for economic growth, on the other hand, energy is also the main source of environmental pollution, particularly in industrialized countries. In an indirect way, it is also known that acid rains as a result of sulfur dioxide emission from fossil fuel plants have already damaged plant and forest life, which are observable especially in the developed countries. Additionally, on the global scale, increasing emissions of air pollutions are main causes of greenhouse gases. If the increasing trend of carbon dioxide continues at the present rate, then major climatic disruptions and local imbalances in the hydrological as well as atmospheric cycles will be the consequences leading to excessive rainfall or drought, excessive heat and cold. Such changes are already experienced by those who are at their 1950s and will also affect the world's potential for food production which is the major survival supply for the human life. The continual use of conventional energy resources is expected to affect adversely the natural environmental conditions, and consequently, social energy related problems are expected to increase in the future. A new factor, however, which may alleviate the environmental and social problems of future energy policies, or even solve them, is the emerging new forms of renewable energies such as solar, wind, biomass, small hydro, ocean and geothermal energies as well as the solar hydrogen energy possibilities. Up to now, the renewable sources have been completely discriminated from the conventional alternatives due to economic reasons. However, the trend in recent years steadily favors the renewable energies in many cases over the conventional sources.
Today consumption of fossil fuel quantities is so high that even minor imbalances between supply and demand may cause considerable societal disruptions. In order to get rid of such disruptions at least for the time being, each country imports coal, and especially, oil to cover the energy imbalances. Oil embargo, by Organization of Petroleum Exporting Countries (OPEC) in 1973, gave the first serious warning and alarm to even industrialized countries that energy self-sufficiency is an essential part of the country concerned for her economic, social and even cultural survival. In fact, the technological and industrial developments in the last 150 years rendered many countries to energy dependable status.
Worldwide use of energy for several decades appeared to be increasing dramatically, but in the last decade, it has leveled off, and even dropped to a certain extent as shown in Fig. 2. In this graph all forms of energy uses are represented in terms of the amount of coal that would provide the equivalent energy. Around 1970s most of the predictions foresaw that energy demand would continue to accelerate causing expected severe energy shortages. However, just an opposite situation developed, and today, there is energy surplus on the worldwide market that has resulted from economic downturn coupled with many-fold increase in the oil prices during the last 20 years.
Fossil fuel reserves in the form of oil and natural gas are still considerable at present consumptive rates for the next 50 years. However, with increasing amounts of renewable sources and discoveries of new reservoirs, this span of time is expected to extend for almost a century from now onwards.
With the unprecedented increase in the population, the industrial products and the technologic developments, the human beings started to search for new and alternative ways of using more energy without harming or perhaps even destroying the natural environment. This is one of the greatest unsolved problem facing mankind in the near future. There is an unending debate that key atmospheric energy source, solar radiation should be harnessed more effectively and turned directly into heat energy to meet the growing demand for cheaper power supplies.
The main purpose of this paper is to discuss the potential of solar energy for future uses as the major alternative among the renewable sources in addition to its environmentally friendly clean characteristics. An extensive literature review on recent and future directions are also presented for solar energy prediction models. The practical uses of solar energy in the forms of low and high temperature collectors and photovoltaic possibilities are also given with future potential research directions.
Section snippets
Natural energy sources
All types of energy, renewable or non-renewable, can be traced back to either atmospheric activities in the past or to the present and future activities within the atmosphere. The renewable energy sources are regarded as related to present atmospheric movements, but non-renewable sources have been deposited in the depths of the earth. The latter types are also referred to as the fossil fuels. By burning the fossil fuels the stored energy of the past atmospheric activities is added to the
Energy units
In general, energy is defined as the ability to perform work. According to the first law of thermodynamics, the total sum of all energy forms in a closed system is constant. It is also referred to as the principal of energy conservation. In order to discuss quantitatively and comparatively various energy alternatives, it is necessary to bring them into a common footing in terms of measurement units.
The basic and physical unit of energy is Joule (J) which is based on the classical definition of
Energy and population
The two major reasons for the increase in the energy consumption at all times are the steady population increase and strive for better social and economical developments. The world population is expected to double in the next 50 years. Such an increment in the population will take place mostly in the developing countries, because the developed countries are not expected to show any significant population increase.
The energy demand growth is linked to population growth and individual development
Renewable alternatives
The sun is the primary source for new and renewable energy alternatives. Unfortunately, this source is not consumed sufficiently at its full extent everywhere in the world. This is due to the fact that all the portions of earth surface do not receive usable amounts of solar energy. For instance, places far away from the equatorial belt do not have enough irradiation intensity because annual clear and sunny days number is too small. On the contrary, zones close to the equator in the north and
Solar energy alternatives
The nuclear fusion reactions in the sun yield a huge amount of energy, which is estimated at 3.47×1024 kJ per unit time. Only a small part of about 5×10−11 of this huge energy is irradiated onto the earth's surface. The incident solar energy is distributed into many branches as shown in Fig. 4. Solar energy is both clean, inexhaustive and harmless to living organisms on the earth because the harmful short wavelength ultra-violet rays are absorbed before reaching the troposphere by the
Sun radiation
Earth receives virtually all of its energy from space in the form of solar electromagnetic radiation. Its total heat content does not change significantly with time, indicating a close overall balance between absorbed solar radiation and the diffuse stream of low-temperature thermal radiation emitted by the planet. The radiance at the mean solar distance—the solar constant—is about 1360 W/m2 [86]. The solar radiation varies according to the orbital variations. If Ss is the total solar radiation
Environmental prospects
It has been stated by Dunn [35] that several problems have arisen from the increased use of energy. For example, oil spillages result from the tanker transportations. Burning of various energy resources has caused global scale carbon dioxide rise due to especially fossil fuels. If the necessary precautions are not considered in the long run, this gas in the atmosphere could exceed the natural levels and may lead to climate change. Another problem is big scale air pollution in large cities,
Solar irradiation calculation
After the solar radiation enters the earth's atmosphere, it is partially scattered and partially absorbed. The scattered portion is also called as the diffuse radiation, which goes partially back to space and the remaining part reaches the ground. On the other hand, the radiation arriving on the ground directly in line from the sun is called direct or beam radiation. Only measurement and knowledge of direct radiation are necessary in designing many solar collector devices. Absorbed, diffused
Solar radiation and heat models
Long-term surface solar radiation records have been kept at only a few sites worldwide [98]. Solar radiation is conceptually simple and its attenuation through the atmosphere can be modeled with a fair degree of accuracy. The greatest uncertainty in estimating surface solar radiation is due to the effect of overlying clouds. Satellite observations of reflected solar radiation help to remove this uncertainty, and with the aid of radiation model or correlative relationships they are used to
Solar radiation devices and collectors
The solar radiation can be used principally as a source of heat, particularly in the forms of domestic hot water consumption, crop dying, power heat engines, power for refrigerators and air conditioners, and ate photovoltaic cells operation for direct electricity production.
Solar energy is expected to be the foundation of a sustainable energy economy, because sunlight is the most abundant renewable energy resource. Additionally, solar energy can be harnessed in an almost infinite variety of
Photo-voltaic
The term ‘photovoltaic’ is derived by combining the Greek word for light, photos, with volt, the name of the unit of electromotive force. The discovery of the photovoltaic effect is generally credited to the French physicist, Edmond Becquerel who in 1939 published a paper describing the experiments with a ‘wet cell’ battery, in the course of which he found that the battery voltage increased when its silver plates were exposed to sunlight.
Photovoltaic cells consist of a junction between two thin
Photo-optical collection and transmission of solar energy
The need for new and renewable energy alternatives due to the depletion of conservative energy sources brought along also the studies on the efficient usage and transmission of available energies. As is well known, the major criticism against these energy alternatives is the problem of the energy storage [137]. Especially, unevenly distributed solar energy potential on the world causes unbalance in their production among various regions, some of which are relatively richer then the others. Such
Solar-hydrogen power
The world energy demand depends mainly on fossil fuels with respective shares of petroleum, coal and natural gas at 38, 30 and 20%, respectively. The remaining 12% are filled by the non-conventional energy alternatives, which are 7% hydropower and 5% nuclear energy shares. It is expected that the world oil and natural gas reserves will last for about several decades, but the coal will sustain the energy requirements for few centuries. This means that the fossil fuel amount is currently limited
Heat transfer and losses
As explained earlier the easiest way of solar radiation collection is for low temperature heating purposes. It is well known that black surfaces absorb solar radiation more than any other color, and therefore, when a surface is blackened it will absorb most of the incident solar radiation. Continuous pour of solar radiation on such a surface will increase its temperature. This will continue until the heat gain from the solar radiation will be in equilibrium with the heat loss from the
Future expectations
In general, there are two distinctive reasons for future energy researches. First, as a result of global warming, atmospheric and environmental pollutions due to energy consumption, present day energy pattern, dominantly fossil fuels, must be either improved in quality or more significantly they must be substituted with more environmentally reliable clean and renewable energy sources. The second reason for the future researches on energy progress is the appreciation that the fossil fuel
References (150)
- et al.
Monthly average daily global beam and diffuse solar radiation and its correlation with hours of bright sunshine for Karachi, Pakistan
Renew Energy
(1991) - et al.
Construction of a quadratic model using modified Angström coefficients to estimate global solar radiation
Solar Energy
(1990) - et al.
Global solar radiation in Italy
Solar Energy
(1978) The effect of day-to-day correlation in solar radiation on the probability of loss of power in stand-alone photovoltaic solar energy systems
Solar Energy
(1986)Estimating the loss-of-power probabilities of stand alone photovoltaic solar energy systems
Solar Energy
(1984)- et al.
The average distribution of solar radiation correlations between diffuse and hemispherical and between daily and hourly insolation values
Solar Energy
(1979) - et al.
Evaluation of selected models for estimating solar radiation on horizontal surfaces
Solar Energy
(1989) Renewable energy and sustainable development: a crucial review
Renew Sustainable Energy Rev
(2000)Kriging in the hydrosciences
Adv Water Resour
(1978)- et al.
A test of Suehrcke's sunshine-radiation relationship using a global data set
Solar Energy
(2002)
Reliability evaluation of solar photovoltaic arrays
Solar Energy
A general formula for computing the coefficients of the correlation connecting global solar radiation to sunshine duration
Solar Energy
Time series analysis of daily horizontal solar radiation
Solar Energy
A critical look at recent interpretations of the Angström approach and its future in global solar irradiation prediction
Solar Energy
Calculation of monthly mean solar radiation for horizontal and inclined surfaces
Solar Energy
An assessment of the mesoscale variability of solar radiation at the Earth's surface
Solar Energy
Errors associated with the spatial interpolation of mean solar irradiance
Solar Energy
Depletion of fossil fuels and the impact of global warming
Resour Energy Econ
Correlation of average diffuse and beam radiation with hours of bright sunshine
Solar Energy
Accurate computations of monthly average daily extraterrestrial irradiation and the maximum possible sunshine duration
Solar Wind Technol
Calculation of monthly average insolation on tilted surfaces
Solar Energy
Loss-of-load probabilities for stand-alone photovoltaic systems
Solar Energy
The utility of the Angström-type equation for the estimation of global radiation
Solar Energy
World distribution of solar radiation
Solar Energy
Statistical comparison of solar radiation correlations. Monthly average global and diffuse radiation on horizontal surfaces
Solar Energy
The historical evolution of the Angström formula and its modifications: review and bibliography
Agric Forest Meteorol
Method for estimating solar radiation from right sunshine data
Solar Energy
The European solar radiation atlas: a valuable digital tool
Solar Energy
Global and diffuse solar radiation in Doha (Qatar)
Solar Wind Technol
Loss of power supply probability of stand-alone photovoltaic systems
IEEE Trans Energy Convers
Solar terrestrial radiation
Q J R Meteorol Soc
On the atmospheric transmission of sun radiation and dust in the air
Geograf Ann
On t he computation of global radiation from records of sunshine
Arkiv Geof
Handbook of fundamentals
Spatial and temporal variations in long-term normal percent possible radiation levels in the United States
J Clim Appl Meteorol
A technique for maximizing details in numerical weather map analysis
J Appl Meteorol
Solar heating design by the f-chart model
Recherges sur les effets de la radiation chimique de la lumiere solaire au moyen des courants electriques produits sous l'influence des rayons solaires
Comptes Rendus L'Acad Sci
Probability statistics and decision for civil engineers
Endogenous substitution among energy resources and global warming
J Political Econ
Wind farm location and environmental impact, network for alternative technology and technology advancements C/O EEDU
The economics of global warming
Statistics for spatial data
An operational objective analysis system
Mon Wea Rev
Solar energy thermal processes
Classification of radiation sites in terms of different indices of atmospheric transparency
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