Purpose of the article is a presentation of possible solutions to the problem of global warming. The first is based on the physical properties of the Earth and its atmospheres. Another way represents reduction of anthropogenous influence on the climate. Efforts of international association in an agreement achievement among issuers’ greenhouse gas emissions on reduction of emissions are analyzed. It discusses an actual objectification problem of emissions quotes distribution based on the principle of differentiated responsibilities. For decision of this problem, it presents a mathematical algorithm of objectification of greenhouse gases distribution.
Among the global issues that came to the fore in the 20th century is that human impact changes the Earth’s climate, leading to global warming. The different aspects of this problem are discussed in the paper: reasons of climate changes; real possibility of ecological catastrophe because of uncontrolled greenhouse gas emissions; influence of greenhouse effect upon stable economic development.
Considering the nature of climate change there are two possible ways for humans to stabilize the surface temperature of the Earth: by regulating parameters of the absorption and reflection of solar energy. These parameters can be changed by varying not only atmospheric concentrations of greenhouse gases but also surface reflectivity. But now only regulation of concentrations of greenhouse gases is in the focus of state’s attention.
Scientists offer different solutions to the problem of distribution of quotas. Many countries (especially developing) disagree with methods of calculating quotas. Countries’ loss of implementation of obligations of reducing greenhouses gas emission is not equal. Now there is no method of calculating quotas that would suit the majority of states. Since the early 1990s numerous attempts have been made to overcome these difficulties at the international level, but none of them have been successful, mainly due to the lack of objective criteria for the solution of this problem.
This is demonstrated by the failure of negotiations on the revision of the Kyoto Protocol in Copenhagen 2009. Reducing emissions by 50% looks more like a common purpose, but not a specific obligation. Copenhagen Accord is not possible to cover developing countries. Now to revise the Kyoto Protocol international society needs new method for distribution of greenhouse gas emission.
This article presents this method. It is a mathematical algorithm of objectification of greenhouse gases distribution (on a world, a country, its region or megalopolis scale) based on the principle of differentiated responsibilities. This algorithm is a modification of the mathematical method of optimal greenhouse gases distribution published in [1-3] (Maergoiz et al., 2010, 2011).
Let us look at the way the global surface temperature of the Earth is determined. If the Earth were an ideal blackbody, all solar energy, E, incident on the Earth’s surface would be absorbed by it and would heat it. However, the Earth is “gray”, and, thus, it reflects part of the received solar radiation back to space. The portion of solar radiation reflected by the Earth’s surface is albedo, A. Thus, the Earth is heated by energy E(l − A).
The solar-heated surface emits infrared rays into space, and their energy increases as the temperature rises, where is the Stefan-Boltzmann constant and T is the absolute temperature at the Earth’s surface. The green-house effect is caused by the emissions of the following greenhouse gases. The major contribution is made by water vapor, and this contribution keeps on growing as the temperature rises. Under the contemporary average global temperature, water vapor accounts for three-fourth of the greenhouse effect. The second place is occupied by carbon dioxide. Although carbon dioxide represents only a relatively small portion of the atmosphere, it accounts for nearly the whole of the remaining one-fourth of the green-house effect. Methane accounts for about 1% - 2%, and the contributions of all other greenhouse gases are not greater than several tenths of one percent. If there were no greenhouse gases in the Earth’s atmosphere, the global surface temperature of the Earth would be determined by the equation.
Due to the presence of greenhouse gases in the atmosphere, a certain amount of the energy is emitted by the Earth returns to the Earth’s surface. Thus, a firstorder approximation of thermodynamic equilibrium is described by the following equation:
where a is the parameter determining the portion of the heat energy emitted by the Earth that is returned to the Earth’s surface by greenhouse gases.
With the changes of the surface temperature of the Earth, the amounts of carbon dioxide and other gases remain practically unchanged. However, concentrations of atmospheric methane and water vapor (in particular) increase dramatically with a temperature rise, resulting in a so-called positive feedback. As the surface temperature of the Earth rises, the amount of atmospheric water vapor increases. The increase in the amount of atmospheric water vapor enhances the greenhouse effect and, hence, raises the surface temperature of the Earth. This process can go on until all oceans evaporate. An important part in the temperature evolution of the Earth’s surface has been played by life that emerged on the Earth (the biosphere). It began controlling concentrations of methane and carbon dioxide, removing them from the atmosphere and “hiding” them in the Earth crust, thus significantly reducing the greenhouse effect. So, the temperature on the Earth was favorable for every living thing and it evolved depending on the ratio between the carbon dioxide emitted by volcanoes and the rate of carbon sequestration inside the Earth performed by the biosphere. For the past 1.5 - 2 centuries people have been increasingly using nonrenewable fuels (coal, oil, and natural gas), thus involuntarily varying atmospheric concentrations of greenhouse gases. Additional amounts of greenhouse gases raise the Earth’s temperature, and this, in turn, increases the amount of water vapor in the atmosphere (parameter a grows) and melts the glaciers (parameter A grows). As these parameters increase simultaneously with a temperature rise, this can provoke the overheating of the Earth’s surface. The dynamic balance between the release of carbon dioxide by erupting volcanoes and its removal by the biosphere would cause alterations of warm and cold climates. This, however, does not mean that a warmer climate would be more favorable for humanity today, as both human civilization and all warm-blooded animals would lose rather than gain.
There are two possible ways for humans to stabilize the surface temperature of the Earth: by regulating parameters A and a (the greenhouse effect) in the atmosphere and on the Earth. A and a can be changed by varying not only atmospheric concentrations of greenhouse gases but also surface reflectivity—by changing the amount of clouds at different heights. This idea was first proposed in the 20th century [
We can reduce our interference in natural processes by maintaining the contemporary state of the atmosphere. The arguments presented in Section 1 suggest the following dilemma: on the one hand, emissions of greenhouse gases (carbon dioxide) due to combustion of nonrenewable energy sources have to be considerably reduced. On the other hand, total energy production should be increased in order to maintain and improve the quality of life in developed countries and, what is even more important, to provide an opportunity for developing countries to attain a comparable standard of living. In order to reduce emissions of greenhouse gases due to combustion of carbon fossil fuel, both its percent in the energy budget and its actual amount should be decreased, by replacing it with renewable sources of carbon fuel, wind power, water power, and nuclear energy. It should be remembered, though, that the use of alternative energy sources will directly or indirectly increase the cost of power generation and, according to UNESCO estimates, must decrease the GDP by 1 - 2. An important consideration is that the effect of this “loss” on developed and developing countries will be different: the use of alternative energy sources can delay the achievement of high life quality in developing countries for decades.
Let us discuss various ways to solve this problem. The first was proposed by Dirk Solte [
The second drawback is that this algorithm does not take into account a nation’s history. Thirdly, no account is taken of the influence of geographic conditions: the quotas for the people living in high-latitude areas and for those living in the equatorial zone cannot be equal, as the former have to heat their homes and other buildings.
The second approach, whose implementation is being attempted now, is to get different countries, gradually and to a greater or lesser extent, to reduce their emissions. The countries accept these obligations voluntarily and cannot be punished for failing to carry them out. The main advantage of this approach is that it is liberal rather than radical. However, contradictions between developed and developing countries do not allow them to reach and implement the necessary agreements. Moreover, certain countries are rightfully suspected of selfishly pursuing their own political or economic aims while trying to stabilize the global temperature.
However, the main defect of this approach is the subjectivity of any of the proposed or finalized agreements. Thus, in our opinion, the most topical issue today is objectivization of the establishment of quotas.
The legal basis for international control and reduction of the human impact causing the “greenhouse effect” is currently provided by the UN Framework Convention on Climate Change accepted in 1992 [
Thus, international community has not reached an agreement on the amounts of emissions to be reduced as the subjective approach to determining them does not suit any country in the world.
The problem of the distribution of greenhouse gas emissions is solved using the algorithm having tested for distribution of monetary resource in problems of collective investment management [
Assume N (N > 2) groups of greenhouse gas emitters (on the global scale, in a country, a region, a megalopolis) negotiate on a certain admissible quantity V of greenhouse gas emissions (in weight units) during a fixed time period. Concentrate on the problem of the distribution of this value among all groups of emitters taking into consideration the size of the population in every group. In mathematical terms this is sum partitioning of the value
where Vk is an admissible quantity of emissions for the group with number k. Let Sk be population of the same group, , and
be population of all groups. Denote by, the mean value (density) of emissions per capita of all population and for the group with number k, where, respectively. By (1), it follows the relation
Introduce the dimensionless values (part of population in the group with number k), (coefficient of proportionality),. Then taking into account the previous equality we find
, (2)
Suppose that emitters reach to the following agreement: conditional rating of every group is defined by the value of the corresponding coefficient of proportionality. Moreover, taking into consideration the principle of differentiated responsibilities for climate change, climate groups differ from each other by the introduced rating, and group indexing is given in ascending order of this value, e.g.
here inequality implies that n groups for n < N agree that their value (density) of emissions per capita of population be less than the mean density r. Mathematical approach to the choice of coefficients is based on the following extremal problem.
Problem B. It is necessary to find values of parameters, such that the functional
attains the minimum provided that equality (2) holds and the following additional linear relation between coefficients is fulfilled:
Parameters (see (2)), , b are fixed numbers satisfying natural restrictions ensuring the condition: the inequality (3) is true.
Relation (5) can be a result of agreement among emitters. For example, the equalities, or, where or, correspondingly, , are used in [2,3] for the distribution of the monetary resource in problems of collective investment. In geometrical terms the proposed optimal principle (see (4)) implies that desired vector
has the smallest length. Its coordinates are differences in emission densities per capita for groups with adjacent numbers. This approach to the choice of positive parameters is of great “psychological” significance. The smaller their values, the easier it is to come to the conclusion of the contract if emitters have agreed with the principle of division into groups, which is reflected in (3).
The obtained solution of the mathematical problem under consideration provides a way to define the admissible quantity of emissions for the group with number. In previous notations, the following formula is correct
where is the solution of Problem B.
The conditional rating of every group can be determined based on another criterion, e.g. its living area. In this case the previous notations have the following meaning: is the living area of the group with number k, where is the total living area; , is, respectively, the mean quantity of emissions per area unit of the total living area and for the group with number k, where is the portion of the territory of this group;,. Coefficients are chosen realized by solving the same extremal problem.
We illustrate a possible way of Problem B solution using two simple examples. This mathematical approach to search of Problem B solution differs from the way of solution in [1-3] (Maergoiz et al., 2010, 2011).
Example 1. Assume in the notations of subsection 4.1 V = 410 million tons, , milliard peoples. Suppose that the inequality (3) is the following one:
and it is taken the equality (5) in the form, where. At first we find the solution in the more general case provided that
(Problem A solution [1-3]):
where,;.
Let in the previous notations. Then By (9), we have
It is easy to check that the inequality (7) is fulfilled. Assume. Then Based on this and (6), we find desired parameters V1 = 90, V2 = 140, V3 = 180 million tons of emissions.
Taking into consideration the another variant of the problem statement (see 4.2) consider the following example.
Example 2. Assume in the notations of subsection 4.1 V = 340 milliard tons, , S = 150 million km2. Take the inequality (3) in such form
and choose the following equality (5), where is a number, admissible for existence of Problem A solution (see example 1, inequality (8)).
In this case, we obtain the following solution of Problem A in the notations of example 1:
where, and, consequently,
Suppose in the previous notations. Then, , , , , ,. By using formulas (11) and (12), we have
Hence, and the equality (10) is true. Let. In a similar way, we find desired parameters Finally, from (6) we deduce
, milliard tons of emissions.
The quickest way for solution of global climate changes problem is to find an objective criterion of the distribution of greenhouse gas emissions. A mathematical approach to discovery of this criterion is proposed in the paper.