by Werner Gitt
– mechanical work (energy)
– potential and kinetic energy (energy of rotation and energy of translation)
– the energy of gravitational fields, and of electrical, magnetic, and electromagnetic fields
– heat energy
– electrical energy
– the energy which binds nucleons in atomic nuclei
– chemical energy
– radiation energy of particles (electrons, protons, and neutrons)
– the equivalence of mass and energy
All physical events and processes obey two fundamental principles, known in thermodynamics as the "first law" and the "second law."
The first law: This important natural law, also known as the "energy law" or the "law of conservation of energy," was first formulated in 1842 by a German physician, Robert Mayer (1814–1879). It states that energy cannot be created in the observable world, neither can it be destroyed. This law is not an axiom, but is derived from experience as are all natural laws (see Theorem N1, paragraph 2.3). In every chemical or physical process, the total energy of the system and its environment, and thus also the total quantity of energy in the universe, remains constant. It is thus impossible to destroy energy or to add to the total quantity of energy. It can only be converted into other forms. Some important consequences of the energy law are:
– Only events which do not change the total amount of energy, can occur in nature. Walter Gerlach (1889–1979), a German physicist, formulated this principle as follows [R1]: "The law of the conservation of energy plays the role of a police commissioner: it decides beforehand whether a line of thought is acceptable or forbidden."
– The impossibility of a perpetual motion machine of the first kind: No machine can be constructed which, after being set in motion, can continue working unless the supply of energy is renewed.
– The different kinds of energy correspond quantitatively, and these energy equivalents can be determined empirically.
The second law: The first law is only concerned with the conversion between heat energy and mechanical energy or vice versa, without any regard as to whether the conversion actually takes place or not. The second law, however, determines the direction of the process. By themselves, all processes run in only one direction, i.e., they are irreversible. We know from experience that if a hot block of copper is put in contact with a cold block in an isolated container, heat will be exchanged; the hot block continues to convey heat to the cold one until an average temperature occurs in both blocks. If two blocks at the same temperature are placed in the container, nothing will happen. It does not contradict the first law when one block becomes warmer and the other one cooler, as long as there is no overall loss or gain of heat.
The second law provides us with a criterion for predicting the direction of a given energy process. An abstract though quite meaningful concept — entropy S — is required for a mathematical formulation of this law. Entropy is a quantifiable value which changes whenever heat is converted. In its briefest form, the second law can be expressed as dS ≥ 0 (for closed systems). The following conclusions can then be drawn:
– Entropy cannot be destroyed, but it can be produced.
– It is impossible to construct a periodically functioning machine which does nothing else but deliver useful work by cooling a single reservoir of heat. This means, for example, that the heat content of the sea cannot be used for propelling a ship.
– Heat cannot by itself flow from a cooler body to a warmer one (R. Clausius, 1850).
– It is impossible to build a perpetual motion machine of the second kind: It never happens in nature that an automatic process can let the amount of entropy decrease with no other effect.
The following formulation was first proposed by J. Meixner [M2]: "In the gigantic factory of natural processes, the function of manager is taken over by the production of entropy, because it prescribes the direction and the kinds of the events of the entire industry. The energy principle only plays the role of accountant, being responsible for the balance between what should be and what is."
The ability of a system to perform useful work: This is an important concept, since work (mechanical effort) can be completely converted into heat. The reverse process, the complete conversion of heat into useful work is theoretically impossible. This asymmetry is a primary result of the second law. In addition, the second law asserts that closed systems tend toward a state where the usable energy is a minimum, and the entropy becomes a maximum. The change in the amount of entropy indicates whether a process is reversible or not. The better a process can prevent an increase in entropy, the more useful energy can be produced. Potential and kinetic energy, as well as electrical energy, can be arbitrarily converted into one another in such a way that the process is very nearly completely reversible and can thus produce a maximum amount of useful work.
On the other hand, heat energy can only be partially converted into mechanical work or into some other form of energy. It is impossible to convert more than a certain fraction of the supplied heat energy, as given by the formula h = (T2-T1)/T2 for an ideal Carnot machine (a reversible Carnot cycle; see also paragraph 2.5). This thermodynamically possible amount of useful energy is known by a distinctive name — exergy. The fact that it is impossible to obtain more work from a heat engine than allowed by ηC follows directly from the second law.
Living organisms have a greater efficiency (= useful mechanical work obtained from a given energy input) than the maximum thermal efficiency allowed by the second law. This does not contradict this natural law, but indicates that the Creator has endowed body muscles with the capacity to convert chemical energy directly into mechanical work, and do so much more efficiently than ordinary heat engines can.
Conclusion: The law of entropy precludes all events which might lead to a decrease in entropy, even while obeying the energy law. Entropy thus reveals itself to be one of the most important and most remarkable concepts of physics.
Figure 42: Three processes in closed systems: Two blocks of copper having different temperatures eventually attain the same temperature. If two compartments contain gases at different pressures, the pressures will quickly be equalized through the opening. Two salt solutions having different concentrations exchange their salt content through a permeable membrane. In all three cases, the common aspect is that the entropy of later states is greater than for the initial conditions (S2 > S1).
Entropy and disorder? In countless publications, examples are given which illustrate that when the entropy of a system increases, the amount of disorder also increases; in other words, the orderliness is diminished. This idea has unfortunately also been extended to biological systems. The following arguments refute such a view:
– Biological processes take place in open systems, and are not closed. The second law allows a decrease in entropy as long as there is a corresponding increase in entropy in the environment. What is completely precluded is that the overall amount of entropy could be diminished.
– There can be no generally valid relationship between entropy and disorder, because entropy is a physical quantity which can be formulated exactly, but there is no exact formulation for disorder. The present author attempted a classification of the order concept in [G5], and different kinds of order are depicted in Figure 43.
Figure 43: The four kinds of order. The entity "order" which characterizes systems can only be described verbally and not mathematically. We can distinguish between order achieved by means of natural laws and intentional order. Structures which figure in physical systems can only be maintained as long as the gradients responsible for their existence (e.g., temperature difference), are active. Such an ordering cannot be stored and thus does not refer to a possible evolution. In the lower part of the diagram, ordered systems which are without exception based on some plan are listed. In these cases, information is either involved directly, or there are structures which originated through information.
– The examples sel
ected for illustrating the apparent relationship between entropy and disorder are, without exception, systems where there is no interaction between components. Such systems are irrelevant as far as biological structures are concerned, since thousands of chemical reactions take place within minute spaces.
– Biological order is based on the information present in all cells. The quality and quantity of this information should now be obvious — see chapter 6 and paragraph A1.2.3.
The ripple patterns produced in beach sand by retreating tides represent a certain order imparted by energetic processes (Figure 44), but there is no underlying code and also no intention. Such order does not represent information and thus cannot be stored.
Figure 44: Ripple marks on beach sand are an example of a structure which originated through the input of energy; this ordering is not based on information (no code is involved).
A3.2 Strategies for Maximizing the Utilization of Energy
The utilization and consumption of energy is always a question of converting one form of energy into another. When the energy produced by a certain source is utilized, the objective is to use the energy as economically as possible. In other words, maximum efficiency is the goal, employing a strategy for maximization. The following sections are devoted to a discussion of technical and biological systems where this principle is used. When energy is consumed, the inverse strategy becomes important, namely minimization of consumption: the available fuel must be used as economically as possible. The required work then has to be done with a minimal input of energy. The brilliant methods and the superlative results achieved by biological systems are discussed in paragraph A3.3.
A3.2.1 Utilization of Energy in Technological Systems
Man’s inventiveness has produced numerous concepts in the field of energy production and utilization. In most cases, the conversion of energy from the primary source to the consumer entails a number of forms of energy. For example, the chemical energy of fuel is converted into heat, the heat is then utilized to produce mechanical work, which, in its turn, is converted into electrical power. In a car engine, the chemical energy of the fuel changes into heat in the combustion chambers, and the explosive expansion of the gases is converted into mechanical work. An electric light bulb converts electrical energy into heat and light. Losses occur during all these conversions, and the ratio between the input energy and the recovered energy represents the efficiency of the process. Even in present-day coal-burning steam generating plants, the efficiency is only about 40%. This means that 60% of the chemical energy of the coal is lost.
In 1993, the total amount of energy generated in Germany was 536.6 TWh [F2, p 1007]. About 5% of this total was water energy, 29.6% was obtained from nuclear reactions, and the rest was generated by the combustion of fossil and other fuels (coal and lignite 55.4%, plus natural gas, oil, and diverse other sources). With the exception of the limited hydro-electrical sources, all these processes involve heat conversion with its low efficiency.
Great technological efforts are exerted to achieve direct conversion of energy without any intermediate forms. Examples include fuel cells, magnetohydrodynamic generators, and photo-voltaic elements. The efficiency of the latter is only about 10%, and the others are not yet technologically viable.
Even in the sunny southern regions of Europe, solar power installations, employing concave mirrors to generate steam (which then drives turbines for the production of electricity), require a total mirror surface of 26,000 m2(2.5 football fields) to generate 1 GWh per annum [X1]. This amounts to one million kilowatt-hours per year — enough to supply 350 homes. It would require an enormous area of 42 square miles (68 square km) to generate the same quantity of electricity as that which can be produced by one 1,300 megawatt nuclear power plant. This area could accommodate 150,000 urban inhabitants.
Wind-driven power plants also require a lot of space. It would require 800 to 900 windmill towers of 492 feet (150 m) to equal the energy production of one 1,300 megawatt nuclear plant. Four chains of such windmills separated by a distance of 1,312 feet (400 m) would extend over a distance of 50 miles (80 km).
A3.2.2 Utilization of Energy in Biological Systems (Photosynthesis)
Photosynthesis is the only natural process by means of which large quantities of solar energy can be stored. Requiring only carbon dioxide (CO2), water (H2O), and small quantities of certain minerals, it is the fundamental process for supplying the energy which plants need for growth and reproduction. The organic substances produced by plants are the primary source of nutrition and energy for all heterotrophic[25] organisms which cannot utilize photosynthesis directly. It can truthfully be stated that photosynthesis is the primary source of energy for all life processes and it also provides most of the usable energy on earth. All fossil fuels and raw materials like coal, lignite, crude oil, and natural gas have been derived from the biomass of earlier times which was formed by photosynthesis.
This process synthesizes complex, energy-rich substances. What usually happens in oxidation/reduction reactions is that a strong oxidizing agent oxidizes a reducing substance, but photosynthesis is exceptional in this respect. It employs a weak oxidizing substance (CO2) to oxidize a weak reducing agent (H2O) to produce a strong oxidizing substance (O2) and a strong reducing compound (carbohydrate). This process requires the input of external energy, namely sunlight. Such a process can only occur in the presence of a substance which can absorb light quanta, transfer the energy to other molecules, and then revert to its initial state where it can again absorb quanta of light. Chlorophyll performs this complex function. There are five types of chlorophyll (a, b, c, d, and f), which differ only slightly in chemical structure. Occurring in "higher" plants and in green algae, types a and b are the most important. The chemical equation for photosynthesis is:
(1) 6 CO2 + 6 H2O + light energy ® C6H12O6+ 6 O2
In this process, glucose is synthesized from CO2 and H2O by employing the energy of sunlight. The capture of light energy and its conversion to chemical energy is only one part of the process. These initial reactions are called photochemical reactions, and all subsequent reactions where chemical energy is utilized for the synthesis of glucose do not require light energy; they are thus known as dark or umbral reactions.
The ability to absorb light varies very strongly from one substance to another. Water absorbs very little light and thus appears to be colorless. The color of a substance depends on the absorption (and reflection) of certain wavelengths of light. When the degree of absorption is plotted against wavelength, we obtain an absorption spectrum. Chlorophyll only absorbs blue light (wavelength 400 to 450 nm) and red light (640–660 nm), so that the reflected light is green. The active spectrum of a process refers to its efficiency in relation to its wavelength. It is therefore noteworthy that the absorption spectrum of chlorophyll closely corresponds to the active spectrum of photosynthesis. This indicates that a finely tuned concept underlies this vital process and an efficiency calculation supports the view that a brilliant mind is involved.
The efficiency of photosynthesis: According to equation (1), exactly 1 mol[26] of glucose is generated from 6 mol CO2 [1] requiring an energy input of 2,872.1 kJ. For 1 mol of CO2, this amounts to 478.7 kJ. As a loss of energy is inherent in each and every energy conversion, the actual quantity of light energy required is greater. Although red light quanta possess less energy (about 2 eV/light quantum) than blue light quanta (approximately 3 eV/quantum), due to different efficiency both types produce approximately the same amount of photochemical work. It has been determined experimentally that 8 to 10 light quanta are required for every molecule of CO2. The energy content of 1 mol of red light quanta (= 6.022 x 1023 quanta [2][27]) amounts to 171.7 kJ. Therefore, 9 mol of red light quanta (the average of 8 and 10) is found by multiplying 171.7 kJ x 9. The result is 1,545.3 kJ. The efficiency Ë can be calculated as the ratio between the theoretical amount of energy required to assimilate 1 mol CO2 (478.7 kJ) and the actual energy content of the incident red ligh
t (1545.3 kJ):
ηred = 478.7/1,545.3 x 100% = 31%
The energy content of blue light quanta is 272.1 kJ/mol, so it follows that ηblue = 20%.
Volume of photosynthesis: The productivity of plants is not only qualitatively but also quantitatively highly impressive. A single beech tree which is 115 years old has 200,000 leaves which contain 180 grams of chlorophyll and have a total area of 1,200 m2, and can synthesize 12 kg of carbohydrates on a sunny day, consuming 9,400 liters of CO2 from a total volume of 36,000 m3 of air [S4]. Through the simultaneous production of 9,400 liters of oxygen, 45,000 liters of air are "regenerated"! On a worldwide scale, 2 x 1011 tons of biomass is produced annually by means of photosynthesis [F6]. The heat value of this mass is about 1014 watt-years (= 3.15 x 1021 Ws). The entire human population annually consumes about 0.4 TWa = 1.26 x 1019 Ws (1 TWa = 1 Terawatt-year = 3.1536 x 1019 Ws), and all the animals require 0.6 TWa. Together, these add up to only one percent of the total annual biomass production.
Respiration: The result of breathing, namely the release of energy, is the opposite of photosynthesis. These two processes are in ecological equilibrium, so that the composition of the atmosphere stays constant, unless it is disturbed by human intervention like heavy industries. It should also be noted that the mechanisms for photosynthesis and respiration are astoundingly similar. The substances involved belong to the same chemical classes. For example, a chlorophyll molecule consists of four pyrrole rings arranged round a central atom, which is magnesium in the case of chlorophyll, and iron in the case of hemoglobin, the active substance on which respiration is based. Both processes occur at the interface of permeable lipid membranes. The inevitable conclusion is that a single brilliant concept underlies both processes and that both are finely tuned to each other. We can thus reject an evolutionary origin, since two such astonishingly perfect and similar processes could not possibly have originated by chance in such diverse organisms.