Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity

The introduction and application of the concept of immanence as a physical quantity allows a broader understanding of effect. Mathematical formulations present the complementary co-factors of information and immanence as the cause and result respectively of the thermodynamic effect. Thus, the concept of immanence helps to clear up the relation between the concepts of information and reality and leads to the derivative of the principle of immanence development which might be applied to problems in astrophysics, e.g. , in the discussion on the information paradox ( i.e. , the question of information loss regarding black holes).


Introduction
In today's information age, the term "information" has become more and more important.We are living in a time of renewed paradigm shift, away from the traditional concepts of energy and matter to the prevailing concept of information in today's information age.Although the concepts of energy and matter are still present and important in our world, they are increasingly being replaced by the concept of information.This applies not only to biology with its deeper biochemistry and molecular biology, but also to physics.This is where the term "information" plays an increasingly important role alongside energy and matter as the third fundamental quantity.The American physicist J OHN A RCHIBALD W HEELER considers an information-theoretical reformulation of quantum theory in general to be promising.He once said: "Tomorrow we will have learned how to understand all physics in the language of information and how to express it in this language".The experimental physicist A NTON Z EILINGER , Vienna, even equates information with reality.Even if reality is not a concept of physics and the concept of effect has no particularly descriptive meaning in physics, one can understand physical reality as a single effect or as the sum of all effects.Then the question of a quantitative connection between information and effect arises.This connection could help to understand effect more comprehensively with the help of the concept of information and to relativize S HANNON 's information theory by taking it onto a semanto-pragmatic level.

Information manifestations
Like matter and energy, we encounter information in various forms such as literature, encyclopaedias, telephone books, news via telecommunication satellites or even communication via jungle drum, language (communication), sheet music, material-related structural information as properties, genetic information (DNA, genome), proteomic information (proteomics, proteomes), hormones and the immune systems of organisms, pheromone language of insects, computer programmes, circuit diagrams of a chip and technical drawings.It appears as potential, current, bound and free information as well as structural, functional [1] and dynamic information and possesses, among other things, statistical, syntactic, logical, semantic, pragmatic, sigmatic, teleological and transcendent 1 aspects.
Looking at the different manifestations of information, two directions of development can be seen: one direction from complex to simple, characterized by the terms decomposition, degradation, analysis and reduction, and an opposite direction from simple to complex, characterized by the terms synthesis, construction, optimization and evolution.These developments represent the production and transformation of information and always take place in the environment of an effect mechanism.The direction of higher development is generally called evolution.The two directions of the development do not always have to be directed onesidedly downward or upward.

Proposed definition of information
A general proposal for a definition of information in compact terms that could be valid for all scientific disciplines in the age of language confusion in relation to the concept of information would be:

Information is the composition of an ensemble of symbols of a certain sequence.
This definition includes all essential aspects of the concept of information such as statistics, syntax, semantics and pragmatics.The formulation "certain sequence" refers to semantics and, inextricably linked with that, to pragmatics (semanto-pragmatics).Likewise, the phrase "composition of an ensemble" refers to statistics, where the terms "probability of a composition" and "canonical ensemble" are used.

Mathematical description of effect with the help of the concept of information
Effect is understood in information theory [2,3] as a pragmatic aspect of information.How one can imagine the unfolding of effect and what role information plays in this is shown in research by elucidating mechanisms of action and the control of life development by genes.So far, however, the mathematical treatment of the relationship between the terms information and effect has not been very pronounced.
L. D E B ROGLIE for the first time developed a formula (1) in the context of the thermodynamics of the isolated particle, which can be found in the pocketbook "Waves and Particles" [4] on p. 234.It describes the equivalence of thermodynamic entropy S and effect A. The thermodynamic entropy S in turn has a proportional relationship to S HANNON 's information entropy H (see equation ( 2)).This relationship is generally accepted in physics today, if one considers entropy as potential information, i.e. as a measure of the number of possible micro states in the macro state.Entropy is associated with the number of yes-no questions (bits) needed to determine a particular state.The more information one has, the fewer questions have to be asked and the lower the entropy (entropy as missing information) [5, p. 149/150].
Thus equation (1) becomes equation ( 3) and, after division by the time t, this leads to the equivalence of information flow H / t and energy (equation ( 4)), which was first postulated by H ARTMUT I SING in 1996 [6] and means an extension of the law of energy conservation.The experimental verification of this hypothesis is still pending, but has already been mentally prepared [6].With reference to Greek philosophy (Philo of Alexandria, 1st century A.D.) I SING refers to the flow of information as "dynamic information".
L IENHARD P AGEL has also described the equivalence of information flow and energy [7, p. 27], derived a sentence on the preservation of "dynamic information" and examined its usefulness.
The D E B ROGLIE formula (1) and the P AGEL formula correspond.While D E B ROGLIE uses thermodynamic entropy, P AGEL employs S HANNON 's information entropy.Also in quantum theory the concept of information is linked with the concept of probability, namely with B ORN 's probability interpretation of the wave function ѱ, which can be understood as potential information.This expression (18) of physical entropy presents itself differently to S HANNON 's information entropy; for the latter is based on the distinguishability of the signs or the underlying binary alternatives respectively.On the other hand, the indistinguishability of the microstates must be taken into account in the quantum theoretical representation.But for the treatment of the concept of immanence presented here, the "classical" information concept of S HANNON is taken as the basis in accordance with the statement of N IELS B OHR , according to which the representation of all experience must take place in classical concepts.

Application of equations (4) and (8)
With the help of equation ( 4), the information content H M of our universe can be calculated as follows: For the theoretical calculation, the universe is regarded as a single black hole, just as one imagines the final stage of the universe according to a common theory.With the black hole entropy (B EKENSTEIN -H AWKING entropy) S H = kc 3 A H / (4 ħG) (see [2, pg. 80]) and H AWKING temperature T H = ħc 3 / (8πkGM) (see [8, pg. 111]) one then gets the equation 2 and A H = 4πR 2 for the area of the event horizon of the black hole, which measures the information potentially contained in it, then for the mass M of the universe one gets By inserting the H UBBLE constant H 0 = 2.285×10 -18 s -1 one gets for the mass of the universe H 0 = 70.5 km s -1 Mpc -1 according to WMAP5 M = 6.This theoretically calculated value, which corresponds to 10 80 proton masses and which makes up the major part of the energy of the cosmos primarily in matter form, can be compared with the value calculated from the volume and density of the universe [10, p. 850].If one uses a radius of 13.8 billion light-years for the size 1, then this value results in today M M ≅ 1.15×10 52 kg ≈ 10 69 J which is a rather good match, considering how difficult it is to obtain the astrophysical data by observation and calculation.

Application of equation (4)
With equation ( 4) the information content H M of our universe can now be calculated from the 10 70 J mass energy equivalent for the universe as follows if the age of the universe (13.8 billion years = 4.376×10 17 s) is used for the time t:
According to equation ( 8) the bound energy is and the heat equivalent of one bit Dividing the energies by the heat equivalent of a bit results in 10 99 J / k • ln2 • 10 32 K = 10 90 bits for the time of the Big Bang and 10 70 J / k • ln2 • 2.7 K = 3.87×10 92 bits for today.
If one now compares the mass energy of the universe calculated from the current cosmological data at the beginning and today, then one determines a 10 29 -fold mass energy decrease according to the standard model.This is contrasted by a 10 32 -fold temperature decrease and a 10 32 -fold entropy/information increase as well as a 10 32 -fold increase in size.In addition, the time increases 10 64 -fold.
So if one only considers the relative conditions, the following picture results if the scale and dimensions are chosen accordingly:

Conclusion:
In the universe, entropy (information) was continuously generated from mass energy during expansion, with the decrease in mass energy being equivalent to the increase in information, so that the sum remained constant over all.
If the mass energy continues to decrease and the volume increases, the density would have to decrease further over time and always remain below the critical density, provided one considers a closed system.This means, however, that the universe would have to expand further and further and no further contraction would be expected.In nature and technology, processes can be observed in which the product of temperature and time (T • t) has a meaning.For example, the product T • t seems to act as a co-factor in a kind of "internal clock" when seasonal changes occur, such as when the trees "break out" in spring or when crocuses' calyxes open and close.This is where, in the field of climatology, the term temperature sum is used.It is needed, for example, in agriculture to determine how plants flourish with this calculated size.This means that the plants only thrive well if, for example, a certain value of the temperature sum is reached in one month ("vitality rate").
In steam and hot air sterilization and pasteurization to kill microorganisms, on the other hand, the term "lethality rate" is used.
The elevated body temperature (fever curve) and its course in viral infections, sauna use, K NEIPP 's water applications, hyperthermia and hypothermia therapy, breeding of birds (the birth of life), melting of ice at the polar caps of the earth and the associated rise in sea levels, the evaporation of ice from car windows after a cold winter night, the increased depletion of the earth's ozone layer after very cold winter periods and the process of cooking potatoes can be cited as further examples where it is important to maintain the temperature over a certain period of time and thus achieve a certain effect.In general, temperature and time are important for all chemical reactions, including biochemical reactions.
If we now introduce the physical quantity I = Immanence (Latin for indwelling, adherence) as the temporal root function of temperature, this quantity can be defined as I = T • t or dI = T • dt (equation ( 5)).
Thus, using the bound energy Q g = TS, the extended mathematical equations ( 6) and (7) for the relationship between the terms information and thermodynamic effect Q g • t are obtained.Equation ( 8) represents an extended relationship (compared to equation ( 4)) for the connection between information flow and bound energy.
The description for the more general case includes the free energy F (see equation (10)).Finally, D E D ONDER's irreversibility performance P can also be used to formulate an irreversibility effect (see equation ( 12)).
These formulations ( 6), ( 7), (10) and (12) show the complementary co-factors information and immanence as cause of effect.Conversely, information results from effect.Equation ( 6) is converted into D E B ROGLIE 's formula (1) or P AGEL 's formula for the special case that the immanence is constantly h / k, thus containing both as a special case.This also applies for the origin of the universe (T • t = 10 32 K • 10 -43 s ≈ h / k) and for the fundamental principle of life according to K ARL T RINCHER (see equation ( 13)).For S = k one obtains Q g t = k I, after which immanence becomes a measure of effect and Q g = kT.
The importance of immanence cannot be overestimated.Immanence is essential for the development of life, for climate change and for the formation of structures in the universe.The term has found practical application as a "temperature sum" in climatology and as a "lethality rate" in steam and hot-air sterilization.K ARL T RINCHER recognized the meaning by naming the quotient h / k biothermodynamic constant.He discovered the fundamental principle of life (see equation ( 13)) in his studies on muscle cells in culture media.
Just as the dose determines whether an active substance is a remedy or a poison in pharmacology, the immanence determines whether one can use the term vitality rate or lethality rate.A little immanence has an invigorating effect, but too much is lethal.

Importance of immanence for structure formation in the universe
The effects of heat are also involved in the formation of structures in the universe, with the result that -due to the enormous heat -the pulpy quark gluon plasma in the Big Bang scenario is said to have evaporated after ten microseconds.
The resulting tiny irregularities, which can still be seen in the cosmic background radiation of about 2.7 K today, 13.8 billion years after the Big Bang, could as seeds have led to the formation of the galaxies.

Immanence formation principle
(according to [13, p. 32/33] with the text passages in italics from [5, p. 269ff.])From equation ( 6) the following immanence principle can be derived: It is impossible to generate or transform information without the simultaneous formation of immanence, or in other words: information and immanence cannot exist independently of each other.They are complementary co-factors.This principle could extend the knowledge of information-processing thermodynamic processes.In a revised formulation, it can be applied to astrophysical questions, such as the discussion about the information paradox (i.e. the question of information loss in black holes) as follows: For the theoretical proof that no information is lost during the radiation of the black hole, the principle of the formation of immanence is reformulated, and then reads: Where immanence is formed, information must also arise or be transformed.Black holes are not really black if you include quantum theory in the description.They radiate with a temperature proportional to the quantum of action h -the Hawking temperature -and inversely proportional to the mass.Since the radiation carries energy, it must be removed from the hole, which leads to a decrease in mass, an increase in temperature and radiation of the hole.Furthermore, a black hole has the B EKENSTEIN -H AWKING entropy, which is proportional to the surface of the event horizon and measures the potential information content of a black hole.
If, however, the radiation has a temperature, then immanence is formed and information must be generated or transformed according to the immanence formation principle, which is extracted from the black hole.So altogether there is no loss of information.
If it turns out that energy-mass is equivalent to information [2, p. 81, 11 and 15], it can also be argued in agreement and addition to this as follows, which means a substantiation of the above argumentation: If matter of the black hole radiates, information must -since the radiation carries energy -reach the outside.
How the radiation could then carry the information through the initial state in a no longer practical state (irrelevant information) would have to be shown by an exact derivation within the framework of the still outstanding theory of quantum gravity, which would lead to the fact that the radiation would no longer be purely thermal.For large black holes, the following is then true: Through the non-thermal character of the radiation, information migrates in an irreversible decoherence process in correlation with the environment and can no longer be retrieved locally, i.e. at the radiation itself.
So in general, a process of action takes place in which the information of the black hole is transformed into irrelevant information of the environment.Here one must also take note of the transition from potential information (possibility) to actual information (reality), which takes place during every irreversible process.
In the year 2004, the quantum theorists D ONALD M AROLF and J UAN M ALDACENA succeeded in proving that information must escape with H AWKING radiation.In the year 2012, the theoretical physicist J OSEPH P OLCHINSKI showed that H AWKING radiation can only carry information from the inside to the outside if the entanglement of the pairs of particles that form on the event horizon is destroyed by releasing a large amount of energy.This transforms the event horizon into a wall of fire.Quantum theory and relativity theory incompatibly collide in these theoretical considerations, because they come to completely different predictions about what happens to the matter that falls into a black hole from the outside.According to quantum theory, matter would burn up as it passed the wall of fire, and according to relativity theory, nothing remarkable would happen on the event horizon.In the latest discussion H AWKING tried to find a way out of the dilemma with a new proposal, by postulating only an "apparent horizon", which is variable in time and from which radiation can escape.

Experimental and phenomenological references
The following examples are merely indications and not evidence and are intended for illustrative purposes only.

Proteomic information and adhesion:
A NDY S MITH and his colleagues from Cornell University (www.cornell.edu/) in Ithaca (USA) tried to understand the phenomenon of proteomic control of the effect of "adhesive proteins" from their properties in snail slime.The unfolding of this effect takes place in the environment of a mechanism in which large sugar molecules are linked to each other by catalysis of the enzymes so that a solid network is formed and the original mucus quickly becomes a gel.The results could be used for the development of new, versatile and flexible adhesives and biocatalysts.
The influence of climate change is changing people's lifestyles.According to the social psychologist V OLKER L INNEWEBER , the increasingly warm weather in Germany -particularly noticed during the summer of 2003 and the summer of 2018 -is significantly changing people's lifestyles."We are confronted with effects of climate change of which we still have no idea," says the professor from the University of Magdeburg.Climate change is exacerbating famine and poverty in African countries.
The carbon cycle is at risk due to climate change, including ocean acidification, irreversible changes in coral reefs, dramatic reductions in plant plankton and impacts on the food chain.The melting of ice at the polar caps of the earth and the associated rise in sea levels is the most obvious effect of climate change.
In the summer of 2018, the lack of oxygen caused massive fish mortality in rivers and lakes.As a protective mechanism, many trees lost their leaves as they would in autumn, so that less water could evaporate through the leaves.
Although the individual mechanisms are not yet fully understood, the examples show that they are associated with information and immanence.

Information and reality
(according to [13, p. 34ff.]) The concept of describing effect with the help of the terms information and immanence, however, leads to an expanded view of the proposal of A NTON Z EILINGER , who wishes to equate reality and information [16, p. 229].My proposal is to understand reality as a single effect or as the sum of all effects.The complete description of reality -to put it philosophically -includes the transcendent 2 component of information as well as the immanent component.Here, immanence does not prove to be the core of things that exists independently of information [16, p. 230], but immanence proves to be a complementary co-factor that, together with information, grasps reality.Since information is thus only a complementary co-factor, the terms information and reality cannot be combined to a common term [16, p. 229].Thus it turns out that A NTON Z EILINGER 's proposal refers to the special case in which the immanence is constantly equal to h / k, since then, as mentioned above, equation ( 6) merges into D E B ROGLIE 's formula (1).This also applies to the origin of the universe (T• t = 10 32 K • 10 -43 s ≈ h / k) and to the fundamental principle of life according to K ARL T RINCHER (see equation ( 13)).The concept of immanence refers to a mathematical relationship between the terms information and time.This corresponds to the idea that reality is a temporal process, as D AVID B OHM explained in his explanations [17, p. 356ff.].Reality would thus be a feedback process of the production and transformation of information.Notes: 1 The transcendent character of the information is also expressed in LEONARD SUSSKIND's statement: "The minus first law of physics is: bits are not destructible.Information is forever", in: L. PAGEL: Information is Energy (2013), p. 9. 2 See note 1.
Scientific GOD Journal | December 2018 | Volume 9 | Issue 8 | pp.598-613 Jöge, F. M., Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity Scientific GOD Journal | December 2018 | Volume 9 | Issue 8 | pp.598-613 Jöge, F. M., Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity Scientific GOD Journal | December 2018 | Volume 9 | Issue 8 | pp.598-613 Jöge, F. M., Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity 25×10 52 kg According to E = Mc 2 this mass corresponds to E M = 5.6×10 69 J ≈ 10 70 J -a numerical value that S TEPHEN H AWKING also calculated for the entire current mass energy equivalent of the universe [9, p. 1355].Scientific GOD Journal | December 2018 | Volume 9 | Issue 8 | pp.598-613 Jöge, F. M., Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity 17 s) E = 1.05×10 -51 J for the energy per bit This leads to 10 70 J / 1.05×10 -51 J = 10 121 bits for the information content of the universe, which corresponds well to the values given in literature[2, p. 81 and 11, p. 388].
Scientific GOD Journal | December 2018 | Volume 9 | Issue 8 | pp.598-613 Jöge, F. M., Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity Scientific GOD Journal | December 2018 | Volume 9 | Issue 8 | pp.598-613 Jöge, F. M., Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity Scientific GOD Journal | December 2018 | Volume 9 | Issue 8 | pp.598-613 Jöge, F. M., Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity Scientific GOD Journal | December 2018 | Volume 9 | Issue 8 | pp.598-613 Jöge, F. M., Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity Scientific GOD Journal | December 2018 | Volume 9 | Issue 8 | pp.598-613 Jöge, F. M., Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity Scientific GOD Journal | December 2018 | Volume 9 | Issue 8 | pp.598-613 Jöge, F. M., Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity For quantum statistical entropy (quantum information) one obtains the functional expression Sp (ρ ln ρ) with ρ = ∑ W ik │ѱ i › ‹ ѱ k → dS/dt = Entropy production (19) P = T δ i S/dt, DE DONDER's Irreversibility performance (also called degree of irreversibility) (20) P • dt 2 = δ i S • dI Irreversibility effect (21) Meaning of the symbols used Quantities: A = Action A H = The area of the black hole event horizon that measures the information potentially contained in it b i = Width of the i-th symbol ß' = Distribution module E = Energy F = Free energy H = SHANNON's information entropy I = Immanence = T • t M = Mass of the universe N = ∑ n i = Sum of a total of N symbols n i = Number of i-th type symbols P i = Probability of drawing a symbol of type i as the next symbol (letter probability) P = DE DONDER's irreversibility performance ρ = Density operator (also statistical operator or density matrix) its characteristics are: ‹ Â › = Sp(ρÂ) hermitic operator Ŝp(ρ) = 1 ^ ρ+ = ρ (positively defined hermitic operator) Scientific GOD Journal | December 2018 | Volume 9 | Issue 8 | pp.598-613 Jöge, F. M., Information & Effect: An Introduction to the Concept of Immanence as a Physical Quantity