This book describes Carmeli's cosmological general and special relativity theory, along with Einstein's general and special relativity. These theories are discussed in the context of Moshe Carmeli's original research, in which velocity is introduced as an additional independent dimension. Four- and five-dimensional spaces are considered, and the five-dimensional braneworld theory is presented. The Tully-Fisher law is obtained directly from the theory, and thus it is found that there is no necessity to assume the existence of dark (...) matter in the halo of galaxies, nor in galaxy clusters.The book gives the derivation of the Lorentz transformation, which is used in both Einstein's special relativity and Carmeli's cosmological special relativity theory. The text also provides the mathematical theory of curved space?time geometry, which is necessary to describe both Einstein's general relativity and Carmeli's cosmological general relativity. A comparison between the dynamical and kinematic aspects of the expansion of the universe is made. Comparison is also made between the Friedmann-Robertson-Walker theory and the Carmeli theory. And neither is it necessary to assume the existence of dark matter to correctly describe the expansion of the cosmos. (shrink)

Recent developments in quantum theory have focused attention on fundamental questions, in particular on whether it might be necessary to modify quantum mechanics to reconcile quantum gravity and general relativity. This book is based on a conference held in Oxford in the spring of 1984 to discuss quantum gravity. It brings together contributors who examine different aspects of the problem, including the experimental support for quantum mechanics, its strange and apparently paradoxical features, its underlying philosophy, and possible modifications (...) to the theory. (shrink)

Although exceptionally successful in the laboratory, the standard version of quantum theory is marred as a realist-objectivist proposition because of its internal conceptual difficulties and its tension with important parts of physics—most conspicuously, relativity theory. So, to meet these challenges, in recent years at least three distinct major objectivist programs have been advanced to further quantum theory into a proper general account of material systems. Unfortunately, the resulting proposals turn out to be, for all practical purposes, empirically (...) equivalent both among themselves and against the standard version. This paper analyzes the basic issues involved in the case. It is argued that (a) the global anti-realist conclusion derived from it are fallacious, and (b) the encountered underdetermination shows how contingent upon the state of empirical knowledge talk about the “limits of science” actually is. (shrink)

Since the onset of logical positivism, the general wisdom of the philosophy of science has it that the kantian philosophy of (space and) time has been superseded by the theory of relativity, in the same sense in which the latter has replaced Newton’s theory of absolute space and time. On the wake of Cassirer and Gödel, in this paper I raise doubts on this commonplace by suggesting some conditions that are necessary to defend the ideality of time in (...) the sense of Kant. In the last part of the paper I bring to bear some contemporary physical theories on such conditions. (shrink)

Special Relativity and the Early Quantum Theory were created within the same programme of statistical mechanics, thermodynamics and maxwellian electrodynamics reconciliation. I shall try to explain why classical mechanics and classical electrodynamics were “refuted” almost simultaneously or, in more suitable for the present congress terms, why did quantum revolution and the relativistic one both took place at the beginning of the 20-th century. I shall argue that quantum and relativistic revolutions were simultaneous since they had common origin - the (...) clash between the fundamental theories of the second half of the 19-th century that constituted the “body” of Classical Physics. The revolution’ s most dramatic point was Einstein’s 1905 photon paper that laid the foundations of both Special Relativity and Old Quantum Theory. Hence the dialectic of the old theories is crucial for theory change. Modern physics began with Einstein’s reconciliation of electrodynamics, mechanics and thermodynamics in 1905 and his unification of Special Relativity and Newtonian Theory of Gravity. Or, in more general social context: progressive scientific change can be described not in Weberian terms of zweckrational action forcing out all the other forms of action only but in terms of Habermas’s communicative rationality encouraging the establishment of mutual understanding between the various scientific communities also. Einstein’s programme constituted a progressive step in respect to its rivals not because it could explain more “facts” or was more “mathematical”. It was high than its rivals because it constituted a basis of communication and interpenetration between three main paradigms of 19-th century physics. Of course in the long run it resulted in empirical successes. Key words: Einstein, scientific revolution, communicative rationality. (shrink)

In lieu of an abstract, here is a brief excerpt of the content:The Human Genome ProjectSharon J. Durfy (bio) and Amy E. Grotevant (bio)In recent years, scientists throughout the world have embarked upon a long-term biological investigation that promises to revolutionize the decisions people make about their lives and lifestyles, the way doctors practice medicine, how scientists study biology, and the way we think of ourselves as individuals and as a species. It is called the Human Genome Project, and its (...) ultimate goal is to map and determine the chemical sequence of the three billion nucleotide base pairs that comprise the human genome. The feat is expected to take about fifteen years (see General Surveys).These three billion base pairs include an estimated 50,000 to 100,000 genes. The rest of the genome—perhaps 95 percent of it—is nongenic sequences with unknown function, sometimes called "junk." Determining the order and organization of all this material has been likened to tearing six volumes of the Encyclopaedia Brittanica into pieces, then trying to put it all back together to read the information (Surveys: Hall 1990). The effort could be well worth it, many scientists say, because it is expected to yield major insights into many common and complex diseases, including cancer, cardiovascular disease, and Alzheimer's disease (Debate: Dulbecco 1986; Koshland 1989).The Human Genome Project is not without controversy, however (Debate: Davis 1990; Leder 1990; Rechsteiner 1990). Many scientists fear that funding for it will be diverted from other areas of research, rather than obtained from new funding sources. This has enlivened the debate about the relative value of "big" versus "small" science. Also, the value of undertaking a complete sequencing of the genome has been questioned, especially given the high proportion of non-genic sequences.Advocates of the effort converted many critics by making two alterations in the original plan. Plans were included to simultaneously determine the nucleotide sequence of the genomes of other organisms; this provides comparisons and points of reference for the human sequence (U.S.: NIH/DOE 1990). Second, in response to concerns about the high cost of developing technology to sequence the whole [End Page 347] genome, the focus moved from large-scale sequencing to mapping the genome, which would hasten the search for disease genes (U.S.: NIH/DOE 1990).The ideal map would be both genetic, locating DNA markers, or signposts, at closely spaced intervals along the chromosomes, and physical, indicating the exact distance between these markers (Map: McKusick 1991). Since 1973, Human Gene Mapping workshops (HGM) have been held at least every two years to locate, compare, and compile genetic markers. This information is published and is accessible through Genome Database at Johns Hopkins University (McKusick 1991). The most recent Human Genome Mapping workshop was held in August 1991, at which the Human Genome Organization (HUGO) began to assume increased responsibility for coordination of the international mapping effort (Surveys: Maddox 1991).Historical Background of the United States EffortThe first serious discussions about sequencing the entire human genome occurred at a workshop at the University of California at Santa Cruz in 1985 (U.S.: Sinsheimer 1989). A second workshop, organized by the U.S. Department of Energy (DOE) and held in March 1986, addressed the feasibility of an organized program (U.S.: DOE 1986). Shortly thereafter, DOE instituted its own genome project (U.S.: DOE 1987). Reports in early 1988 from both the National Research Council (NRC) of the National Academy of Sciences (NAS) and Congress' Office of Technology Assessment (OTA) (U.S.: NRC 1988; OTA 1988) served as catalysts, and in fiscal year 1988, the U.S. Congress officially launched the Human Genome Project by appropriating funds to both the Department of Energy and the National Institutes of Health (NIH).To avoid potential congressional "meddling" (U.S.: Roberts 1988), NIH and DOE drafted a memorandum of understanding for interagency coordination in October 1988 (U.S.: NIH/DOE 1990). The agencies then created both separate and joint committees, and working groups to administer the project. NIH established the Office of Human Genome Research in 1988 (directed by James D. Watson) to plan and coordinate NIH genome activities. That office has evolved into the National Center for Human Genome Research (NCHGR... (shrink)

Rethinking “philosophy” to-day, it is necessary to think first of all about ontological foundations of the modern scientific universe description and rethink them on the ground of modern scientific knowledge, because until now there is no any precise scientific conception of the structure of the universe, of reasons and movingforces of its permanent evolution. All of it create basis to propose various unscientific ideas of creationism. Until now most of philosophers associate the motion of Matter on the whole only with (...) its motion in space and in time, mixing philosophical and physical aspects of these two principle categories. Generally speaking, the present-day ontological model of understanding the World, the Universe is constructed purely on the basis of only these two fundamental categories. However, a more deep reflection of the essence of Being, if to realize it on the basis of only these two global categories, brings us to the disappointing conclusion, that in this case we have nothing more except a mechanical motion, i.e. spatial displacement of a material point (or a system of points) relatively some point of counting off. To make it normal and logic we should add to the ontological model one more essential part – the motion in quality. So, in order to create the full and complete picture of the formation and evolution of the material World it is necessary to observe the motion of material forming in the three equivalentphilosophical categories: in space time quality. The ideas of the new conception of ontological model become actual supplementation of really scientific philosophical knowledge on the way of a more objective ontological comprehension of our Being, of the law of development of the human civilization and the Universe as a whole. This knowledge can be successfully used for the description of the realistic paradigm of Being, in explanations of the meaning of Life. (shrink)

The main idea of quantum mechanics, whether formulated in terms of the Planck constant or the noncommutativity of certain observables, must be tied to the recognition of the relativity and nonuniversality of the abstract concept of set (manifold) in the description of quantum systems. This entails the necessarily probabilistic description of quantum systems: since a quantum system ultimately cannot be decomposed into elements or sets, we have to describe it in terms of probabilities of only a relative selection of (...) certain elements or sets in its structure. This gives rise to the potential possibilities of quantum systems in an actual physical situation, and as a result the corresponding probabilities are ontologically real, like any other physically verifiable relationships. In this way, the quantum potential possibilities (and probabilities as their measure) are no less objectively real than the conventional reality which we identify with the physically directly verifiable elements, particles, etc. Indeed, the distribution of probabilities described by the nonfactorizable wave function is as objectively real and concrete as chairs, walls and all other physical things. In the pure quantum state the probabilities of selection of elements from the ultimately detailed state of the system are mutually coordinated and correlated by the phenomenon of wholeness of the system, and form an implicative logical structure governed by this phenomenon of wholeness. This idea of the implicative logical organization of the probabilistic structure of a quantum system in the so-called pure (non-detailable) state, and the governing role of the phenomenon of wholeness (in the redistribution of probabilities depending on the nature of the development of the real experiment), is in good agreement with the results of quantum correlation experiments (for example, the experiments of Alain Aspect, Nicolas Gisin and others). (shrink)

The main idea of quantum mechanics, whether formulated in terms of the Planck constant or the noncommutativity of certain observables, must be tied to the recognition of the relativity and nonuniversality of the abstract concept of set (manifold) in the description of quantum systems. This entails the necessarily probabilistic description of quantum systems: since a quantum system ultimately cannot be decomposed into elements or sets, we have to describe it in terms of probabilities of only a relative selection of (...) certain elements or sets in its structure. This gives rise to the potential possibilities of quantum systems in an actual physical situation, and as a result the corresponding probabilities are ontologically real, like any other physically verifiable relationships. In this way, the quantum potential possibilities (and probabilities as their measure) are no less objectively real than the conventional reality which we identify with the physically directly verifiable elements, particles, etc. Indeed, the distribution of probabilities described by the nonfactorizable wave function is as objectively real and concrete as chairs, walls and all other physical things. In the pure quantum state the probabilities of selection of elements from the ultimately detailed state of the system are mutually coordinated and correlated by the phenomenon of wholeness of the system, and form an implicative logical structure governed by this phenomenon of wholeness. This idea of the implicative logical organization of the probabilistic structure of a quantum system in the so-called pure (non-detailable) state, and the governing role of the phenomenon of wholeness (in the redistribution of probabilities depending on the nature of the development of the real experiment), is in good agreement with the results of quantum correlation experiments (for example, the experiments of Alain Aspect, Nicolas Gisin and others). (shrink)