Demystifying Emergence

Are the special sciences autonomous from physics? Those who say they are need to explain how dependent special science properties could feature in irreducible causal explanations, but that’s no easy task. The demands of a broadly physicalist worldview require that such properties are not only dependent on the physical, but also physically realized. Realized properties are derivative, so it’s natural to suppose that they have derivative causal powers. Correspondingly, philosophical orthodoxy has it that if we want special science properties to bestow genuinely new causal powers, we must reject physical realization and embrace a form of emergentism, in which such properties arise from the physical by mysterious brute determination. In this paper, I argue that contrary to this orthodoxy, there are physically realized properties that bestow new causal powers in relation to their realizers. The key to my proposal is to reject causal-functional accounts of realization and embrace a broader account that allows for the realization of shapes and patterns. Unlike functional properties, such properties are defined by qualitative, non-causal specifications, so realizing them does not consist in bestowing causal powers. This, I argue, allows for causal novelty of the strongest kind. I argue that the molecular geometry of H2O—a qualitative, multiply realizable property—plays an irreducible role in explaining its dipole moment, and thereby bestows novel powers. On my proposal, special science properties can have the kind of causal novelty traditionally associated with strong emergence, without any of the mystery

Value and doubt: the persuasive power of 'authenticity' in the antiquities market

No abstract available

Potential of series hybrid drive systems to reduce fuel use and emissions in domestic vehicles : a thesis presented in partial fulfilment of the requirements for the degree of Master of Technology in Energy Development at Massey University

For the last 100 years the reciprocating internal combustion engine (ICE) powered vehicle and the fossil oil that it is reliant upon has dominated our transport culture. In terms of land-based domestic and commercial transport, we would be completely lost without it. Most goods and services are transported by it. We use it to get to work, pick up the children, do the shopping and for some of us the domestic vehicle is an extension of our personalities. It has become an indispensable business and recreational tool of modern contemporary society. The conventional ICE powered vehicle initially gave us freedom, the ability to go wherever and whenever we wanted and to do it relatively cheaply. Now, however, our ever-increasing search for more mobility and the transport of goods and services has imprisoned modern society into high levels of emissions, pollution, increasing oil dependence, oil depletion concerns and the creation of resource wars in search of more energy (oil) to pursue our need for travel, transportation and the proper running of a modern society. This is because transport in general registers the most rapid increases in energy consumption and remains almost entirely dependent on oil because of few substitution possibilities to less carbon intensive fuels (IEA, 2000b). In most affluent countries the ICE powered vehicle meets 75 to 80 percent of personal travel (Sperling, 1996a)

Improvements of Zeyded method for calculating flutter of flat panels

Method for calculating flutter boundaries and estimating stresses in infinite spanwise array of panels is presented. Numerical analyses are included for pinned edge panels, isotropic panel material, zero viscous damping, and no elastic foundation. Design flutter boundaries are presented for aluminum panels on Saturn spacecraft trajectory

Substrate specificity and structural investigation into PepO and PepW : two peptidases from Lactobacillus rhamnosus : a thesis presented in partial fulfilment of the requirements for the degree of Master of Science in Biochemistry at Massey University, Palmerston North, New Zealand

The proteolytic systems of lactic acid bacteria have important roles in the maturation and flavour development of cheese. Lactic acid bacteria pepetidases contribute to the taste of cheese through the production of low-molecular weight peptides and free amino acids. Although some lactic acid bacteria peptidases have been structurally and enzymatically characterised for their substrate specificity, there are some that are yet to be completely biochemically characterised. The aim of the present study was to investigate the substrate specificity and three-dimensional structure of two peptidases that could potentially be used as a tool to modify and control cheese bitterness and possibly other flavour attributes from Lactobacillus rhamnosus, PepO and PepW. The pepW gene was successfully cloned from L. rhamnosus into an E. coli expression system. Recombinant PepW was purified to homogeneity and was shown to exist as a hexamer of 50 kDa subunits. Recombinant PepO was expressed from a previously established L. lactis expression system and purified to homogeneity. PepO was shown to exist as a 70 kDa monomer, and function as a metallopeptidase. Pepo and PepW were shown to selectively hydrolyse chymosin-derived bovine β- and κ-casein peptides, and casein peptides extracted from Cheddar cheese. One conclusive PepO cleavage site that had not been previously characterised was identified. This was the β-casein peptide bond between Leu₆-Asn₇. Several possible PepO and PepW cleavage sites in αs₁-, β- and κ- casein were identified, suggesting that PepO has a broad endopeptidase activity, whilst PepW has a specific exopeptidase activity. Pepo and PepW crystals were successfully grown for structure determination by x-ray crystallography. Native data sets were collected for both PepO and PepW, and derivative data were collected for PepO. Structure determination was attempted using Multiple Isomorphous Replacement and Molecular Replacement techniques. Results from the substrate specificity and structural investigation of the L. rhamnosus peptidases, PepO and PepW, are presented in this thesis

Lambda and Antilambda reconstruction in central Pb C Pb collisions using

The large acceptance time projection chambers of the NA49 experiment are used to record the trajectory of charged particles from Pb + Pb collisions at 158 GeV per nucleon. Neutral strange hadrons have been reconstructed from their charged decay products. To obtain distributions of Λ, and Ks0 in discrete bins of rapidity, y, and transverse momentum, pT, calculations have been performed to determine the acceptance of the detector and the efficiency of the reconstruction software as a function of both variables. The lifetime distributions obtained give values of cτ = 7.8 ± 0.6 cm for Λ and cτ = 2.5 ± 0.3 cm for Ks0, consistent with data book values