Spin observables are very useful to improve our insight into themicrosocopic dynamics of exclusive reactions, inclusive reactions andparton distributions.Each spin observable is typically normalised to vary between -1 and +1.Pairs of observables of the same reaction are often constrained to asub-domain of the square [-1,+1]^2, such as the unit disk or a triangle.For triples of observables, the domain inside the cube [-1,+1]^3 canassume a variety of shapes: sphere, cone, pyramid, tetrahedron, etc.The corresponding inequalities can be derived by purely algebraicmethods, or from the positivity of the density matrices describing theinitial or final spin states of the reaction and its crossed channels.Examples will be given for the strangeness exchange reaction antiproton+proton -> antiLambda + Lambda, the photoproduction of pseudoscalarmesons, and the Soffer inequality for transversity distributions insidethe nucleon.
15/11/2007 at 4:00 pm
Prof. Monique Combescure, Institut de Physique Nucleaire, Lyon, France
Seminar of General Interest
Lecture Hall
Document Date:
Mutually unbiased bases in quantum information theory
Mutually unbiased bases in quantum information theory
Two orthonormal bases in dimension d are said “mutually unbiased” if the hermitian scalar products of any vector in one base with any vector in the other base are in modulus equal to the inverse square root of d. One important issue is to determine the maximum number of mutually unbiased bases (MUB) for d dimensions. If d is a prime number or a power of a prime number it is known that this maximum number is d+1. We revisit this problem in both cases using the simple notions of Discrete Fourier Transform, of unitary Hadamard matrices, and of circulant matrices (for which the successive rows are circulant permutations of each other)
29/10/2007 at 4:00 pm
Prof. L. Satpathy
Seminar of General Interest
Lecture Hall
Document Date:
Exotic Fission Decay of Neutron-Rich Urnium Isotopes
Exotic Fission Decay of Neutron-Rich Urnium Isotopes
Presently about 2000 nuclei both naturally occurring and man made are known; and different mass formulae predict the survival of another 5000 nuclei which could be synthesised in the Laboratory. Accordingly, Radioactive Ion Beam (RIB) facilities are under construction in the major laboratories around the world to explore the entire nuclear landscape. The three actinide nuclei U(233), U(235) and Pu(239) in the stability valley are thermally fissile which have been mainly used in the reactor for energy generation. The question – if other nuclei in particular heavier Uranium isotopes having such features could exist and if so what will be their fission decay properties – is of serious experimental and theoretical importance. Attempts will be made to answer these questions in the present talk. Studies reveal a number of new fission properties of such nuclei, the most prominent one being a new mode of fission decay in which along with the two heavy fragments simultaneously about 2/3 prompt neutrons will be released at the time of scission. This is termed as “Multifragmentation Fission”. Its implication for r-process nucleosynthesis in stellar evolution and energy generation will be discussed