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1	Pion-proton elastic scattering in the energy range 300 to 700 MeV Ogden, Philip Myron. January 1964 (has links) Thesis (Ph. D. in Physics)--University of California, Berkeley, June 1964. / "UCRL-11180." Bibliography: p. 90-91. Pions
2	O mecanismo do polo do píon e a perda de energia da SN1987 A Mori, Fernando [UNESP] January 1992 (has links) (PDF) Made available in DSpace on 2016-01-13T13:27:29Z (GMT). No. of bitstreams: 0 Previous issue date: 1992. Added 1 bitstream(s) on 2016-01-13T13:31:12Z : No. of bitstreams: 1 000179954.pdf: 1712926 bytes, checksum: 1cdc7955ed3eb57ea723f56deadd37e7 (MD5) Pions
3	O mecanismo do polo do píon e a perda de energia da SN1987 A / Mori, Fernando. January 1992 (has links) Orientador: Adriano Antonio Natale / Mestre Pions.
4	Observation of two-photon emission after pion capture in carbon-12 Mazzucato, Eddy January 1979 (has links) The ¹²C(π⁻,2γ)X reaction for stopped pions has been investigated at TRIUMF using two large Nal crystals (TINA and MINA) and two lead glass Cerenkov counters. A 20 MeV pion beam from the stopped π /μ channel (M9) was used. The incoming pion beam was defined by a 3-counter telescope (S₁,S₂,S₃) and was stopped in a 1.25 cm thick carbon target. The last telescope counter (S₃) determined the time of arrival of the pions. The four γ-detectors were located at +55°, +105°, -55°, and -135°, with respect to the incident pion beam. Scintillation counters were placed in front of each γ-detector in order to identify charged particles. For the Nal crystals, time-of-flight information was used to separate neutrons and gammas originating from the (π⁻,nn) and (π⁻,nγ) reactions. Accidental coincidences from simultaneous (π⁻,γ) reactions generated by multiple pion stops in the target were rejected by measuring the energy deposited by the incoming pions in S₃. A total of 2.5x10¹¹ pions were stopped, and after background subtraction, about 500 good events were observed at 6 different opening angles (θ[sub γγ] = 50°, 80°, 110°, 120°, 160°, 170°). The total branching ratio for the ¹²C(π⁻,2γ) reaction was measured to be (1.2 ± 0.2)x0⁻⁵; this value was found to be very sensitive to the low-energy threshold of the Y~detectors. The good energy resolution (=10%) of the Nal crystals permitted the investigation of the energy-sharing between the two photons at θ[sub γγ] = 120°. The sum energy spectrum of the two photons peaks at 120 MeV i and has a width of about 40 MeV. Its shape indicates that most of the available energy is carried off by the two photons and that the residual nucleus, most likely ¹²B, is not highly excited. Detailed theoretical calculations made by other authors predict a total 2γ rate approximately 30% larger than our measured value. No evidence for pion condensates or precondensate effects in ¹²C was found. / Science, Faculty of / Physics and Astronomy, Department of / Graduate Pions
5	The absolute dosimetry of negative pions Shortt, Kenneth Robert January 1979 (has links) Soon three centres will be treating cancer with beams of negative pions: LAMPF, Los Alamos, U.S.A.; SIN, Villigen, Switzerland; and TRIUMF, Vancouver, Canada. In order to understand this new modality, it will be necessary to compare the results of pion therapy to those achieved with conventional means and to compare results among the three centres. Absolute dosimetry is the basis of this comparison. An absolute dose determination has been made for the negative pion beam at TRIUMF. using an ionization chamber. The relationship required to convert the ionization per unit mass, J/M, measured by the chamber to dose in tissue is D = J/M W r F where W, r and F are calculated quantities. W is the average energy expended in the gas per ion pair produced. Since the W-value for a secondary liberated during pion capture depends upon its energy, it was necessary to average over the energy spectra for the various secondaries. r is the ratio of dose in the wall material, carbon, to dose in the gas, either methane or carbon dioxide. Since the pion secondaries have ranges which are of the same size as the cavity of the ion chamber, it was necessary to explicitly consider those secondaries which emerge from the wall with insufficient energy to cross the cavity and those pions which form stars inside the cavity. Thus, r was found to be pressure dependent. The pressure dependence for carbon dioxide arises as follows:- as the pressure is increased, there are more pion captures in the gas, but since there is less energy released to charged secondaries per pion capture on oxygen than carbon, the dose in the gas decreases. Therefore, the calculation predicted that, as pressure is increased, J/M would remain unchanged for methane, but would decrease rather dramatically for carbon dioxide. F is the ratio of dose in tissue to dose in wall material, carbon in this case. F is the product of two factors: P, which accounts for the difference in the stopping pion density for tissue compared to carbon, and K, which accounts for the difference in energy released per pion capture in tissue compared to carbon. Experimentally, the ionization per unit mass was measured in a parallel plate chamber as a function of pressure for various gases with carbon, aluminum and TE-A150 electrodes. The pressure dependence of J/M measured for methane and carbon dioxide with carbon electrodes was compared to the behavior predicted by the calculation. Qualitatively, the prediction was confirmed: the ionization per unit mass for CO₂ decreases more dramatically with increased pressure than for CH₄. Therefore pion capture in the gas is significant and the energy released to charged secondaries per pion capture on oxygen is less than for carbon. Quantitatively, the percentage change is larger than predicted. The value of J/M extrapolated to zero pressure and the appropriate values calculated for W and r enabled a determination of the absolute dose in carbon with an estimated accuracy of ± 5%. The ionization created with aluminum electrodes was compared to that for carbon in order to estimate the dose in aluminum. After considering the dose contribution from beam contaminants, the value of F required to convert dose in carbon to dose in tissue was estimated to be 0.93 ± 0.05. Therefore, the absolute dose in tissue was determined to an accuracy of ± 7%. In order to increase the accuracy, it is necessary to improve the data available as input to the calculation. / Science, Faculty of / Physics and Astronomy, Department of / Graduate Pions
6	Hadronic response of the MINOS detectors Barker, Matthew Anthony January 2003 (has links) No description available. 539.77 Pions
7	Problems in pion physics Spearman, T. D. January 1961 (has links) No description available. 510 Pions
8	3.0 Bev/c negative pi meson-nucleus interactions Schutt, Paul Frederick, 1932- January 1959 (has links) No description available. Mesons. Pions.
9	A measurement of the Tau electronic branching ratio Robertson, Steven Hugh 10 November 2011 (has links) Graduate pions kaons
10	A pion-nucleus optical potential in coordinate-space / Lefèbvre, Pierre David January 1978 (has links) No description available. Pions -- Scattering.

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