Global ETD Search

211	Searching for gamma-ray signals form pulsars and periodic signals fromthe galactic gamma-ray sources 吳文謙, Ng, Man-him. January 1996 (has links) published_or_final_version / Physics / Master / Master of Philosophy Gamma ray sources. Galactic cosmic rays.
212	Simulations and software developments for cosmic-ray and particle physics experiments in underground laboratories 曾熙旻, Tsang, Hei-man. January 2007 (has links) published_or_final_version / abstract / Physics / Master / Master of Philosophy Particles (Nuclear physics) Cosmic rays. Gamma rays.
213	Studies of gadolinium-loaded liquid scintillator used in the Aberdeen tunnel experiment in Hong Kong Lee, Ka-pik., 李嘉碧. January 2008 (has links) published_or_final_version / Physics / Master / Master of Philosophy Gadolinium. Scintillators. Cosmic ray muons - Measurement.
214	Electromagnetic interactions of cosmic ray muons 劉愼言, Lau, Shun-yin. January 1976 (has links) published_or_final_version / Physics / Doctoral / Doctor of Philosophy Cosmic rays. Muons - Spectra. Electromagnetic interactions.
215	Measurements of Cosmic Ray Antiprotons with PAMELA Wu, Juan January 2010 (has links) QC 20100420 cosmic ray antiproton PAMELA Astroparticle physics Astropartikelfysik
216	THE APPLICATION OF IMAGING TO THE ATMOSPHERIC CERENKOV TECHNIQUE: OBSERVATIONS OF THE CRAB NEBULA. GIBBS, KENNETH GERARD. January 1987 (has links) Gamma-ray astronomy is generally viewed as an adjunct to cosmic ray physics. As such, the observation of very high energy gamma-rays will allow a new and complementary means of examining the origin and evolution of cosmic rays. However, at present the atmospheric Cerenkov technique (the technique by which very high energy gamma-rays are observed) is seriously hampered by limited flux sensitivity. Monte Carlo simulations suggest that the application of imaging to the atmospheric Cerenkov technique will provide a much needed increase in sensitivity. The successful application of imaging to very high energy gamma-ray observations of the Crab nebula will be discussed, as will improved techniques for calibration and noise rejection. These observations permit an improved estimate of the nebular magnetic field strength. Cosmic rays. Crab Nebula. Cherenkov counters.
217	Detection of high-energy cosmic ray showers by atmospheric fluorescence. Halverson, Peter Georges. January 1989 (has links) A novel detector for ultra-high energy cosmic rays, and its prototype are discussed. It detects events with primary energy greater than 100 PeV. (1 PeV = 1000 TeV; 1EeV = 1000 PeV.) The detector operates by sensing the near-ultraviolet scintillation light of ionized nitrogen molecules created by the passage of ionizing particles in extensive air showers. (The concept is loosely based on the highly successful Fly's Eye detector situated at Dugway, Utah.) Typical events should consist of 1 to 100 EeV primary energy showers, with near-vertical cores, passing through the detector's field-of-view at distances of 1 to 20 km. The optical field of view of the hypothetical detector would be 60 degrees wide by several (≈ 3) degrees high and would look in a near-horizontal direction at a distant mountain range or other suitably dark background roughly 20 Ian away. A typical good location would be the rim of a canyon, looking slightly downward at the other side. The field-of-view would be subdivided into 3 or more thinner ''wedges'', 60 degrees wide by, perhaps, 1 degree high. A single detector provides timing and brightness information only. Three widely-separated detectors with overlapping fields-of-view provide sufficient data to determine the core location, the zenith and azinruthal angles of the core axis, and the absolute luminosity of the cascade. Interpretation of the luminosity data would be a challenge, but it should be possible to estimate primary energy from it. The advantage of this new scheme is the enormous effective detector area per relatively low-cost detector module. Each triplet of detectors "sees" 300 square km with a typical core axis acceptance of roughly 1 sr. The construction and testing of a prototype unit has been accomplished. The field-of-view was 41 degrees wide by 2 degrees high. Light was collected by a 4.7 square meter mirror and focused onto a wave-shifter PMT system. 8 events with primary energies in the 0.1 to 1 EeV range were observed in an 8.5 hour period. Representative events are shown and preliminary data analysis is discussed. Cosmic ray showers. Optical detectors. Fluorimetry.
218	Local atmospheric electricity and its possible application in high-energy cosmic ray air shower detection. Chen, Chuxing. January 1989 (has links) We have conducted an extensive experimental study on the subject of near ground atmospheric electricity. The main objective was to gain more understanding of this particular aspect of atmospheric phenomena, while testing the possible application to cosmic ray research. The results in atmospheric electricity show that there are certain patterns in ion grouping such as the size and lifetime. The average lifetime of ion group is 0.7 seconds and the average size is about 10 meters at our experimental site. Ultrahigh energy cosmic ray air showers should create sizable slow atmospheric electric pulses according to our theoretical calculations. Preliminary studies on air showers with total particle number N equal or greater than 10⁵ (10¹⁵ eV) have yielded strong evidence that slow atmospheric current pulses are associated with air showers. The theory and the experiment agree with each other fairly well when we average over large numbers of events. With our current experimental arrangement, when the air shower exceeds a certain size, the system response saturates. Therefore it is extremely desirable in future research that the counter array be designed for a much higher threshold level, since this prototype experiment indicates that interesting data would be obtained. Another reason for further experimental research being directed toward ultrahigh energy, e.g., N ≥ 10⁷ (10¹⁷ eV) and higher, is to establish a calibration of the slow atmospheric electric signals generated by cosmic rays as a function of primary cosmic ray energy and core location. This type of slow atmospheric electric signal, if fully understood and calibrated, offers a new and potentially less expensive technique to observe ultrahigh energy cosmic ray events, which hold some fundamental keys to the knowledge of the universe on a large scale. Atmospheric electricity. Atmospheric ionization. Cosmic ray showers.
219	Thermal fields and cosmic loops Steer, Daniele Ann January 1997 (has links) No description available. 530.1
220	Field theory and topological defects Gill, Alasdair James January 1996 (has links) No description available. 530.1 Quantum field theory; Cosmic strings

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