Advanced Neutron Sources 1988, Proceedings of the 10th Meeting of the INT Collaboration on Advanced Neutron Sources (ICANS X), Held at Los Alamos, October 1988Revolving around the interaction between spectrometer and target-station design and performance, this volume emphasises the need for feedback that must exist between scientific requirements and source design. It achieves a forum for the sharing of information on the development of spallation neutron sources. Of great value to researchers in condensed matter physics, instrumentation and data processing involved in neutron scattering at pulsed and steady sources. |
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Results 1-3 of 80
Page 56
... temperature distribution . The temperature rise per μA was thus determined as 15.6 ± 3.2 ° C / μA . The maximum temperature of the target block is , therefore , estimated to be 177 ± 32 ° Cat the designed proton - beam current of 10 μA ...
... temperature distribution . The temperature rise per μA was thus determined as 15.6 ± 3.2 ° C / μA . The maximum temperature of the target block is , therefore , estimated to be 177 ± 32 ° Cat the designed proton - beam current of 10 μA ...
Page 350
... temperature of Ba in HoBa2Cu3O7 is the same as that of barium metal . From these results , the effective temperatures of Y and Ba in Y Ba2Cuз07 at T = 300 K were assumed to be Teff = 300 K. Then , the effective temperatures of Y and Ba ...
... temperature of Ba in HoBa2Cu3O7 is the same as that of barium metal . From these results , the effective temperatures of Y and Ba in Y Ba2Cuз07 at T = 300 K were assumed to be Teff = 300 K. Then , the effective temperatures of Y and Ba ...
Page 351
... TEMPERATURE ( K ) 1200 1000 800 Cu in YBa2 Cu 3 07 Cu in La2 Cu04 600 Fo 400 Cu in CuO 200 Copper metal 500 1000 1500 2000 2500 DEBYE TEMPERATURE ( K ) Fig . 8 Relation between the effective temperature and the Debye temperature at ...
... TEMPERATURE ( K ) 1200 1000 800 Cu in YBa2 Cu 3 07 Cu in La2 Cu04 600 Fo 400 Cu in CuO 200 Copper metal 500 1000 1500 2000 2500 DEBYE TEMPERATURE ( K ) Fig . 8 Relation between the effective temperature and the Debye temperature at ...
Contents
Monday October 3 1988 | 9 |
Tuesday October 4 1988 | 135 |
Wednesday October 5 1988 | 609 |
Copyright | |
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accelerator Advanced Neutron Sources analysis angular background beam line Brillouin scattering calculated chopper cold neutron cold source collimators count rate cross section crystal data acquisition deconvolution decoupled density detector deuterium diffraction diffractometer distribution dose effective energy transfer experimental experiments facility factor Figure fission flight path foil function gamma Gaussian geometry high-energy histogram improve increase inelastic injection instrument intensity IPNS irradiation ISIS LAMPF leakage liquid hydrogen Los Alamos magnetic material MaxEnt maximum measured methane module Monte Carlo neutron beam neutron flux neutron scattering Nucl Nuclear obtained operation optimization parameters peak performance Phys position present problems produced proton proton beam radiation radius range reactor reconstruction reflector resolution Rutherford Appleton Laboratory sample scattering angle shield shown in Fig shows solid methane spallation neutron source spallation source spectra spectrometer spectrum surface temperature thermal neutron thick time-of-flight tube wavelength width