ایک کمی
جب کہانی کا مرکزی کردار مر جائے
تو ثانوی کردار ادھورے رہ جاتے ہیں
یہ ادھورا پن بھی کتنی بڑی کمی ہے
Strategic issues are the core of the work of business organizations and occupy the main pillar of the work of commercial banks, whose fields of work and their competitive environment have developed. Strategic flexibility has become an urgent and binding issue for the commercial banking sector to keep pace with environmental changes and developments and raise the performance of banks to keep pace with environmental developments. The research aims to delve into two very important variables by doing The commercial banking sector, which is flexibility The strategy and performance of the banks. Six commercial banks were chosen to be happy with the research (Baghdad, Iraqi investment, Gulf, investment development, Al-Mansour, Babylon). A member of bank managers, people's officials, and accountants in commercial banks. The data were subjected to statistical analysis by applying the statistical program (spss). The results demonstrated an impact on the overall level of the two variables. The study (strategic flexibility, bank performance) The findings revealed the existence of relationships between (banking service flexibility, competitive flexibility, investment flexibility, and human resource flexibility). And bank performance at the sub-dimension level (financial dimension, customer dimension, internal operations dimension, education and growth dimension). The study came to a set of conclusions and suggestions.
The primary orientation of this thesis is to explore some interesting linear and nonlinear instabilities of low frequency waves in magnetized plasmas including the dust dynamics. These waves may be electrostatic or electromagnetic in nature. These investigations find significance and applications in small and large scale plasmas. This thesis contains several novel collective modes and instabilities in both classical and quantum plasmas. The low-frequency long wavelength electro- magnetic waves, viz., shear Alfv ́n waves in a cold dusty plasma, are examined e employing two-potential theory and plasma fluid model. It is observed that the presence of the unmagnetized dust particles and magnetized plasma components give rise to a new ion-dust lower hybrid cutoff frequency for the electromagnetic shear Alfv ́n wave propagation. e Subsequently, we consider the parametric instabilities for two regimes. First, the parametric decay instability of an Alfv ́n wave into low-frequency electro- e static dust-lower-hybrid and electromagnetic shear Alfv ́n waves in a classical e dusty magnetoplasma. Second, the parametric decay instability of a dust ion acoustic wave into low-frequency electrostatic dust-lower-hybrid and electromag- netic shear Alfv ́n waves is also investigated in detail in an inhomogeneous cold e quantum dusty plasma in the presence of an ambient uniform magnetic field. Magnetohydrodynamic fluid equations and the quantum magnetohydrodynamic model of plasmas with quantum effect arising through the Bohm potential and the Fermi degenerate pressure are employed in order to find the linear and nonlin- ear response of the plasma particles for three-wave nonlinear coupling in a dusty magnetoplasma. Here, the two cases are discussed, the first when the pump taken to be a relatively high frequency electromagnetic Alfv ́n wave and in the second e case the pump is an electrostatic dust ion acoustic wave. It couples with other two low-frequency internal possible modes of the dusty magnetoplasma, viz., the dust-lower-hybrid and shear Alfv ́n waves. The nonlinear dispersion relation of e the dust-lower-hybrid wave is solved to obtain the growth rate of the parametric decay instability. The growth rate of the dust-lower-hybrid wave is derived and solved graphically for different cases. Finally, the drift waves and their instabilities are investigated in detail in a nonuniform dusty magnetoplasma using the quantum hydrodynamic model of plasmas with the ion streaming. It is found that in the presence of a nonuniform ambient magnetic field, the drift waves grow in amplitude by taking energy from the streaming ions and density inhomogeneity.