General Solution of the Schrödinger Equation with Potential Field Quantization and Some Applications

Stok Kodu:
9786254330308
Boyut:
19.5x23.5
Sayfa Sayısı:
150
Basım Tarihi:
2021-10
Kapak Türü:
Ciltsiz
Kağıt Türü:
1. Hamur
%15 indirimli
195,00TL
165,75TL
Taksitli fiyat: 9 x 20,26TL
Temin süresi 2-5 gündür.
9786254330308
1203778
General Solution of the Schrödinger Equation with Potential Field Quantization and Some Applications
General Solution of the Schrödinger Equation with Potential Field Quantization and Some Applications
165.75

A simple procedure has been found for the general solution of the time-independent Schrödinger Equation (SE) with the help of quantization of potential area in one dimension without making any approximation. Energy values are not dependent on wave functions. So, to find the energy values, it is enough to find the classic turning points of the potential function. Two different solutions were obtained, namely, symmetric, and antisymmetric in bound states. These normalized wave functions are always periodic. It is enough to take the integral of the square root of the potential energy function to find the normalized wave functions. If these calculations cannot be made analytically, they should then be performed by numerical methods. The SE has been solved for a particle in many one-dimension and the spherical symmetric central potential well as examples. The relative Dirac Equation is also solved. Their energies and normalized wave functions were found as examples. These solutions were also applied to the theories of scattering and alpha decay. The results obtained with the experimental values were compared with the calculated values. One was seen to be very fit.

A simple procedure has been found for the general solution of the time-independent Schrödinger Equation (SE) with the help of quantization of potential area in one dimension without making any approximation. Energy values are not dependent on wave functions. So, to find the energy values, it is enough to find the classic turning points of the potential function. Two different solutions were obtained, namely, symmetric, and antisymmetric in bound states. These normalized wave functions are always periodic. It is enough to take the integral of the square root of the potential energy function to find the normalized wave functions. If these calculations cannot be made analytically, they should then be performed by numerical methods. The SE has been solved for a particle in many one-dimension and the spherical symmetric central potential well as examples. The relative Dirac Equation is also solved. Their energies and normalized wave functions were found as examples. These solutions were also applied to the theories of scattering and alpha decay. The results obtained with the experimental values were compared with the calculated values. One was seen to be very fit.

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