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Dr.Eman Zakaria Hegazy Quantum Mechanics and Statistical Thermodynamics Lecture 18 A trial function that depends linearly on the variational parameters leads to a secular determinant - as another example of the variational method, consider a particle in one dimensional box. We should expect it to be symmetric about x = a/2 and to go to zero at the walls. - one of the simplest functions with this properties is xn ( a-x)n , where n is a positive integer , consequently , let’s estimate Eo by using : c1x (a x ) c 2 x 2 (a x ) 2 (1) Where c1 and c2 are to be the variational parameters. We find after the energy of particle in one dimensional box exactly equal to: E exact h2 h2 0.125000 2 8ma ma 2 (2) Now we will use a trial function to calculate Emin to particle in one dimensional box. A trial function can be generally written as: N C n f n n 1 (3) Where the Cn are variational parameters and fn are arbitrary known functions [1] Dr.Eman Zakaria Hegazy Quantum Mechanics and Statistical Thermodynamics Lecture 18 Consider c1f 1 c 2f 2 Then : ˆ d (c f c f )Hˆ (c f c f )d H 11 22 11 22 ˆ d c c f Hf ˆ d c c f Hf ˆ d c 2 f Hf ˆ d c12 f 1Hf 1 1 2 1 2 1 2 2 1 2 2 2 c12 H 11 c1c 2 H 12 c1c 2 H 21 c 22 H 22 (4) Where ˆ d H ij f i Hf j (5) We will note that : f i ˆ d f Hf Hf j j ˆ id (6) So Hij=Hji Using this result, equation (4) becomes ˆ d c 2 H 2c c H c 2 H H 1 11 1 2 12 2 22 (7) Similary we have [2] Dr.Eman Zakaria Hegazy Quantum Mechanics and Statistical Thermodynamics Lecture 18 2 2 2 d c S 2 c c S c 1 11 1 2 12 2 S 22 (8) Where S ij S ji f i f j d (9) The quantities Hij and Sij are called matrix elements . By substituting equations 7,8 into equation 10 E 0 Ĥ 0d 0 0d (10) We find that : c12 H 11 2c1c 2 H 12 c 22 H 22 E (c1 , c 2 ) 2 c1 S 11 2c1c 2S 12 c 22S 22 (11) Before differentiating E(c1,c2) in equation 11 with respect to c1and c2 , it is convenient to write equation 11 in the form: E (c1 , c 2 )(c12S 11 2c1c 2S 12 c 22S 22 ) c12H 11 2c1c 2 H 12 c 22H 22 (12) If we differentiate equation 12 with respect to c1 we find that (2c1 S 11 2c 2S 12 )E E 2 (c1 S 11 2c1c 2S 12 c 22S 22 ) 2c1 H 11 2c 2 H 12 (13) c1 Because we are minimizing E with repect to c1 , equation 13 becomes [3] E c1 =0 and so Dr.Eman Zakaria Hegazy Quantum Mechanics and Statistical Thermodynamics Lecture 18 (2c1 S 11 2c 2S 12 )E 2c1 H 11 2c 2 H 12 c1 (H 11 ES 11 ) c 2 (H 12 ES 12 ) 0 (14) Similarly by differentiating E(c1,c2)with repect to c2 instead of c1 we find c1 (H 12 ES 12 ) c 2 (H 22 ES 22 ) 0 (15) Equations (14) and (15) constitute a pair of linear algebraic equations for c1 and c2 This equation is not simply solved but if c1 = c2 H 11 ES 11 H 12 ES 12 H 12 ES 12 0 H 22 ES 22 (16) To illustrate the use of equation 16 let us go back to solving the problem of a particle in a one – dimensional box variationally using equation (1) c1x (a x ) c 2 x 2 (a x ) 2 We will set a = 1. In this case , f1 = x (1- x) and f2 = x2 (1- x) 2 So, we will solve H11 , H12, H22 , S11, S12 and S22 from the equations (5) , (9) [4] Dr.Eman Zakaria Hegazy Quantum Mechanics and Statistical Thermodynamics Lecture 18 ˆ d H ij f i Hf j S ij S ji f i f j d 2 d ˆ H 11 f 1Hf 1d x (1 x ) x (1 x ) dx 2 2m dx 0 1 2 1 x (1 x ) 0 2dx 2m 0 2 2m 1 2 2 x 2 x )dx 0 2 1 2 2 2 3 x x 2m 0 3 6m - As the same you can get H12 and H22 2 2 H12 = H21= and 30m H22 = 1 2 f dx 1 - Also we can get S11 = 0 2 1 x (1 x ) dx 0 [5] 105m Dr.Eman Zakaria Hegazy Quantum Mechanics and Statistical Thermodynamics Lecture 18 1 (x 2 2x 3 x 4 )dx 0 2 1 1 1 10 x 3 x 4 x 5 4 5 30 3 - As the same we can get S12 and S22 1 S12 = S21 = 140 1 and S22 = 630 - Substituting the matrix elements Hij and Sij into the secular determinant gives 1 E 1 E 6 30 30 140 0 1 E 1 E 30 140 105 630 where E = E m/ 2 . The corresponding secular equation is E 2 - 56 E +252=0 whose roots are E 56 2128 51.065and 4.93487 2 We choose the smaller root and obtain [6] Dr.Eman Zakaria Hegazy Quantum Mechanics and Statistical Thermodynamics Lecture 18 2 E min h2 4.93487 0.125002 m m Compare with Eexact when a =1 E exact h2 0.125000 m The excellent agreement here is better than should be expected normally for such a simple trial function. Note that E min E exact , as it must be. Example Using Equation f1=x (1-x) and f2= x2(1-x) 2, show explicitly that H12=H21 Solution: using the Hamiltonian operator of a particle in a box, we have 1 2 d 2 2 ˆ H 12 f 1Hf 2dx x (1 x ) x (1 x ) dx 2 2 m dx 0 2 2m 1 2 dx x (1 x ) 2 12 x 12 x 0 1 2m 15 30m 2 2 [7] Dr.Eman Zakaria Hegazy Quantum Mechanics and Statistical Thermodynamics Lecture 18 2 d 2 2 ˆ H 21 f 2 Hf 1dx x (1 x ) x (1 x ) dx 2 2m dx 0 1 2 2m 1 2 2 x (1 x ) 2dx 0 1 2m 15 30m 2 2 [8]