About the radial Schrödinger quation

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Douasing
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Dear all,
I meet a difficult question as follows:

[itex]-\frac{1}{ρ^{2}}\frac{d}{dρ}(ρ^{2}\frac{dR_{l}}{dρ})+[\frac{l(l+1)}{ρ^{2}}+V(ρ)]R_{l}(ρ)=ER_{l}(ρ)[/itex] (1)

let [itex]x=ln(ρ)[/itex] and [itex]y=ρ^{1/2}R_{l}(ρ)[/itex] ,then

[itex]y^{''}=γy[/itex] (2)
[itex]γ=exp(2x)(V-E)+(l+\frac{1}{2})^{2}[/itex] (3)

What is the details from (1) to (2) and (3)?


Thank you in advance!

Paul
 
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Hi Paul! Welcome to PF! :smile:

(type "tex" instead of "itex" when you have tiny fractions! :wink:)
Douasing said:
Dear all,
I meet a difficult question as follows:

[tex]-\frac{1}{ρ^{2}}\frac{d}{dρ}\left(ρ^{2}\frac{dR_{l}}{dρ}\right)+ \left[\frac{l(l+1)}{ρ^{2}}+V(ρ)\right]R_{l}(ρ)=ER_{l}(ρ)[/tex] (1)

let [itex]x=ln(ρ)[/itex] and [itex]y=ρ^{1/2}R_{l}(ρ)[/itex] ,then

[itex]y^{''}=γy[/itex] (2)
[itex]γ=exp(2x)(V-E)+(l+\frac{1}{2})^{2}[/itex] (3)

What is the details from (1) to (2) and (3)?


Thank you in advance!

Paul
Put y = (√ρ)Rl(ρ), and differentiate twice …

show us what you get :wink:
 
tiny-tim said:
Hi Paul! Welcome to PF! :smile:

(type "tex" instead of "itex" when you have tiny fractions! :wink:)

Put y = (√ρ)Rl(ρ), and differentiate twice …

show us what you get :wink:




y''= -(1/4)ρ^(-3/2) R + ρ^(-1/2) R' + ρ^(1/2) R''

Am I right?
 
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Douasing said:
y''= -(1/4)ρ^(-3/2) R + ρ^(-1/2) R' + ρ^(1/2) R''

Am I right?

yes :smile:

hmm … that doesn't help at all :confused:

ohhhh … i think y'' means wrt x :redface:

try it with y = ex/2R(x) :wink:
 
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tiny-tim said:
yes :smile:

hmm … that doesn't help at all :confused:

ohhhh … i think y'' means wrt x :redface:

try it with y = ex/2R(x) :wink:

y''= [(1/4)R(x)+R'(x)+R''(x)]e^(x/2)

Is it right ?
 
By the way, The formulas above are in the book by L.T. Loucks (1967). But the mathematical techniques are not well understood by us,so I posted them here.
 
Hi Douasing! :smile:

(just got up :zzz:)
Douasing said:
y''= [(1/4)R(x)+R'(x)+R''(x)]e^(x/2)

Is it right ?

Yes!

ok, now put l(l+1) = (l + 1/2)2 - 1/4,

and use d/dρ = 1/ρ d/dx to rewrite

[itex]-\frac{1}{ρ^{2}}\left[\frac{d}{dρ}(ρ^{2}\frac{dR}{dρ})+l(l+1)R\right][/itex]
 
Hi,tiny-tim!

:smile:

tiny-tim said:
Hi Douasing! :smile:

(just got up :zzz:)


Yes!

ok, now put l(l+1) = (l + 1/2)2 - 1/4,

and use d/dρ = 1/ρ d/dx to rewrite

[itex]-\frac{1}{ρ^{2}}\left[\frac{d}{dρ}(ρ^{2}\frac{dR}{dρ})+l(l+1)R\right][/itex]


[tex]-\frac{1}{ρ^{2}}[\frac{1}{ρ}\frac{d}{dx}(ρ^{2}\frac{1}{ρ}\frac{dR}{dx})+(l+\frac{1}{2})^2R-\frac{1}{4}R][/tex]

:confused:
 
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tiny-tim said:
why make it more difficult? :confused:

wouldn't it have been easier to differentiate the ρ2 wrt ρ first, before changing to d/dx ?


ok, :)

[itex]-\frac{1}{ρ^{2}}\left[\frac{d}{dρ}(ρ^{2}\frac{dR}{dρ})+l(l+1)R\right][/itex]
[itex]= -\frac{1}{ρ^{2}}\left[2ρ\frac{dR}{dρ}+ρ^{2}\frac{d}{dρ}(\frac{dR}{dρ})+l(l+1)R\right][/itex]
[itex]= -\frac{1}{ρ^{2}}\left[2ρ+ρ\frac{d}{dx}(\frac{1}{ρ}\frac{dR}{dx})+(l+\frac{1}{2})^{2}R-\frac{1}{4}R\right][/itex]

and then ?
 
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Thanks for your kind reminding, now I copy them as follows:

(1) [tex]y^{''}=\left[\frac{1}{4}R+R^{'}+R^{''}\right]e^{\frac{x}{2}}[/tex]

(2) [tex]-\frac{1}{ρ^{2}}\left[2\frac{dR}{dx}+ρ\frac{d}{dx}(\frac{1}{ρ}\frac{dR}{dx})+(l+\frac{1}{2})^{2}R+\frac{1}{4}R\right][/tex]
 
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tiny-tim said:
Hi Douasing! :smile:

(just got up :zzz:)


Yes!

ok, now put l(l+1) = (l + 1/2)2 - 1/4,

and use d/dρ = 1/ρ d/dx to rewrite

[itex]-\frac{1}{ρ^{2}}\left[\frac{d}{dρ}(ρ^{2}\frac{dR}{dρ})+l(l+1)R\right][/itex]


Hi,tiny-tim,I finally got it. Thank you very much,especially for your patient with me.
:approve: