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    能帶理論
    2017/12/13 21:52:51
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    Chap. 7 Energy Gap

    Two different standing waves, k=±π/a

    ψ(+)=2cos(πx/a), ψ(-)=2isin(πx/a) in 1-D

    Charge probability density, ρ(+)=|ψ(+)|² cos²(πx/a) at x=0, a, 2a, 3a能量最低

    ρ(-)=|ψ(-)|² sin²(πx/a) at x= a/2, 3a/2, 5a/2…能量較高

    Normalized standing wave:

    |ψ(+)|²dx=1 → A²acos²(πx/a)dx=1 → A²a/π∫πcos²ydy=1 → A²a/π(y/2+sin2y/4)|₀π=1

    A²a/2=1, A=(2/a)1/2 ψ(+)=(2/a)1/2cos(πx/a)

    同理, ψ(-)=(2/a)1/2sin(πx/a)

    potential energy, U(x)=Ucos(2πx/a)U(+)=∫ψ*(+)Uψ(+)dx, U(-)=∫ψ*(-)Uψ(-)dx

    Eg=U(-) - U(+)=U

    Bloch theorem

    Hψ=Eψ, (ℏ²k²/2m+U)ψ=Eψ

    ⸪晶格為週期性排列ψ亦為週期性函數

    the solution of Schrödinger equation for a periodic potential,

    ψk(r)=eikruk(r) where uk(r)=uk(r+T) T: translation vector

    ψk(r)=ψk(r+T) 表示相位相同即起始條件一樣

    Free electron model: ψk(r)=eikr, 平面波,自由電子沒有位能存在

    Nearly free electron model: ψk(r)=eikruk(r) Bloch function(描述理想晶體時)

    Kronig-Penny model(1-D)

    (-ℏ²/2m)d²ψ∕dx²+Uψ=Eψ, H=(-ℏ²/2m)d²/dx²+U

    in the region 0<x<a, U=0

    ψ∕dx²+2mEψ/ℏ²=0, K²= 2mE/ℏ²

    ψ₁(x)=AeiKx+Be-iKx

    in the region a<x<a+b, U=U0

    ψ∕dx²-2m(U0-E)ψ/ℏ²=0, let Q²= 2m(U0-E)/ℏ²

    ψ₂(x)=CeQx+De-Qx

    Boundary conditions: ψ₁(a)=ψ₂(a) and dψ₁/dx|x=a=dψ₂/dx|x=a when x=a

    AeiKa+Be-iKa=CeQa+De-Qa, iKAeiKa-iKBe-iKa =QCeQa-QDe-Qa C, D

    C=e-Qa/2Q[Q(AeiKa+Be-iKa)+(iKAeiKa-iKBe-iKa )], D=eQa/2Q[Q(AeiKa+Be-iKa)-(iKAeiKa-iKBe-iKa )]

    ψ₁(x)=AeiKx+Be-iKx,

    ψ₂(x)=eQ(x-a)/2Q[Q(AeiKa+Be-iKa)+(iKAeiKa-iKBe-iKa )]+e-Q(x-a)/2Q[Q(AeiKa+Be-iKa)-(iKAeiKa-iKBe-iKa )]代入 bloch function

    ψ(x+a+b)=u(x+a+b)eik(x+a+b)=u(x)eikxeik(a+b)=ψ(x)eik(a+b), x=0

    ψ(a+b)=ψ(0)eik(a+b), and dψ₂(a+b)/dx=[dψ₁(0)/dx]eik(a+b) ψ, ψ代入解A, B

    [(Q²-K²)/2QK](sinhQb)sinKa+(coshQb)cosKa=cosk(a+b)…(a),

    Q²= 2m(U0-E)/ℏ², K²= 2mE/ℏ², k=2π/λ

    in the limiting case: b0, U0 and define P=Q²ba/2 a finite quantity.

    sinhQb=(eQb-e-Qb)/2≈1/2[(1+Qb+Q²b²/2+...)-(1-Qb+Q²b²/2-...)]=Qb,

    coshQb=(eQb+e-Qb)/2≈1

    (a)簡化為(Q/2K)QbsinKa+cosKa=coska (P/Ka)sinKa+cosKa=coska

    • P0 coska=1 at the X points, ka=nπ, n=1, 2, 3,… k=nπ/a時發生不連續

      ka=π, k=π/a E=ℏ²k²/2m=ℏ²|π/a|²/2m=Eπ , ℏ²|(π+)/a|²/2m=Eπ

      Wave equation of electron in a periodic potential for a general crystal potential

      U(r)=U(r+T) 3-D vs. U(x)=U(x+na) 1-D

      U(x) can be expanded as a Fourier series in the reciprocal lattice.

      U(x)=GUGeiGx=G>0UG(eiGx+e-iGx)=2G>0UGcosGx代入Schrodinger equation

      [P²/2m+U(x)]ψ(x)=Eψ(x), P=-ih(d/dx) [(-ℏ²/2m)d²/dx²+U]ψ(x)=Eψ(x)…(b)

      ψ(x)=∑kC(k)eikx, k=2nπ/L and U(x)=GUGeiGx代入(b)

      [(-ℏ²/2m)d²kC(k)eikx/dx²+GUGeiGxkC(k)eikx=EkC(k)eikx

      (ℏ²k²/2m)kC(k)eikx+∑GUGeiGxkC(k)eikx=EkC(k)eikx

      (ℏ²k²/2m)kC(k)eikx+∑GkUGC(k)ei(G+k)x=EkC(k)eikx

      上式等號左邊第二項GkUGC(k)ei(G+k)x, k 換成 k+G

      GkUGC(k)ei(G+k)x=∑GkUGC(k-G)eikx=GkUGC(k-G)eikx

      By equating the coefficient of eikx on both sides.

      k[(ℏ²k²/2m)C(k)+∑GUGC(k-G)]eikx=kEC(k)eikx (ℏ²k²/2m)C(k)+∑GUGC(k-G)=EC(k)

      (λₖ-E)C(k)+∑GUGC(k-G)=0…central equation, λₖ= ℏ²k²/2m

      *只要C(k)存在,必有一C(k-G)存在

      ψ(x)=∑GC(k-G)ei(k-G)x=∑GC(k-G)e-iGxeikx= uk(x)eikx, GC(k-G)e-iGx=uk(x)

      if uk(x+T)=uk(x)滿足bloch equation的要求

      uk(x+T)=∑GC(k-G)e-iG(x+T)=∑GC(k-G)e-iGxe-iGT, G=2mπ/a, T=na GT=2mnπ

      U(x)=GUGeiGx, G=2nπ/a

      另類導出Kronig-Penney model solution:

      U(x)=∑GU(G)eiGx=A∙a∙∑ₛδ(x-sa)

      i.e. delta function δ(x-sa)dx=1 δ(x-a)f(x)dx=f(a)

      U(G)=1/adxU(x)e-iGx=1/adxA∙a∙∑ₛδ(x-sa)e-iGx=A∑ₛδ(x-sa)e-iGxdx=A∑ₛe-iGsa=A∑ₛe-i2πns

      G=±2πn/a reciprocal vector, 某一個UG對應一個s, UG= A 代入central eq.

      (λk -E)C(k)+∑ₙ AC(k-2πn/a)=0 define: f(k)=∑ₙ C(k-2πn/a), and f(k)=f(k-2πn/a)

      C(k)=-Af(k)/(λk -E)=-[(2mA/ℏ²)f(k)]/[k²-(2mE/ℏ²)] 代入 λk = ℏ²k²/2m

      上式用k-2πn/a代換k

      C(k-2πn/a)=-[(2mA/ℏ²)f(k-2πn/a)]/[(k-2πn/a)²-(2mE/ℏ²)]=-[(2mA/ℏ²)f(k)]/[(k-2πn/a)²-(2mE/ℏ²)]

      ∑ₙC(k-2πn/a)=-(2mA/ℏ²)f(k)∑ₙ1/[(k-2πn/a)²-(2mE/ℏ²)]

      - ℏ²/2mA=∑ₙ[(k-2πn/a)²-(2mE/ℏ²)]⁻¹ i.e. α²=2mE/ℏ²

      - ℏ²/2mA=∑ₙ[(k-2πn/a)²-α²]⁻¹=∑ₙ[(k-2πn/a-α)(k-2πn/a+α)]⁻¹=∑ₙ(1/2α)[(k-2πn/a-α)⁻¹-(k-2πn/a +α)⁻¹]=∑ₙ(1/2α)[a/(ka-2πn-αa)-a/(ka-2πn+αa)]

      - ℏ²/2mA=(a/4α)∑ₙ[1/(ka/2-αa/2-πn)-1/(ka/2+αa/2-πn)] i.e. cotx=∑ₙ1/(nπ±x)

      ∑ₙ[1/(ka/2-αa/2-πn)-1/(ka/2+αa/2-πn)]=cot(ka/2-αa/2)-cot(ka/2+αa/2)

      =cos(ka/2-αa/2)/sin(ka/2-αa/2)-cos(ka/2+αa/2)/sin(ka/2+αa/2)

      =2cos(αa/2)sin(αa/2)/[sin²(ka/2)cos²(αa/2)-cos²(ka/2)sin²(αa/2)]

      =

      - ℏ²/2mA=(a/4α)[2sinαa/(cosαa -coska)]=(a/2α)[sinαa/(cosαa -coska)]

      - ℏ²α/maA=sinαa/(cosαa -coska)

      coska=cosαa+(maA/ℏ²α)sinαa=cosαa+(P/αa)sinαa

      coska=cosαa+(P/αa)sinαa P=ma²A/ℏ²

      Ex: U(x)=U2π/aei2πx/a+U-2π/ae-i2πx/a=2Ucos(2πx/a)=2Ucos(gx), U2π/a=U-2π/a=Ug=U-g=U

      (λₖ-E)C(k)+∑GUGC(k-G)=0(λₖ-E)C(k)+UgC(k-g)+U-gC(k+g)=0

      Approximation solution near a zone edge

      1. At the zone edge

      (λₖ-E)C(k)+∑GUGC(k-G)=0, k=g/2=π/a and λk =ℏ²k²/2m

      ψ(x)=∑GC(k-G)ei(k-G)xC(k)eikx+C(k-g)ei(k-g)x=C(g/2)eigx/2+C(-g/2)e-igx/2

      U(x)=GU(G)eiGx=U2π/aei2πx/a+U-2π/ae-i2πx/a=2Ucos(2πx/a), when G=2π/a

      as k=g/2, UG1/G² C(k-g) and C(k+g)二項近似, 其餘忽略

      (λₖ-E)C(k)+UgC(k-g)+U-gC(k+g)=0 → (λg/2 -E)C(g/2)+UgC(k-g)+U-gC(k+g)=0

      (λg/2 -E)C(g/2)+UgC(-g/2)+U-gC(3g/2)=0 → (λg/2 -E)C(g/2)+UgC(-g/2)=0...(1)

      as k=-g/2

      (λₖ-E)C(k)+UgC(k-g)+U-gC(k+g)=0 → (λ-g/2 -E)C(-g/2)+UgC(-3g/2)+U-gC(g/2)=0

      (λ-g/2 -E)C(-g/2)+U-gC(g/2)=0

      for non-trivial solution of C(k) → =0

      E²-(λg/2+λ-g/2)E+λg/2λ-g/2-UgU-g=0

      λk =ℏ²k²/2m λg/2= ℏ²(g/2)²/2m= ℏ²(-g/2)²/2m=λ-g/2 and Ug=U-g=U

      (λg/2-E)²-Ug²=0 E=λg/2±Ug=ℏ²(g/2)²/2m±Ug, for E(+)= λg/2+Ug=ℏ²(g/2)²/2m+Ug

      代入(1), [λg/2 -E(+)]C(g/2)+UgC(-g/2)=0 → C(g/2)/C(-g/2)=-Ug/[λg/2 -E(+)]=+1

      ψ(x)= C(g/2)eigx/2+C(-g/2)e-igx/2=C(g/2)(eigx/2+e-igx/2)=2C(g/2)cos(gx/2)=2C(g/2)cos(πx/a)

      x=0, a, 2a,…|ψ₍₊₎|² |cos(πx/a)|² 電子在晶格點上的機率最大,總能量也較低

      for E(-)= λg/2-Ug=ℏ²(g/2)²/2m-Ug [λg/2 -E(-)]C(g/2)+UgC(-g/2)=0 → C(g/2)/C(-g/2)=-Ug/[λg/2 -E(-)]=-1

      ψ(x)= C(g/2)eigx/2+C(-g/2)e-igx/2=C(g/2)(eigx/2-e-igx/2)=2C(g/2)sin(gx/2)=2C(g/2)sin(πx/a)

      x=a/2, 3a/2,…|ψ₍₋₎|² = |2C(g/2)sin(πx/a)|²

      1. If the wavevector k is very near the zone edge(kg/2, but kg/2)

      取前二項近似, C(k) and C(k-g)

      ψ(x)=∑GC(k-G)ei(k-G)xC(k)eikx+C(k-g)ei(k-g)x代入bloch equation

      (λₖ-E)C(k)+∑GUGC(k-G)=0 (λₖ-E)C(k)+UgC(k-g)+U-gC(k+g)=0 and (λₖ₋g-E)C(k-g)+UgC(k-2g)+U-gC(k)=0 →取前二項近似, C(k) and C(k-g)

      (λₖ-E)C(k)+UgC(k-g)=0...(3), (λₖ₋g-E)C(k-g)+U-gC(k)=0...(4)

      for non-trivial solution of C(k) → =0

      E²-(λk+λk-g)E+λkλk-g-Ug²=0(⸪Ug=U-g=U₀), E=½{(λk+λk-g)±[(λk+λk-g)²-4(λkλk-g-Ug²)]1/2}

      E=½{(λk+λk-g)±[(λk-λk-g)²+4Ug²)]1/2}, ⸪ λk=ℏ²k²/2m, λk-g=ℏ²(k-g)²/2m, λ=ℏ²(g/2)²/2m

      and let K=k-g/2 可以將解整理成EK=(ℏ²/2m)(g²/4+K²)±Ug[1+4(λ/Ug²)(ℏ²K²/2m)]1/2 i.e. λk+λk-g=2λ+ ℏ²K²/2m, λk-λk-g= ℏ²2Kg/2m

      when kg/2=π/a, 4(λ/Ug²)(ℏ²K²/2m)=(ℏ²Kg/2mUg)²<<1 span="">

      EK(±)(ℏ²/2m)(g²/4+K²)±Ug[1+½∙4(λ/Ug²)(ℏ²K²/2m)]=(λ±Ug)+(ℏ²K²/2m)(1±2λ/Ug)

          1. upper band, Ug<0, font="" face="Times New Roman, serif">EK(-)=(λ-Ug)+(ℏ²K²/2m)(1-2λ/Ug)

          2. lower band EK(+)=(λ+Ug)+(ℏ²K²/2m)(1+2λ/Ug)

      numbers of states in a band:

      consider a linear crystal constructed of N primitive cells of lattice constant a

      根據週期性條件U(sa)=U(sa+L), k=0, ±2π/L, ±4π/L,...Nπ/L, L=Na

      [π/a-(-π/a)]/(2π/L)=Na/a=N, 在第一不連續中有Nstates, 考慮spin每個state有兩個不同的spin(down and up), there are 2N independent states in each energy band2N electrons

      1. for alkali metals which have one valence electron per primitive cell. N cells N valence electrons the energy band is half-filled metal

      2. for Alkali earth metal: each primitive cell have two valence electrons N cells 2N valence electrons band is filled up insulators.

      If the bonds are partly overlapped semiconductors

      For diamond, silicon and Ge: each primitive cell has 2 atoms, each atom has 4 valence electrons. N cells have 8N valence electrons

      可填滿4band,且無overlap現象, energy gap~kTsemiconductor

      Appendix:

      E=½{(λk+λk-g)±[(λk-λk-g)²+4Ug²)]1/2}

      EK=(ℏ²/2m)(g²/4+K²)±Ug[1+4(λ/Ug²)(ℏ²K²/2m)]1/2,

      λk=ℏ²k²/2m, λk-g=ℏ²(k-g)²/2m, λ=ℏ²(g/2)²/2m and let K=k-g/2

    Quantum mechanics of electrons in crystal lattices R. De L. Kronig and William George Penney published: Proc. Roy. Soc. 03 Feb. 1931 vol. 130 Issue 814 

    Solutions of Kronig-Penney Models by the T-Matrix Method William J. Titus American Journal of Physics 41, 512 (1973)

    Kronig-Penney model: electron in a periodic field of a crystal

    I: d²ψ/dx²+(2mE/ℏ²)ψ(x)=0 α²=2mE/ℏ²

    II: ψ/dx²+(2m/²)(E-V)ψ(x)=0 γ²=(2m/²)(V₀-E)

    Bloch wave: ψ(x)=u(x)eikx u(x): periodic function, different for various directions in crystal.

    代入I, II方程式

    ψ/dx²= d²(u(x)eikx)/dx²=d/dx[(du/dx)eikx+iku(x)eikx]

    =(d²u/dx²)eikx+ik(du/dx)eikx+ik[(du/dx)eikx+iku(x)eikx ]=[(d²u/dx²)+2ik(du/dx)-k²u(x)]eikx

    I (d²u/dx²)+2ik(du/dx)-k²u(x)+α²u(x)=0 u+2ikDu+(α²—k²)u=0 D=-ik±iα

    u(x)=(Aeiαx+Beiαx)eikx

    II (d²u/dx²)+2ik(du/dx)-k²u(x)-γ²u(x)=0 D=-ik±γ

    u(x)=(Ceγx+Deγx)eikx

    Schrödinger eq. -ℏ²/2m(d²ψ/dx²)+U(x)ψ(x)=Eψ(x)

    potential in periodic crystal U(x+a)=U(x) a: lattice constant

    expanding wave function and potential function by Fourier series

    ψ(x)=C(k)eikx, U(x)=GU(G)eiGx

    where G =2πn/a is the reciprocal lattice vector and

    U(G)=UG =1/adxU(x)e-iGx (7.69)

    Because U(x) is real, it is easy to show that UG* = U-G.

    UG* =[1/adxU(x)e-iGx]*=1/adxU(x)eiGx= 1/adxU(x)e-i(-G)x= U-G (7.70)

    We can use these plan waves as our basis, and therefore we can write any wavefunction in the following form

    ψ(x)=∑ₖC(k)eikx (7.71), C(k)=1/adxψ(x)e-ikx (7.72)

    Consider a system with size L and periodic boundary conditions, ψ(x + L) = ψ(x). With such a boundary condition, we know that the wavevector for plan waves can only take discrete values

    k =2πn/L (7.73) with n = … - 3, -2, -1, 0, 1, 2, 3…

    代入Schrödinger eq.

    -ℏ²/2m(d²∑C(k)eikx/dx²)+∑G U(G)eiGx C(k)eikx=E∑C(k)eikx

    -ℏ²/2m∙(ik)²∑C(k)eikx+∑G U(G)eiGx C(k)eikx-E∑C(k)eikx=0

    (ℏ²k²/2m-E)∑C(k)eikx+∑G U(G) C(k)ei(k+G)x=0

    The second term on the l.h.s. has two sums G . Define k = G + k and change the sum over k into the sum of k . As a result, this term becomes

    G U(G) C(k)ei(k+G)x= G U(G) C(k-G)eikx =G U(G) C(k-G)eikx (7.77)

    So

    [(ℏ²k²/2m-E)C(k)+G U(G) C(k-G)]eikx=0 (7.78)

    For plane waves, if I have a equation

    a(k)eikx=0 (7.80)

    the only solution to this equation is a(k)=0 for every k. This is because plane waves with different wave-vectors are linear independent <k|k >=0 .Therefore, if the sum over planes with different k is zero, every term in the sum must be zero. For the Schrodinger equation we

    considered above, this means that

    (ℏ²k²/2m-E)C(k)+G U(G) C(k-G)=0 (7.81)

    In our text book, it is defined λk = ℏ²k²/2m, so we get

    (λk -E)C(k)+G U(G) C(k-G)=0 (7.82)

    This equation is known as the central equation. It is just the Schrodinger equation rewritten in the plane wave basis.

    The central equation implies that C(k) is coupled with C(k+G), which includes C(k±π/a), C(k ±2 π/a), C(k ±3π/a), …

    In the same time, it is easy to notice that if k - k G, C(k) and C(k ) decouple from each other. C(k ) never appears in any equation of C(k) and vice versa. In other words, the value of C(k) doesn’t care about the value of C(k ).

    U(x)=∑GU(G)eiGx=A∙a∙∑ₛδ(x-sa) i.e. delta function δ(x-sa)dx=1 δ(x-a)f(x)dx=f(a)

    U(G)==1/adxU(x)e-iGx=1/adxA∙a∙∑ₛδ(x-sa)e-iGx=A∑ₛδ(x-sa)e-iGx dx=A∑ₛ e-iGsa=A∑ₛ e-i2πns

    G=±2πn/a reciprocal vector, 某一個UG對應一個s, UG= A 代入central eq.

    (λk -E)C(k)+∑ₙ AC(k-2πn/a)=0 define: f(k)=∑ₙ C(k-2πn/a), and f(k)=f(k-2πn/a)

    C(k)=-Af(k)/(λk -E)=-[(2mA/ℏ²)f(k)]/[k²-(2mE/ℏ²)] 代入 λk = ℏ²k²/2m

    上式用k-2πn/a代換k

    C(k-2πn/a)=-[(2mA/ℏ²)f(k-2πn/a)]/[(k-2πn/a)²-(2mE/ℏ²)]=-[(2mA/ℏ²)f(k)]/[(k-2πn/a)²-(2mE/ℏ²)]

    ∑ₙC(k-2πn/a)=-(2mA/ℏ²)f(k)∑ₙ1/[(k-2πn/a)²-(2mE/ℏ²)]

    - ℏ²/2mA=∑ₙ[(k-2πn/a)²-(2mE/ℏ²)]⁻¹ i.e. α²=2mE/ℏ²

    - ℏ²/2mA=∑ₙ[(k-2πn/a)²-α²]⁻¹=∑ₙ[(k-2πn/a-α)(k-2πn/a+α)]⁻¹=∑ₙ(1/2α)[(k-2πn/a-α)⁻¹-(k-2πn/a +α)⁻¹]=∑ₙ(1/2α)[a/(ka-2πn-αa)-a/(ka-2πn+αa)]

    - ℏ²/2mA=(a/4α)∑ₙ[1/(ka/2-αa/2-πn)-1/(ka/2+αa/2-πn)] i.e. cotx=∑ₙ1/(nπ±x)

    ∑ₙ[1/(ka/2-αa/2-πn)-1/(ka/2+αa/2-πn)]=cot(ka/2-αa/2)-cot(ka/2+αa/2)

    - ℏ²/2mA=(a/4α)[2sinαa/(cosαa -coska)]=(a/2α)[sinαa/(cosαa -coska)]

    - ℏ²α/maA=sinαa/(cosαa -coska) coska=cosαa+(maA/ℏ²α)sinαa=cosαa+(P/αa)sinαa

    coska=cosαa+(P/αa)sinαa P=ma²A/ℏ²

    De Broglie’s postulate:

    The motion of a particle is governed by the propagation of its associated pilot waves.

    Relationship between them,

    pilot wave的特性:

    ω=νλ=(E/h)(h/P)=E/P在某一瞬間, t=t0 可以偵測pilot wave的波形,有關粒子在空間的運動

    pilot wave = a group of waves, and group velocity, g=粒子運動的速度

    pilot wave function, ψ(x,t)=sin2π(x/λ-νt)=sin2π(kx-νt), k=1/λ

    if ψ=0, 2π(kx-νt)=nπ n=0, 1, 2,… x=n/k+νt/k 波速, ω=dxₙ/dt=ν/k=νλ

    代表粒子運動是一群pilot wave相加重疊洏成,變成一群pilot waves.

    考慮兩個pilot wave相加的情況: ψ(x,t)=ψ(x,t)+ψ(x,t)

    ψ(x,t)=sin2π(kx-νt), ψ(x,t)=sin2π[(k+dk)x-(ν+dν)t], i.e. sinA+sinB=2cos½(A-B)sin½(A+B)

    ψ(x,t)=2cos2π(dkx/2-dνt/2)sin2π[(2k+dk)x/2-(2ν+dν)t/2]

    2cos2π(dkx/2-dνt/2)sin2π(kx-νt) if dk<<k, dv<<v

    個別pilot wave波速可以第二項求得ω=ν/k=νλ

    group wave 的速度, g由第一項求得g=dv/dk=dE/dP

    由相對論公式E=mc², P=mv and E²=m²c+P²c²+m²c又可證明group wave 的速度等於粒子運動的速度, g=v

    g=dv/dk=dE/dP=c²P/E=c²mv/mc²=v ( 2EdE=c²2PdP, dE/dP=c²P/E)

    又可知ω>g dE/dP=c²P/E g=c²/ω≤c

    Schrödinger Theorem:

    總能, Etotal以古典能量為定義: E=P²/2m+V若成立, 粒子速度是否等於波群速度?

    ν=E/h=P²/2mh+V/h , k=1/λ=P/h dv=2PdP/2mh, dk=dP/h g=dv/dk=[2PdP/2mh]/(dP/h)=P/m=v

    所以Schrödinger theorem:

    1. 可以滿足h/P=λ, E/h=v and E=P²/2m+V

    2. 波函數是線性組合的方程式解

    3. 位能V=V(x,t), 但特殊情況下V=V0=constant, F=∂V0∕∂x=0, dP/dt=F=0 P=const. E=P²/2m+V=定值 λ, v 也都是定值

    Def: K=2πk, ω=2πν P=K, E=ℏω

    代入E=P²/2m+V重整可得ω=ℏ²K²/2m+V(x,t)

    因為微分方程式解為ψ(x,t)須滿足上述條件,我們可以試以ψ(x,t)=sin(Kx-ωt)是否符合ω=ℏ²K²/2m+V0的形式

    ψ∕∂x=Kcos(Kx-ωt), ∂²ψ∕∂x²=-K²sin(Kx-ωt), ψ∕∂t=-ωcos(Kx-ωt)

    套入微分方程式α(∂²ψ∕∂x²)+V0ψ=β(ψ∕∂t)看是否符合ω=ℏ²K²/2m+V0的形式

    -αK²sin(Kx-ωt)+V0sin(Kx-ωt)=-β ωcos(Kx-ωt)可知ψ(x,t)=sin(Kx-ωt)不合

    ψ(x,t)=cos(Kx-ωt)也不合, 因此試以ψ(x,t)=cos(Kx-ωt)+γsin(Kx-ωt)

    ²ψ∕∂x²=-K²cos(Kx-ωt)-γK²sin(Kx-ωt), ψ∕∂t=ωsin(Kx-ωt)-ωγcos(Kx-ωt)

    代入微分方程式α(∂²ψ∕∂x²)+V0ψ=β(ψ∕∂t)

    α[-K²cos(Kx-ωt)-γK²sin(Kx-ωt)]+V0[cos(Kx-ωt)+γsin(Kx-ωt)]=β[ωsin(Kx-ωt)-ωγcos(Kx-ωt)]

    (-αK²+V0+βωγ)cos(Kx-ωt)+(-αγK²+γV0-βω)sin(Kx-ωt)=0

    -αK²+V0+βωγ=0...(a), -αγK²+γV0-βω=0 -αK²+V0-βω/γ=0...(b)

    (a)-(b) βωγ+βω/γ=0, γ²+1=0 γ=±i 代入(a) -αK²+V0=-+iβω

    ω=ℏ²K²/2m+V0比較α=- ℏ²/2m, -+iβ=

    因此微分方程式呈現

    (-ℏ²/2m)∂²ψ∕∂x²+V0ψ=iℏ(∂ψ∕∂t), 其解為ψ(x,t)=cos(Kx-ωt)+isin(Kx-ωt)

    波動函數只有在Schrödinger theorem才存在,因其複數的特徵無法在物理世界去測量

    但波動函數和粒子存在的關連,是以波的振幅強度來描述粒子存在的機率密度

    born假設 at t=t0

    P(x,t)dx=ψψ*dx , ψ=R+iI and ψ*=R-iI ψψ*= R²+I²

    If ψ(-ℏ²/2m)∂²ψ∕∂x²+V0ψ=iℏ(∂ψ∕∂t)之解

    ψ*就可以成為(-ℏ²/2m)∂²ψ∕∂x²+V0ψ=iℏ(∂ψ∕∂t)…(a)的共軛方程式解

    [(-ℏ²/2m)∂²ψ∕∂x²+V0ψ=iℏ(∂ψ∕∂t)]* → [(-ℏ²/2m)∂²ψ∕∂x²]*+(V0ψ)*=[iℏ(∂ψ∕∂t)]*

    (-ℏ²/2m)∂²ψ*∕∂x²+V0ψ*=iℏ(∂ψ*∕∂t)…(b)

    (a)xψ*-(b)xψ (-ℏ²/2m)[ψ*∂²ψ∕∂x²-ψ∂²ψ*∕∂x²]=i[ψ*ψ∕∂t-ψψ*∕∂t]

    化簡(-ℏ²/2m)[ψ*∂²ψ∕∂x²-ψ∂²ψ*∕∂x²]=i[ψψ*∕∂t]兩邊積分

    (-ℏ²/2m)∂∕∂x(ψ*ψ∕∂x-ψψ*∕∂x)dx=[iℏ(∂ψψ*∕∂t)]dx

    (i/2m)(ψ*ψ∕∂x-ψψ*∕∂x)|xx=∂∕∂txx ψψ* dx

    ex.ψ(x,t)=exp[i(Kx-ωt)]為例

    ψ*(x,t)=e-i(Kx-ωt) ψ∕∂x=iKψ, ψ*∕∂x=-iKψ*

    ⸫(i/2m)(ψ*ψ∕∂x-ψψ*∕∂x)|xx=∂∕∂txx ψψ*dx (i/2m)(2iKψ*ψ)|xx=∂∕∂txx ψ*ψdx K/m(ψ*ψ)=∂∕∂txx ψ*ψdx=v-v ψ*ψ=1, K/m=P/m=v

    V=V0的例子來說, v也為常數, and ψ*ψ=1t微分,兩邊0=0

    因為-∞ ψ*ψd=1,對任何t都成立,所以(i/2m)(ψ*ψ∕∂x-ψψ*∕∂x)|xx永遠為實數的機率通量

    不含時Schrödinger equation(偏微分常微分)

    if V=V(x) ψ(x,t)=φ(x)ϕ(t)代入微分方程式

    (-ℏ²/2m)∂²φ(x)ϕ(t)∕∂x²+V0φ(x)ϕ(t)=iℏ[∂φ(x)ϕ(t)∕∂t]

    (-ℏ²/2m)ϕ(t)∂²φ(x)∕∂x²+V0φ(x)ϕ(t)=iℏ[φ(x)∂ϕ(t)∕∂t]

    除以φ(x)ϕ(t)

    1/φ(x)[(-ℏ²/2m)∂²φ(x)∕∂x²+V0]=iℏ/φ(x)[∂ϕ(t)∕∂t] 兩邊變數不同需有共同常數解C才成立

    iℏ/φ(x)[∂ϕ(t)∕∂t]=C dϕ(t)∕ϕ(t)=(C/iℏ)dt=-iCt/ℏ → lnϕ(t)=-iCt/ℏ, ϕ(t)=e-iCt/ℏ

    C/ℏ=ω, C=ℏω=Eϕ(t)=e-iEt/ℏ 波函數變成ψ(x,t)=φ(x)exp(-iEt/ℏ)

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