Hannay burchagi: Versiyalar orasidagi farq

Klassik mexanikada Hannay burchagi aylanma geometrik fazaning (yoki Berry fazasining) mexanik analogidir. U Buyuk Britaniyaning Bristol universitetidan Jon Hannay sharafiga nomlangan. Xannay birinchi marta 1985 yilda burchakni tasvirlab, yaqinda rasmiylashtirilgan Berry bosqichi gʻoyalarini klassik mexanikaga kengaytirdi.

Klassik mexanikada Hannay burchagi[tahrir | manbasini tahrirlash]

Hannay burchagi harakat-burchak koordinatalari kontekstida aniqlanadi. Dastlab vaqt oʻzgarmaydigan tizimda harakat oʻzgaruvchisi ${\displaystyle I_{\alpha }}$ doimiy hisoblanadi. Vaqti-vaqti bilan bezovtalanishni kiritgandan soʻng ${\displaystyle \lambda (t)}$, harakat oʻzgaruvchisi ${\displaystyle I_{\alpha }}$ adiabatik invariantga aylanadi va Hannay burchagi ${\displaystyle \theta _{\alpha }^{H}}$ uning mos burchak oʻzgaruvchisi uchun buzilish sodir boʻlgan evolyutsiyani ifodalovchi yoʻl integraliga koʻra hisoblanishi mumkin. ${\displaystyle \lambda (t)}$ asl qiymatiga qaytadi^[1]:

$${\displaystyle \theta _{\alpha }^{H}=-{\frac {\partial }{\partial I_{\alpha }}}\oint \!{\boldsymbol {p}}\cdot {\frac {\partial {\boldsymbol {q}}}{\partial \lambda }}\mathrm {d} \lambda }$$

${\displaystyle {\boldsymbol {p}}}$

${\displaystyle {\boldsymbol {q}}}$

Misol[tahrir | manbasini tahrirlash]

Fuko mayatnik klassik mexanikaning namunasidir, u baʼzan Berri fazasini tasvirlash uchun ham ishlatiladi. Quyida biz harakat burchagi oʻzgaruvchilari yordamida Fuko mayatnikini oʻrganamiz. Oddiylik uchun biz umumiy protokolda qoʻllaniladigan Gamilton-Jakobi tenglamasidan foydalanmaymiz.

Biz chastotali tekislik mayatnikini koʻrib chiqamiz ${\displaystyle \omega }$ burchak tezligi boʻlgan Yerning aylanishi taʼsirida ${\displaystyle {\vec {\Omega }}=(\Omega _{x},\Omega _{y},\Omega _{z})}$ sifatida belgilangan amplituda bilan ${\displaystyle \Omega =|{\vec {\Omega }}|}$ . Mana, ${\displaystyle z}$ yoʻnalishi Yerning markazidan mayatnikgacha. Mayatnik uchun Lagrangian:

$${\displaystyle L={\frac {1}{2}}m({\dot {x}}^{2}+{\dot {y}}^{2})-{\frac {1}{2}}m\omega ^{2}(x^{2}+y^{2})+m\Omega _{z}(x{\dot {y}}-y{\dot {x}})}$$

$${\displaystyle {\ddot {x}}+\omega ^{2}x=2\Omega _{z}{\dot {y}}}$$

$${\displaystyle {\ddot {y}}+\omega ^{2}y=-2\Omega _{z}{\dot {x}}}$$

${\displaystyle \varpi =x+iy}$

${\displaystyle \varpi }$

$${\displaystyle {\ddot {\varpi }}+\omega ^{2}\varpi =-2i\Omega _{z}{\dot {\varpi }}}$$

$${\displaystyle \lambda ^{2}+\omega ^{2}=-2i\Omega _{z}\lambda }$$

${\displaystyle \Omega \ll \omega }$

$${\displaystyle \lambda =-i\Omega _{z}\pm i{\sqrt {\Omega _{z}^{2}+\omega ^{2}}}\approx -i\Omega _{z}\pm i\omega }$$

$${\displaystyle \varpi =e^{-i\Omega _{z}t}(Ae^{i\omega t}+Be^{-i\omega t})}$$

${\displaystyle T=2\pi /\Omega \approx 24h}$

${\displaystyle \varpi }$

$${\displaystyle \Delta \varphi =2\pi {\frac {\omega }{\Omega }}+2\pi {\frac {\Omega _{z}}{\Omega }}}$$

$${\displaystyle \theta ^{H}=2\pi {\frac {\Omega _{z}}{\Omega }}}$$

Manbalar[tahrir | manbasini tahrirlash]

• Hannay John H. 1985 Angle variable holonomy in adiabatic excursion of an integrable Hamiltonian J. Phys. A: Math. Gen. 18 221-30.
• Marsden, Jerrold E.; Montgomery, Richard; Ratiu, Tudor S.. Reduction, Symmetry, and Phases in Mechanics. AMS Bookstore, 1990 — 69 bet. ISBN 0-8218-2498-8. 
• C. Pisani. Quantum-mechanical Ab-initio Calculation of the Properties of Crystalline Materials, Proceedings of the IV School of Computational Chemistry of the Italian Chemical Society, Springer, 1994 — 282 bet. ISBN 3-540-61645-4. 
• ; Jean-Marc Triscone; Charles H AhnPhysics of Ferroelectrics: a Modern Perspective. Springer, 2007 — 2 bet. ISBN 978-3-540-34590-9. 

Havolalar[tahrir | manbasini tahrirlash]

• Professor John H. Hannay: Research Highlights. Department of Physics, University of Bristol.