غزّال

A spinor visualized as a vector pointing along the Möbius band, exhibiting a sign inversion when the circle (the "physical system") is continuously rotated through a full turn of 360°.^[أ]

في الرياضيات والفيزياء، غـزّال أو سپينور (Spinor ؛ /spɪnər/) هم عناصر فضاء متجهات من مركـَّبة التي يمكن أن تقترن بالفضاء الاقليدي.^[ب] وبشكل أكثر تحديداً ضمن نظرية المجموعات المتعامدة على كائنات رياضية مشابهة للأشعة أو المتجهات لكنها تغير اشارتها بعد تطبيق دوران بقيمة عليها أي دائرة كاملة.

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مقدمة

A gradual rotation can be visualized as a ribbon in space.^[ت] Two gradual rotations with different classes, one through 360° and one through 720° are illustrated here in the belt trick puzzle. A solution of the puzzle is a continuous manipulation of the belt, fixing the endpoints, that untwists it. This is impossible with the 360° rotation, but possible with the 720° rotation. A solution, shown in the second animation, gives an explicit homotopy in the rotation group between the 720° rotation and the 0° identity rotation.

An object attached to belts or strings can spin continuously without becoming tangled. Notice that after the cube completes a 360° rotation, the spiral is reversed from its initial configuration. The belts return to their original configuration after spinning a full 720°.

A more extreme example demonstrating that this works with any number of strings. In the limit, a piece of solid continuous space can rotate in place like this without tearing or intersecting itself

الملخص في أبعاد قليلة

In 1 dimension (a trivial example), the single spinor representation is formally Majorana, a real 1-dimensional representation that does not transform.
In 2 Euclidean dimensions, the left-handed and the right-handed Weyl spinor are 1-component complex representations, i.e. complex numbers that get multiplied by e^±iφ/2 under a rotation by angle φ.
In 3 Euclidean dimensions, the single spinor representation is 2-dimensional and quaternionic. The existence of spinors in 3 dimensions follows from the isomorphism of the groups SU(2) ≅ Spin(3) that allows us to define the action of Spin(3) on a complex 2-component column (a spinor); the generators of SU(2) can be written as Pauli matrices.
In 4 Euclidean dimensions, the corresponding isomorphism is Spin(4) ≅ SU(2) × SU(2). There are two inequivalent quaternionic 2-component Weyl spinors and each of them transforms under one of the SU(2) factors only.
In 5 Euclidean dimensions, the relevant isomorphism is Spin(5) ≅ USp(4) ≅ Sp(2) that implies that the single spinor representation is 4-dimensional and quaternionic.
In 6 Euclidean dimensions, the isomorphism Spin(6) ≅ SU(4) guarantees that there are two 4-dimensional complex Weyl representations that are complex conjugates of one another.
In 7 Euclidean dimensions, the single spinor representation is 8-dimensional and real; no isomorphisms to a Lie algebra from another series (A or C) exist from this dimension on.
In 8 Euclidean dimensions, there are two Weyl–Majorana real 8-dimensional representations that are related to the 8-dimensional real vector representation by a special property of Spin(8) called triality.
In d + 8 dimensions, the number of distinct irreducible spinor representations and their reality (whether they are real, pseudoreal, or complex) mimics the structure in d dimensions, but their dimensions are 16 times larger; this allows one to understand all remaining cases. See Bott periodicity.
In spacetimes with p spatial and q time-like directions, the dimensions viewed as dimensions over the complex numbers coincide with the case of the (p + q)-dimensional Euclidean space, but the reality projections mimic the structure in |p − q| Euclidean dimensions. For example, in 3 + 1 dimensions there are two non-equivalent Weyl complex (like in 2 dimensions) 2-component (like in 4 dimensions) spinors, which follows from the isomorphism SL(2, $ℂ$ ) ≅ Spin(3,1).

Metric signature	Weyl, complex		Conjugacy	Dirac, complex	Majorana–Weyl, real		Majorana, real
Metric signature	Left-handed	Right-handed	Conjugacy	Dirac, complex	Left-handed	Right-handed	Majorana, real
(2,0)	1	1	Mutual	2	–	–	2
(1,1)	1	1	Self	2	1	1	2
(3,0)	–	–	–	2	–	–	–
(2,1)	–	–	–	2	–	–	2
(4,0)	2	2	Self	4	–	–	–
(3,1)	2	2	Mutual	4	–	–	4
(5,0)	–	–	–	4	–	–	–
(4,1)	–	–	–	4	–	–	–
(6,0)	4	4	Mutual	8	–	–	8
(5,1)	4	4	Self	8	–	–	–
(7,0)	–	–	–	8	–	–	8
(6,1)	–	–	–	8	–	–	–
(8,0)	8	8	Self	16	8	8	16
(7,1)	8	8	Mutual	16	–	–	16
(9,0)	–	–	–	16	–	–	16
(8,1)	–	–	–	16	–	–	16

انظر أيضاً

ملاحظات

^ Spinors in three dimensions are points of a line bundle over a conic in the projective plane. In this picture, which is associated to spinors of a three-dimensional pseudo-Euclidean space of signature (1,2), the conic is an ordinary real conic (here the circle), the line bundle is the Möbius bundle, and the spin group is SL₂( $ℝ$ ). In Euclidean signature, the projective plane, conic and line bundle are over the complex instead, and this picture is just a real slice.
^ Spinors can always be defined over the complex numbers. However, in some signatures there exist real spinors. Details can be found in spin representation.
^ The TNB frame of the ribbon defines a rotation continuously for each value of the arc length parameter.

الهامش

الكلمات الدالة:

نظرية المجموعات

[1] Spinors in three dimensions are points of a line bundle over a conic in the projective plane. In this picture, which is associated to spinors of a three-dimensional pseudo-Euclidean space of signature (1,2), the conic is an ordinary real conic (here the circle), the line bundle is the Möbius bundle, and the spin group is SL₂( $ℝ$ ). In Euclidean signature, the projective plane, conic and line bundle are over the complex instead, and this picture is just a real slice.

[2] Spinors can always be defined over the complex numbers. However, in some signatures there exist real spinors. Details can be found in spin representation.

[3] The TNB frame of the ribbon defines a rotation continuously for each value of the arc length parameter.

[أ]

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