Symmetry Motif the fundamental part of a symmetric
- Slides: 93
Symmetry Motif: the fundamental part of a symmetric design that, when repeated, creates the whole pattern Operation: some act that reproduces the motif to create the pattern Element: an operation located at a particular point in space
2 -D Symmetry = 360 o/2 rotation to reproduce a motif in a symmetrical pattern A Symmetrical Pattern 6 6 Symmetry Elements 1. Rotation a. Two-fold rotation
2 -D Symmetry Elements Operation 1. Rotation a. Two-fold rotation = the symbol for a two-fold rotation 6 Element 6 = 360 o/2 rotation to reproduce a motif in a symmetrical pattern Motif
2 -D Symmetry Elements 1. Rotation a. Two-fold rotation = the symbol for a two-fold rotation 6 second operation step 6 = 360 o/2 rotation to reproduce a motif in a symmetrical pattern first operation step
2 -D Symmetry Elements 1. Rotation a. Two-fold rotation Some familiar objects have an intrinsic symmetry
2 -D Symmetry Elements 1. Rotation a. Two-fold rotation Some familiar objects have an intrinsic symmetry
2 -D Symmetry Elements 1. Rotation a. Two-fold rotation Some familiar objects have an intrinsic symmetry
2 -D Symmetry Elements 1. Rotation a. Two-fold rotation Some familiar objects have an intrinsic symmetry
2 -D Symmetry Elements 1. Rotation a. Two-fold rotation Some familiar objects have an intrinsic symmetry
2 -D Symmetry Elements 1. Rotation a. Two-fold rotation Some familiar objects have an intrinsic symmetry
2 -D Symmetry Elements 1. Rotation a. Two-fold rotation Some familiar objects have an intrinsic symmetry 180 o rotation makes it coincident Second 180 o brings the object back to its original position What’s the motif here? ?
2 -D Symmetry Elements 1. Rotation b. Three-fold rotation 6 6 6 = 360 o/3 rotation to reproduce a motif in a symmetrical pattern
2 -D Symmetry Elements 1. Rotation b. Three-fold rotation 6 6 step 3 6 = 360 o/3 rotation to reproduce a motif in a symmetrical pattern step 1 step 2
2 -D Symmetry Elements 1. Rotation 6 6 6 a identity Z t 9 6 6 Objects with symmetry: 4 -fold 6 3 -fold 6 2 -fold 6 6 6 1 -fold 6 6 -fold d 5 -fold and > 6 -fold rotations will not work in combination with translations in crystals (as we shall see later). Thus we will exclude them now.
4 -fold, 2 -fold, and 3 -fold rotations in a cube Click on image to run animation
2 -D Symmetry Elements 2. Inversion (i) inversion is identical to 2 -fold rotation in 2 -D, but is unique in 3 -D (try it with your hands) 6 6 inversion through a center to reproduce a motif in a symmetrical pattern = symbol for an inversion center
2 -D Symmetry Elements 3. Reflection (m) Reflection across a “mirror plane” reproduces a motif = symbol for a mirror plane
2 -D Symmetry We now have 6 unique 2 -D symmetry operations: 1 2 3 4 6 m Rotations are congruent operations reproductions are identical Inversion and reflection are enantiomorphic operations reproductions are “opposite-handed”
2 -D Symmetry Combinations of symmetry elements are also possible To create a complete analysis of symmetry about a point in space, we must try all possible combinations of these symmetry elements In the interest of clarity and ease of illustration, we continue to consider only 2 -D examples
2 -D Symmetry Try combining a 2 -fold rotation axis with a mirror
2 -D Symmetry Try combining a 2 -fold rotation axis with a mirror Step 1: reflect (could do either step first)
2 -D Symmetry Try combining a 2 -fold rotation axis with a mirror Step 1: reflect Step 2: rotate (everything)
2 -D Symmetry Try combining a 2 -fold rotation axis with a mirror Step 1: reflect Step 2: rotate (everything) Is that all? ?
2 -D Symmetry Try combining a 2 -fold rotation axis with a mirror Step 1: reflect Step 2: rotate (everything) No! A second mirror is required
2 -D Symmetry Try combining a 2 -fold rotation axis with a mirror The result is Point Group 2 mm “ 2 mm” indicates 2 mirrors The mirrors are different (not equivalent by symmetry)
2 -D Symmetry Now try combining a 4 -fold rotation axis with a mirror
2 -D Symmetry Now try combining a 4 -fold rotation axis with a mirror Step 1: reflect
2 -D Symmetry Now try combining a 4 -fold rotation axis with a mirror Step 1: reflect Step 2: rotate 1
2 -D Symmetry Now try combining a 4 -fold rotation axis with a mirror Step 1: reflect Step 2: rotate 2
2 -D Symmetry Now try combining a 4 -fold rotation axis with a mirror Step 1: reflect Step 2: rotate 3
2 -D Symmetry Now try combining a 4 -fold rotation axis with a mirror Any other elements?
2 -D Symmetry Now try combining a 4 -fold rotation axis with a mirror Any other elements? Yes, two more mirrors
2 -D Symmetry Now try combining a 4 -fold rotation axis with a mirror Any other elements? Yes, two more mirrors Point group name? ?
2 -D Symmetry Now try combining a 4 -fold rotation axis with a mirror Any other elements? Yes, two more mirrors Point group name? ? 4 mm Why not 4 mmmm?
2 -D Symmetry 3 -fold rotation axis with a mirror creates point group 3 m Why not 3 mmm?
2 -D Symmetry 6 -fold rotation axis with a mirror creates point group 6 mm
2 -D Symmetry All other combinations are either: Incompatible (2 + 2 cannot be done in 2 -D) Redundant with others already tried m + m 2 mm because creates 2 -fold This is the same as 2 + m 2 mm
2 -D Symmetry The original 6 elements plus the 4 combinations creates 10 possible 2 -D Point Groups: 1 2 3 4 6 m 2 mm 3 m 4 mm 6 mm Any 2 -D pattern of objects surrounding a point must conform to one of these groups
3 -D Symmetry New 3 -D Symmetry Elements 4. Rotoinversion a. 1 -fold rotoinversion ( 1 )
3 -D Symmetry New 3 -D Symmetry Elements 4. Rotoinversion a. 1 -fold rotoinversion ( 1 ) Step 1: rotate 360/1 (identity)
3 -D Symmetry New 3 -D Symmetry Elements 4. Rotoinversion a. 1 -fold rotoinversion ( 1 ) Step 1: rotate 360/1 (identity) Step 2: invert This is the same as i, so not a new operation
3 -D Symmetry New Symmetry Elements 4. Rotoinversion b. 2 -fold rotoinversion ( 2 ) Step 1: rotate 360/2 Note: this is a temporary step, the intermediate motif element does not exist in the final pattern
3 -D Symmetry New Symmetry Elements 4. Rotoinversion b. 2 -fold rotoinversion ( 2 ) Step 1: rotate 360/2 Step 2: invert
3 -D Symmetry New Symmetry Elements 4. Rotoinversion b. 2 -fold rotoinversion ( 2 ) The result:
3 -D Symmetry New Symmetry Elements 4. Rotoinversion b. 2 -fold rotoinversion ( 2 ) This is the same as m, so not a new operation
3 -D Symmetry New Symmetry Elements 4. Rotoinversion c. 3 -fold rotoinversion ( 3 )
3 -D Symmetry New Symmetry Elements 4. Rotoinversion c. 3 -fold rotoinversion ( 3 ) Step 1: rotate 360 o/3 Again, this is a temporary step, the intermediate motif element does not exist in the final pattern 1
3 -D Symmetry New Symmetry Elements 4. Rotoinversion c. 3 -fold rotoinversion ( 3 ) Step 2: invert through center
3 -D Symmetry New Symmetry Elements 4. Rotoinversion c. 3 -fold rotoinversion ( 3 ) 1 Completion of the first sequence 2
3 -D Symmetry New Symmetry Elements 4. Rotoinversion c. 3 -fold rotoinversion ( 3 ) Rotate another 360/3
3 -D Symmetry New Symmetry Elements 4. Rotoinversion c. 3 -fold rotoinversion ( 3 ) Invert through center
3 -D Symmetry New Symmetry Elements 4. Rotoinversion c. 3 -fold rotoinversion ( 3 ) 3 1 Complete second step to create face 3 2
3 -D Symmetry New Symmetry Elements 4. Rotoinversion c. 3 -fold rotoinversion ( 3 ) Third step creates face 4 (3 (1) 4) 3 1 4 2
3 -D Symmetry New Symmetry Elements 4. Rotoinversion c. 3 -fold rotoinversion ( 3 ) Fourth step creates face 5 (4 (2) 5) 1 5 2
3 -D Symmetry New Symmetry Elements 4. Rotoinversion c. 3 -fold rotoinversion ( 3 ) Fifth step creates face 6 (5 (3) 6) Sixth step returns to face 1 5 1 6
3 -D Symmetry New Symmetry Elements 4. Rotoinversion c. 3 -fold rotoinversion ( 3 ) This is unique 5 4 3 1 6 2
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 )
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 )
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 ) 1: Rotate 360/4
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 ) 1: Rotate 360/4 2: Invert
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 ) 1: Rotate 360/4 2: Invert
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 ) 3: Rotate 360/4
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 ) 3: Rotate 360/4 4: Invert
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 ) 3: Rotate 360/4 4: Invert
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 ) 5: Rotate 360/4
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 ) 5: Rotate 360/4 6: Invert
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 ) This is also a unique operation
3 -D Symmetry New Symmetry Elements 4. Rotoinversion d. 4 -fold rotoinversion ( 4 ) A more fundamental representative of the pattern
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) Begin with this framework:
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) 1
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) 1
3 -D Symmetry New Symmetry Elements 4. Rotoinversion 1 e. 6 -fold rotoinversion ( 6 ) 2
3 -D Symmetry New Symmetry Elements 4. Rotoinversion 1 e. 6 -fold rotoinversion ( 6 ) 2
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) 1 3 2
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) 1 3 2
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) 1 3 2 4
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) 1 3 2 4
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) 1 3 5 2 4
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) 1 3 5 2 4
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) 1 3 5 2 6 4
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) Note: this is the same as a 3 -fold rotation axis perpendicular to a mirror plane Top View (combinations of elements follows)
3 -D Symmetry New Symmetry Elements 4. Rotoinversion e. 6 -fold rotoinversion ( 6 ) A simpler pattern Top View
3 -D Symmetry We now have 10 unique 3 -D symmetry operations: 1 2 3 4 6 i m 3 4 6 Combinations of these elements are also possible A complete analysis of symmetry about a point in space requires that we try all possible combinations of these symmetry elements
3 -D Symmetry 3 -D symmetry element combinations a. Rotation axis parallel to a mirror Same as 2 -D 2 || m = 2 mm 3 || m = 3 m, also 4 mm, 6 mm b. Rotation axis mirror 2 m = 2/m 3 m = 3/m, also 4/m, 6/m c. Most other rotations + m are impossible 2 -fold axis at odd angle to mirror? Some cases at 45 o or 30 o are possible, as we shall see
3 -D Symmetry 3 -D symmetry element combinations d. Combinations of rotations 2 + 2 at 90 o 222 (third 2 required from combination) 4 + 2 at 90 o 422 ( “ “ “ ) 6 + 2 at 90 o 622 ( “ “ “ )
3 -D Symmetry As in 2 -D, the number of possible combinations is limited only by incompatibility and redundancy There are only 22 possible unique 3 -D combinations, when combined with the 10 original 3 -D elements yields the 32 3 -D Point Groups
3 -D Symmetry But it soon gets hard to visualize (or at least portray 3 -D on paper) Fig. 5. 18 of Klein (2002) Manual of Mineral Science, John Wiley and Sons
3 -D Symmetry The 32 3 -D Point Groups Every 3 -D pattern must conform to one of them. This includes every crystal, and every point within a crystal Table 5. 1 of Klein (2002) Manual of Mineral Science, John Wiley and Sons
3 -D Symmetry The 32 3 -D Point Groups Regrouped by Crystal System (more later when we consider translations) Table 5. 3 of Klein (2002) Manual of Mineral Science, John Wiley and Sons
3 -D Symmetry The 32 3 -D Point Groups After Bloss, Crystallography and Crystal Chemistry. © MSA
- What is skew symmetric matrix
- Tiga dimensi perasaan menurut wundt
- Strip pattern symmetry
- Symmetric with respect to
- Symmetry powerpoint presentation
- Fundamental part 2
- Giọng cùng tên là
- Voi kéo gỗ như thế nào
- Thẻ vin
- Thơ thất ngôn tứ tuyệt đường luật
- Các châu lục và đại dương trên thế giới
- Hươu thường đẻ mỗi lứa mấy con
- Từ ngữ thể hiện lòng nhân hậu
- Thế nào là hệ số cao nhất
- Diễn thế sinh thái là
- Vẽ hình chiếu vuông góc của vật thể sau
- 101012 bằng
- Lời thề hippocrates
- Tư thế worm breton là gì
- đại từ thay thế
- Quá trình desamine hóa có thể tạo ra
- Công thức tiính động năng
- Sự nuôi và dạy con của hổ
- Thế nào là mạng điện lắp đặt kiểu nổi
- Các loại đột biến cấu trúc nhiễm sắc thể
- Thế nào là sự mỏi cơ
- Bổ thể
- Vẽ hình chiếu đứng bằng cạnh của vật thể
- độ dài liên kết
- Thiếu nhi thế giới liên hoan
- Hát lên người ơi alleluia
- điện thế nghỉ
- Một số thể thơ truyền thống
- Trời xanh đây là của chúng ta thể thơ
- Số nguyên tố là số gì
- đặc điểm cơ thể của người tối cổ
- Tỉ lệ cơ thể trẻ em
- Fecboak
- Các châu lục và đại dương trên thế giới
- ưu thế lai là gì
- Hệ hô hấp
- Kể tên các môn thể thao
- Tư thế ngồi viết
- Hát kết hợp bộ gõ cơ thể
- Cái miệng nó xinh thế chỉ nói điều hay thôi
- Mật thư anh em như thể tay chân
- Tư thế ngồi viết
- The part of a shadow surrounding the darkest part
- Brainpop ratios
- Minitab adalah
- Define technical description
- Part whole model subtraction
- Parts of the front bar
- Unit ratio definition
- Principal axes theorem
- Transitive closure meaning
- Examples of diagonal matrix
- Symmetric difference quotient
- Heavy symmetric top with one point fixed
- Theorem
- Anti symmetric relation example
- Eigenvectors of orthogonal matrix
- Security aspects
- What is symmetric difference between two sets
- Key distribution
- Multpoe
- Reflexive relation examples
- Symmetric shared memory architecture
- Nat hole punching
- Properties of equality
- Searchable symmetric encryption
- Uniform symmetric or skewed
- Searchable symmetric encryption
- Which symmetric block cipher supersedes blowfish
- Confidentiality
- Symmetric shared memory architecture
- Symmetric transpose
- A long jumper leaves the ground at an angle of 45
- Symmetrical growth restriction
- Symmetric about the y axis
- Java symmetric encryption
- Reciprocal pythagorean theorem
- Antisymmetric relation example
- Encipherment using modern symmetric-key ciphers
- Bilaterally symmetric
- Shape of distribution
- Half wave symmetry
- Traditional ciphers
- Representing relations using digraphs
- Oblate top
- Example of reflexive property
- Symmetric binary variables
- Diagonal matrix properties