Description
Red crystal Bracelet is the
best feeling stone. The location is in the middle of the chest or
the middle of breasts, corresponding to one of the seven chakra
"heart chakra" the function: balancing the thymus,
strengthening the heathy condition of heart and lung, easing
the tense and fidgety emotion so as to make you broad-minded, know
how to considerate others, feel people’s’ innermost
being
Enterprises with export qualification and international ecommerce
technology,Sino-japan joint venture. handan yinyou crafts Co.,Ltd
is located in handan which is the China historical and cultural
city, the capital of idiom. It covers an area of *7acres.It's with
the import and export qualification and the technique of the
international electronic business, mainly engaged in natural
crystal, emerald ,natural jade, natural gem, natural amber, series
of products and the international fashion style artware of the
natural jewel
Rose crystal is july’s birthstone. As the symbol of love and
"unconditional love stone" , it can promote the passion of lovers ,
form karma widely and contribute to the similarities between
people. The faction is protecting heart and lung, Easing tension,
relieving sour expression, letting you broad-minded and conversing
the negative energy to active one.
Amethyst has the following characteristics , developing
intelligence and interpersonal relations, inhancing intuition and
memory capacity , stabiliting emotion ,helping thinking, and giving
people the courage and strength. t represent noble constancy of
love so the sweethearts treat them as lovestones.
Crystal White is one of the seven treasures of Buddhism and was
named " cinta^-maN!i.". It was also Known as the "The King of
Crystal", stand for pure , selfless .Wiring Crystal White can
improve your aura, get rid of Distractions and bad luck
and defend villain at the same time. Its Magnetic field will let
you calm down and motivate your potential to deal with all things
with best condition.
Main article: Crystal structure
The process of forming a crystalline structure from a fluid or from
materials dissolved in
the fluid is often referred to as the crystallization process.
In the old example referenced
by the root meaning of the word crystal, water being cooled
undergoes a phase change from
liquid to solid beginning with small ice crystals that grow
until they fuse, forming a
polycrystalline structure. The physical properties of the ice
depend on the size and
arrangement of the individual crystals, or grains, and the
same may be said of metals
solidifying from a molten state.
Which crystal structure the fluid will form depends on the
chemistry of the fluid, the
conditions under which it is being solidified, and also on the
ambient pressure. While the
cooling process usually results in the generation of a
crystalline material, under certain
conditions, the fluid may be frozen in a noncrystalline state.
In most cases, this involves
cooling the fluid so rapidly that atoms cannot travel to their
lattice sites before they
lose mobility. A noncrystalline material, which has no
long-range order, is called an
amorphous, vitreous, or glassy material. It is also often
referred to as an amorphous solid,
although there are distinct differences between crystalline
solids and amorphous solids:
most notably, the process of forming a glass does not release
the latent heat of fusion.
Crystalline structures occur in all classes of materials, with
all types of chemical bonds.
Almost all metal exists in a polycrystalline state; amorphous
or single-crystal metals must
be produced synthetically, often with great difficulty.
Ionically bonded crystals can form
upon solidification of salts, either from a molten fluid or
upon crystallization from a
solution. Covalently bonded crystals are also very common,
notable examples being diamond,
silica, and graphite. Polymer materials generally will form
crystalline regions, but the
lengths of the molecules usually prevent complete
crystallization. Weak van der Waals forces
can also play a role in a crystal structure; for example, this
type of bonding loosely holds
together the hexagonal-patterned sheets in graphite.
Most crystalline materials have a variety of crystallographic
defects. The types and
structures of these defects may have a profound effect on the
properties of the materials.
Since the initial discovery of crystal-like individual arrays of
atoms that are not regularly repeated, made in ***2 by Dan
Shechtman, the acceptance of the concept and the word quasicrystal
have led the International Union of Crystallography to redefine the
term crystal to mean "any solid having an essentially discrete
diffraction diagram", thereby shifting the essential attribute of
crystallinity from position space to Fourier space. Within the
family of crystals one distinguishes between traditional crystals,
which are periodic, or repeating, at the atomic scale, and
aperiodic (incommensurate) crystals which are not. This broader
definition adopted in ***6 reflects the current understanding that
microscopic periodicity is a sufficient but not a necessary
condition for crystals.
While the term "crystal" has a precise meaning within
materials science and solid-state physics, colloquially "crystal"
refers to solid objects that exhibit well-defined and often
pleasing geometric shapes. In this sense of the word, many types of
crystals are found in nature. The shape of these crystals is
dependent on the types of molecular bonds between the atoms to
determine the structure, as well as on the conditions under which
they formed. Snowflakes, diamonds, and table salt are common
examples of crystals.
Some crystalline materials may exhibit special electrical
properties such as the ferroelectric effect or the piezoelectric
effect. Additionally, light passing through a crystal is often
refracted or bent in different directions, producing an array of
colors; crystal optics is the study of these effects. In periodic
dielectric structures a range of unique optical properties can be
expected as seen in photonic crystals.
Since the initial discovery of crystal-like individual arrays of
atoms that are not regularly repeated, made in ***2 by Dan
Shechtman, the acceptance of the concept and the word quasicrystal
have led the International Union of Crystallography to redefine the
term crystal to mean "any solid having an essentially discrete
diffraction diagram", thereby shifting the essential attribute of
crystallinity from position space to Fourier space. Within the
family of crystals one distinguishes between traditional crystals,
which are periodic, or repeating, at the atomic scale, and
aperiodic (incommensurate) crystals which are not. This broader
definition adopted in ***6 reflects the current understanding that
microscopic periodicity is a sufficient but not a necessary
condition for crystals.
While the term "crystal" has a precise meaning within materials
science and solid-state physics, colloquially "crystal" refers to
solid objects that exhibit well-defined and often pleasing
geometric shapes. In this sense of the word, many types of crystals
are found in nature. The shape of these crystals is dependent on
the types of molecular bonds between the atoms to determine the
structure, as well as on the conditions under which they formed.
Snowflakes, diamonds, and table salt are common examples of
crystals.
Some crystalline materials may exhibit special electrical
properties such as the ferroelectric effect or the piezoelectric
effect. Additionally, light passing through a crystal is often
refracted or bent in different directions, producing an array of
colors; crystal optics is the study of these effects. In periodic
dielectric structures a range of unique optical properties can be
expected as seen in photonic crystals.
Since the initial discovery of crystal-like individual arrays of
atoms that are not regularly repeated, made in ***2 by Dan
Shechtman, the acceptance of the concept and the word quasicrystal
have led the International Union of Crystallography to redefine the
term crystal to mean "any solid having an essentially discrete
diffraction diagram", thereby shifting the essential attribute of
crystallinity from position space to Fourier space. Within the
family of crystals one distinguishes between traditional crystals,
which are periodic, or repeating, at the atomic scale, and
aperiodic (incommensurate) crystals which are not. This broader
definition adopted in ***6 reflects the current understanding that
microscopic periodicity is a sufficient but not a necessary
condition for crystals.
While the term "crystal" has a precise meaning within materials
science and solid-state physics, colloquially "crystal" refers to
solid objects that exhibit well-defined and often pleasing
geometric shapes. In this sense of the word, many types of crystals
are found in nature. The shape of these crystals is dependent on
the types of molecular bonds between the atoms to determine the
structure, as well as on the conditions under which they formed.
Snowflakes, diamonds, and table salt are common examples of
crystals.
Some crystalline materials may exhibit special electrical
properties such as the ferroelectric effect or the piezoelectric
effect. Additionally, light passing through a crystal is often
refracted or bent in different directions, producing an array of
colors; crystal optics is the study of these effects. In periodic
dielectric structures a range of unique optical properties can be
expected as seen in photonic crystals.
Since the initial discovery of crystal-like individual
arrays of atoms that are not regularly repeated, made in ***2 by
Dan Shechtman, the acceptance of the concept and the word
quasicrystal have led the International Union of Crystallography to
redefine the term crystal to mean "any solid having an essentially
discrete diffraction diagram", thereby shifting the essential
attribute of crystallinity from position space to Fourier space.
Within the family of crystals one distinguishes between traditional
crystals, which are periodic, or repeating, at the atomic scale,
and aperiodic (incommensurate) crystals which are not. This broader
definition adopted in ***6 reflects the current understanding that
microscopic periodicity is a sufficient but not a necessary
condition for crystals.
While the term "crystal" has a precise meaning within materials
science and solid-state physics, colloquially "crystal" refers to
solid objects that exhibit well-defined and often pleasing
geometric shapes. In this sense of the word, many types of crystals
are found in nature. The shape of these crystals is dependent on
the types of molecular bonds between the atoms to determine the
structure, as well as on the conditions under which they formed.
Snowflakes, diamonds, and table salt are common examples of
crystals.
Some crystalline materials may exhibit special electrical
properties such as the ferroelectric effect or the piezoelectric
effect. Additionally, light passing through a crystal is often
refracted or bent in different directions, producing an array of
colors; crystal optics is the study of these effects. In periodic
dielectric structures a range of unique optical properties can be
expected as seen in photonic crystals.
Red crystal Bracelet is the
best feeling stone. The location is in the middle of the chest or
the middle of breasts, corresponding to one of the seven chakra
"heart chakra" the function: balancing the thymus,
strengthening the heathy condition of heart and lung, easing
the tense and fidgety emotion so as to make you broad-minded, know
how to considerate others, feel people’s’ innermost
being
Enterprises with export qualification and international ecommerce
technology,Sino-japan joint venture. handan yinyou crafts Co.,Ltd
is located in handan which is the China historical and cultural
city, the capital of idiom. It covers an area of *7acres.It's with
the import and export qualification and the technique of the
international electronic business, mainly engaged in natural
crystal, emerald ,natural jade, natural gem, natural amber, series
of products and the international fashion style artware of the
natural jewel
Rose crystal is july’s birthstone. As the symbol of love and
"unconditional love stone" , it can promote the passion of lovers ,
form karma widely and contribute to the similarities between
people. The faction is protecting heart and lung, Easing tension,
relieving sour expression, letting you broad-minded and conversing
the negative energy to active one.
Amethyst has the following characteristics , developing
intelligence and interpersonal relations, inhancing intuition and
memory capacity , stabiliting emotion ,helping thinking, and giving
people the courage and strength. t represent noble constancy of
love so the sweethearts treat them as lovestones.
Crystal White is one of the seven treasures of Buddhism and was
named " cinta^-maN!i.". It was also Known as the "The King of
Crystal", stand for pure , selfless .Wiring Crystal White can
improve your aura, get rid of Distractions and bad luck
and defend villain at the same time. Its Magnetic field will let
you calm down and motivate your potential to deal with all things
with best condition.
Main article: Crystal structure
The process of forming a crystalline structure from a fluid or from
materials dissolved in
the fluid is often referred to as the crystallization process.
In the old example referenced
by the root meaning of the word crystal, water being cooled
undergoes a phase change from
liquid to solid beginning with small ice crystals that grow
until they fuse, forming a
polycrystalline structure. The physical properties of the ice
depend on the size and
arrangement of the individual crystals, or grains, and the
same may be said of metals
solidifying from a molten state.
Which crystal structure the fluid will form depends on the
chemistry of the fluid, the
conditions under which it is being solidified, and also on the
ambient pressure. While the
cooling process usually results in the generation of a
crystalline material, under certain
conditions, the fluid may be frozen in a noncrystalline state.
In most cases, this involves
cooling the fluid so rapidly that atoms cannot travel to their
lattice sites before they
lose mobility. A noncrystalline material, which has no
long-range order, is called an
amorphous, vitreous, or glassy material. It is also often
referred to as an amorphous solid,
although there are distinct differences between crystalline
solids and amorphous solids:
most notably, the process of forming a glass does not release
the latent heat of fusion.
Crystalline structures occur in all classes of materials, with
all types of chemical bonds.
Almost all metal exists in a polycrystalline state; amorphous
or single-crystal metals must
be produced synthetically, often with great difficulty.
Ionically bonded crystals can form
upon solidification of salts, either from a molten fluid or
upon crystallization from a
solution. Covalently bonded crystals are also very common,
notable examples being diamond,
silica, and graphite. Polymer materials generally will form
crystalline regions, but the
lengths of the molecules usually prevent complete
crystallization. Weak van der Waals forces
can also play a role in a crystal structure; for example, this
type of bonding loosely holds
together the hexagonal-patterned sheets in graphite.
Most crystalline materials have a variety of crystallographic
defects. The types and
structures of these defects may have a profound effect on the
properties of the materials.
Since the initial discovery of crystal-like individual arrays of
atoms that are not regularly repeated, made in ***2 by Dan
Shechtman, the acceptance of the concept and the word quasicrystal
have led the International Union of Crystallography to redefine the
term crystal to mean "any solid having an essentially discrete
diffraction diagram", thereby shifting the essential attribute of
crystallinity from position space to Fourier space. Within the
family of crystals one distinguishes between traditional crystals,
which are periodic, or repeating, at the atomic scale, and
aperiodic (incommensurate) crystals which are not. This broader
definition adopted in ***6 reflects the current understanding that
microscopic periodicity is a sufficient but not a necessary
condition for crystals.
While the term "crystal" has a precise meaning within
materials science and solid-state physics, colloquially "crystal"
refers to solid objects that exhibit well-defined and often
pleasing geometric shapes. In this sense of the word, many types of
crystals are found in nature. The shape of these crystals is
dependent on the types of molecular bonds between the atoms to
determine the structure, as well as on the conditions under which
they formed. Snowflakes, diamonds, and table salt are common
examples of crystals.
Some crystalline materials may exhibit special electrical
properties such as the ferroelectric effect or the piezoelectric
effect. Additionally, light passing through a crystal is often
refracted or bent in different directions, producing an array of
colors; crystal optics is the study of these effects. In periodic
dielectric structures a range of unique optical properties can be
expected as seen in photonic crystals.
Since the initial discovery of crystal-like individual arrays of
atoms that are not regularly repeated, made in ***2 by Dan
Shechtman, the acceptance of the concept and the word quasicrystal
have led the International Union of Crystallography to redefine the
term crystal to mean "any solid having an essentially discrete
diffraction diagram", thereby shifting the essential attribute of
crystallinity from position space to Fourier space. Within the
family of crystals one distinguishes between traditional crystals,
which are periodic, or repeating, at the atomic scale, and
aperiodic (incommensurate) crystals which are not. This broader
definition adopted in ***6 reflects the current understanding that
microscopic periodicity is a sufficient but not a necessary
condition for crystals.
While the term "crystal" has a precise meaning within materials
science and solid-state physics, colloquially "crystal" refers to
solid objects that exhibit well-defined and often pleasing
geometric shapes. In this sense of the word, many types of crystals
are found in nature. The shape of these crystals is dependent on
the type
