Use "Crystal Lattice" in a sentence | "Crystal Lattice" sentence examples

Crystal lattice is a term used in the field of chemistry to describe the three-dimensional arrangement of atoms, ions, or molecules in a crystal. It is a highly ordered and repetitive structure that gives crystals their unique properties, such as their shape, color, and hardness. If you are studying chemistry or any related field, it is important to know how to use the term crystal lattice correctly in a sentence. Here are some tips to help you do just that:

1. Understand the meaning of crystal lattice Before you can use the term crystal lattice in a sentence, you need to understand what it means. Crystal lattice refers to the arrangement of atoms, ions, or molecules in a crystal. It is a highly ordered and repetitive structure that gives crystals their unique properties.

2. Use crystal lattice in a sentence to describe the structure of a crystal One way to use the term crystal lattice in a sentence is to describe the structure of a crystal.

For example, "The crystal lattice of diamond is a highly ordered arrangement of carbon atoms." This sentence describes the structure of diamond, which is made up of a highly ordered arrangement of carbon atoms.

3. Use crystal lattice in a sentence to explain the properties of a crystal Another way to use the term crystal lattice in a sentence is to explain the properties of a crystal.

For example, "The crystal lattice of quartz gives it its unique hardness and resistance to scratching." This sentence explains that the unique properties of quartz, such as its hardness and resistance to scratching, are due to its crystal lattice structure.

4. Use crystal lattice in a sentence to compare different crystals You can also use the term crystal lattice in a sentence to compare different crystals.

For example, "The crystal lattice of salt is different from that of diamond, which is why they have different properties." This sentence compares the crystal lattice structures of salt and diamond and explains why they have different properties.

5. Use crystal lattice in a sentence to discuss crystallography

Finally, you can use the term crystal lattice in a sentence to discuss crystallography, which is the study of crystals and their properties.

For example, "Crystallography is the study of the crystal lattice structures of different materials." This sentence explains what crystallography is and how it relates to the study of crystal lattice structures.

In conclusion, crystal lattice is an important term in the field of chemistry and related fields. To use it correctly in a sentence, you need to understand its meaning and how it relates to the structure and properties of crystals. By following these tips, you can use crystal lattice effectively in your writing and communication.

In the remaining portion of this article, additional example sentences are presented to demonstrate the usage of the term "Crystal Lattice" within sentences.

"Crystal Lattice"

(1) The polarized particles form a crystal lattice.

(2) By analyzing the eigenmodes of a crystal lattice

(3) The electrons diffract from the crystal lattice.

(4) The X-ray beam was diffracted by the crystal lattice

(5) The ionic compound formed a crystal lattice structure.

(6) Phonons can interact with defects in a crystal lattice

(7) The ions in a crystal lattice determine its structure.

(8) The molecules in the crystal lattice bonded hexagonally

(9) The crystal lattice of the compound is centrosymmetric.

(10) The ions in a crystal lattice determine its properties.

Sentence For "Crystal Lattice"

(11) Phonons are quantized vibrations of the crystal lattice.

(12) The crystals in the rock overlap like a crystal lattice.

(13) The anatase crystal lattice has a high degree of symmetry.

(14) X-rays can diffract when they encounter a crystal lattice.

(15) The interatomic spacing in this crystal lattice is uniform.

(16) The symmetry of a crystal lattice is an invariant property.

(17) The bismuthal crystal lattice has a rhombohedral structure.

(18) The axisymmetry of the crystal lattice made it more stable.

(19) The crystal lattice was composed of interconnected hexagons.

(20) The p-type doping introduces holes into the crystal lattice.

"Crystal Lattice" In A Sentence

(21) The borons in this crystal lattice give it a distinct color.

(22) The unit cell is repeated in space to form a crystal lattice.

(23) The bisymmetric structure of the crystal lattice was complex.

(24) The crystal lattice structure was studied in chemistry class.

(25) The crystallographer discovered a new crystal lattice pattern.

(26) Phonons are quanta of vibrational energy in a crystal lattice.

(27) The molecules in the crystal lattice were arranged hexagonally

(28) The divalents in this crystal lattice create a regular pattern.

(29) The crystal lattice of a mineral can be disrupted by impurities

(30) The crystal lattice of a salt crystal can be dissolved in water

"Crystal Lattice" Sentence

(31) The crystal lattice of a snowflake can exhibit fractal patterns

(32) The unit cell is the basic building block of a crystal lattice.

(33) The crystal lattice of a metal can undergo phase transformations

(34) The light scattered anisotropically through the crystal lattice.

(35) The symmetries in the crystal lattice gave it a unique structure.

(36) The crystal lattice of a protein can be disrupted by denaturation

(37) The ionised atoms in the crystal lattice determine its structure.

(38) The crystal lattice of a crystal determines its optical properties

(39) The quaternate structure of the crystal lattice gave it stability.

(40) The unit cell is the smallest repeating unit in a crystal lattice.

"Crystal Lattice" Sentence Examples

(41) The mineral's holohedral shape is a result of its crystal lattice.

(42) The X-ray beam diffracts when it interacts with a crystal lattice.

(43) The scientist observed pleochroic behavior in the crystal lattice.

(44) The toric symmetry of the crystal lattice was fascinating to study.

(45) The axisymmetry of a crystal lattice determines its symmetry group.

(46) The hemihedral crystal lattice is composed of repeating unit cells.

(47) Ionic bonding results in the formation of a stable crystal lattice.

(48) Phonons can scatter off defects and impurities in a crystal lattice.

(49) The interatomic forces determine the stability of a crystal lattice.

(50) Phonons can scatter off impurities and defects in a crystal lattice.

Sentence With "Crystal Lattice"

(51) The trihedral nature of the crystal lattice was analyzed in the lab.

(52) Bosonic modes of vibration in a crystal lattice are known as phonons.

(53) The crystal lattice of the compound is composed of hexahydrate units.

(54) The crystal lattice of the compound consists of hexahydrate crystals.

(55) The crystal lattice of this material can exhibit different polytypes.

(56) The ionic radius of an atom determines its size in a crystal lattice.

(57) Diamonds are composed of pure carbone in a crystal lattice structure.

(58) The anisotropy of the crystal lattice affected its optical properties.

(59) The crystal lattice of a crystal can exhibit defects and imperfections

(60) The isotropy of a crystal lattice determines its mechanical stability.

Use "Crystal Lattice" In A Sentence

(61) The water of crystallization can be trapped within the crystal lattice

(62) The pleonaste crystal lattice is composed of oxygen and aluminum ions.

(63) The indicatrix of a crystal lattice determines its optical properties.

(64) The interionic forces in the crystal lattice determined its stability.

(65) The microprobe allowed us to study the crystal lattice of the mineral.

(66) The planarity of a crystal lattice can affect its physical properties.

(67) The crystal lattice of a substance determines its physical properties.

(68) The elements in a crystal lattice are arranged in a repeating pattern.

(69) The crystal lattice of this mineral exhibits a tetrahedral arrangement.

(70) The internuclear spacing in a crystal lattice determines its structure.

Sentence Using "Crystal Lattice"

(71) The atoms in this crystal lattice cohere through strong chemical bonds.

(72) Phonons can be thought of as quantized vibrations in a crystal lattice.

(73) The ruthenate structure is characterized by its unique crystal lattice.

(74) The nondegenerate crystal lattice exhibited symmetry in all directions.

(75) The anhedrals in this crystal lattice are arranged in a unique pattern.

(76) The anhedrals in this crystal lattice are arranged in a random pattern.

(77) The crystal lattice structure of diamonds makes them incredibly strong.

(78) The isotropy of the crystal lattice determines its physical properties.

(79) The unit cell is repeated in three dimensions to form a crystal lattice.

(80) The fusibility of these minerals is influenced by their crystal lattice.

Sentences With "Crystal Lattice"

(81) The fine structure of this crystal lattice is crucial for its stability.

(82) The triclinic crystal lattice has three unequal axes and oblique angles.

(83) The crystallizable material exhibited a unique crystal lattice structure.

(84) The atoms in a crystal lattice are arranged in a spherical about pattern.

(85) The stability of a crystal lattice is influenced by its associated state.

(86) The organic structure of a crystal lattice determines its crystal system.

(87) The internuclear spacing in the crystal lattice determines its structure.

(88) The gemstone's pleochroism was a result of its crystal lattice structure.

(89) The addition of a seed crystal nucleates the growth of a crystal lattice.

(90) The molecules accrete together to form a solid crystal lattice structure.

Sentence Of "Crystal Lattice"

(91) The micrograph displayed the arrangement of atoms in the crystal lattice.

(92) The acicular structure of the crystal lattice made it strong and durable.

(93) The interatomic spacing in a crystal lattice is typically a few angstroms.

(94) Fonons are considered to be collective excitations of the crystal lattice.

(95) The p-type doping introduces acceptor impurities into the crystal lattice.

(96) The crystal lattice structure of the compound recrystallizes upon cooling.

(97) The lattice structure of the crystal lattice determines its melting point.

(98) The distance between atoms in a crystal lattice is measured in picometers.

(99) The anisotropism of the crystal lattice affected its thermal conductivity.

(100) The crystal lattice of a quartz crystal can vibrate at specific frequencies

"Crystal Lattice" Sentences

(101) The biaxal nature of the crystal lattice affected its thermal conductivity.

(102) The crystallinity of the crystal lattice determined its optical properties.

(103) The atomical bonding between the atoms in the crystal lattice was metallic.

(104) The tetrahedrally arranged molecules can pack tightly in a crystal lattice.

(105) Protonic defects in a crystal lattice can influence its optical properties.

(106) The n-s symmetry of the crystal lattice determines its physical properties.

(107) The axiality of the crystal lattice determines its symmetry and properties.

(108) The crystal lattice of a metal determines its conductivity and malleability.

(109) The ellipticity of a crystal lattice can affect the way it diffracts X-rays.

(110) The recrystallized compound exhibited a different crystal lattice structure.

"Crystal Lattice" Use In Sentence

(111) The anisotropism of the crystal lattice affects its electrical conductivity.

(112) The physics professor explained the baculiform shape of the crystal lattice.

(113) The rhombohedral crystal lattice can be visualized as a stack of rhombohedra.

(114) The octahedral crystal lattice of the mineral gives it its unique properties.

(115) The crystal lattice structure of a diamond gives it its exceptional hardness.

(116) The diffraction of X-rays through a crystal lattice can reveal its structure.

(117) The polycrystal structure of the crystal lattice creates a beautiful pattern.

(118) The quasiperiodic structure of the crystal lattice gave it unique properties.

(119) The water of crystallization can be chemically bonded to the crystal lattice.

(120) The centrosymmetric crystal lattice gives rise to unique magnetic properties.

Sentence On "Crystal Lattice"

(121) The dispersive forces between the ions caused them to form a crystal lattice.

(122) The axialities of a crystal lattice determine its overall shape and symmetry.

(123) The fine structure of this crystal lattice determines its optical properties.

(124) The crystal lattice of a substance can be determined using x-ray diffraction.

(125) The line spectrum of a crystal lattice can be used to study its phonon modes.

(126) The isoclinic angles of the crystal lattice determine its optical properties.

(127) The fluorescence of fluorites is caused by impurities in the crystal lattice.

(128) The coordination number of a sodium ion in a crystal lattice is typically six.

(129) The anisotropic growth of the crystal lattice affected its optical properties.

(130) The polymorphs of the substance can have different crystal lattice structures.

"Crystal Lattice" Example

(131) Anharmonic motion can result in the breaking of symmetry in a crystal lattice.

(132) The self-energy of a vibrating crystal lattice determines its phonon spectrum.

(133) The diffractometer revealed the presence of impurities in the crystal lattice.

(134) The lattice structure of the crystal lattice determines its optical properties.

(135) The pleochroism of the mineral was influenced by its crystal lattice structure.

(136) Scientists are studying the interlamellar interactions in this crystal lattice.

(137) The crystal lattice of a rock salt crystal can be cleaved along specific planes

(138) These calcites have a yellowish color due to impurities in the crystal lattice.

(139) Atomicities are used to describe the arrangement of atoms in a crystal lattice.

(140) The trihedral nature of the crystal lattice determined its physical properties.

"Crystal Lattice" In Sentence

(141) The orientation of dipoles in a crystal lattice affects its optical properties.

(142) The ions in a crystal lattice can be analyzed using a crystallography software.

(143) The conformal symmetry of a crystal lattice determines its physical properties.

(144) The crystal lattice of the salt recrystallised when it was exposed to moisture.

(145) The internuclear spacing in a crystal lattice determines the lattice parameters.

(146) The coordination number of a vanadium ion in a crystal lattice is typically six.

(147) The arrangement of atoms in a crystal lattice is determined by atomic structure.

(148) The septenary structure of a crystal lattice determines its physical properties.

(149) The study involved a microscopical examination of the crystal lattice structure.

(150) Phonons can be described as collective vibrations of atoms in a crystal lattice.

"Crystal Lattice" Sentences In English

(151) The biradial structure of the crystal lattice gave it unique optical properties.

(152) The hemihedral crystal lattice can be visualized using three-dimensional models.

(153) The macle twinning in this mineral is a result of its crystal lattice structure.

(154) The anharmonicity of the crystal lattice affects the phonon dispersion relation.

(155) The distance between atoms in a crystal lattice can be measured in millimicrons.

(156) The crystal lattice structure of ionic compounds contributes to their stability.

(157) The equiaxial structure of the crystal lattice resulted in a high melting point.

(158) The internuclear spacing in a crystal lattice determines its packing efficiency.

(159) The tetrahedral structure of the crystal lattice gives it its unique properties.

(160) Avogadro's number is used to calculate the number of atoms in a crystal lattice.

Make Sentence With "Crystal Lattice"

(161) Molecular attraction between ions in a crystal lattice determines its structure.

(162) The anharmonicity of the crystal lattice causes the thermal expansion of solids.

(163) The coordination number of a magnesium ion in a crystal lattice is typically six.

(164) The crystal lattice structure of an ionic compound is a result of the ionic bond.

(165) The biaxal arrangement of the atoms in the crystal lattice affected its hardness.

(166) The axisymmetric nature of the crystal lattice determined its optical properties.

(167) The trinodal structure of the crystal lattice determines its physical properties.

(168) The triaxial symmetry of this crystal lattice gives it unique optical properties.

(169) The scientist observed a monoclinous arrangement of atoms in the crystal lattice.

(170) The fluorescence of fluorites is caused by impurities within the crystal lattice.

Sentences Using "Crystal Lattice"

(171) The symmetry of a crystal lattice is determined by its invariant points and axes.

(172) The internuclear spacing in a crystal lattice determines the unit cell dimensions.

(173) The crystal lattice of a snowflake determines its intricate and symmetrical shape.

(174) The crystal lattice structure of ionic compounds is due to the strong ionic bonds.

(175) The isomerous structure of the crystal lattice gives it unique optical properties.

(176) The isomerous structure of the crystal lattice gives the mineral its unique shape.

(177) The isomorphous phase transition is accompanied by changes in the crystal lattice.

(178) The anisotropism of the crystal lattice affects its thermal expansion coefficient.

(179) A diffractometer is crucial if you want to analyze the crystal lattice parameters.

(180) The intergranular spacing in the crystal lattice determines its overall structure.

Sentence From "Crystal Lattice"

(181) The internuclear spacing in a crystal lattice determines its unit cell dimensions.

(182) The anisotropies in the crystal lattice affected the conductivity of the material.

(183) The crystal lattice of a mineral can be studied using X-ray diffraction techniques.

(184) The choice of dopant can determine the type of defects formed in a crystal lattice.

(185) Simple harmonic motion is used to study the behavior of atoms in a crystal lattice.

(186) The colors of fluorite are caused by impurities and defects in its crystal lattice.

(187) The isomerous structure of the crystal lattice gives the gemstone its unique color.

(188) The intergranular boundaries in the crystal lattice determine its overall strength.

(189) The force of attraction between ions in a crystal lattice determines its structure.

(190) The mineral has a dimorphous crystal lattice, but it still has distinct properties.

(191) The azimuthal symmetry of the crystal lattice was analyzed using X-ray diffraction.

(192) The unit cell of a crystal lattice can be determined by X-ray diffraction analysis.

(193) The distance between atoms in a crystal lattice is often expressed in millimicrons.

(194) The zeolitic framework of the crystal lattice was analyzed using X-ray diffraction.

(195) The catenulate structure of the crystal lattice determines its physical properties.

(196) The nucleation of defects in a crystal lattice can affect its mechanical properties.

(197) The cohesive energy of a crystal lattice is influenced by the strength of its bonds.

(198) The crystal lattice of a salt crystal can be disrupted by the addition of other ions

(199) The crystallographer analyzed the symmetry of the tetrahedra in the crystal lattice.

(200) The polycrystal structure of the crystal lattice creates a stable crystal structure.

(201) The size and charge of counterions can influence the structure of a crystal lattice.

(202) The anharmonic behavior of a crystal lattice can result in the formation of defects.

(203) The lattice structure of the crystal lattice determines its electrical conductivity.

(204) The impurities in the crystal lattice are removed when the substance recrystallizes.

(205) The dopant was introduced into the crystal lattice to create a p-type semiconductor.

(206) The spacing between adjacent atoms in a crystal lattice is typically a few angstroms.

(207) The spacing between adjacent atoms in a crystal lattice can be measured in angstroms.

(208) The polycrystal structure of the crystal lattice creates a strong bond between atoms.

(209) The coplanarity of the atoms in the crystal lattice determined its crystal structure.

(210) The tetrahedrally coordinated ions can exchange positions within the crystal lattice.

(211) Monocrystal is a type of crystal structure that consists of a single crystal lattice.

(212) Enantiomorphism can be observed in the arrangement of atoms within a crystal lattice.

(213) The water of hydration in a crystal lattice can help determine its crystal structure.

(214) The tripodal arrangement of the atoms in the crystal lattice was studied extensively.

(215) The valences of the elements in this mineral determine its crystal lattice structure.

(216) The antiparallel arrangement of atoms in a crystal lattice can affect its properties.

(217) The ultraparallel structure of the crystal lattice determines its physical properties.

(218) The scientist discovered a new mineral with a tetragonally structured crystal lattice.

(219) Antiferromagnetic ordering is characterized by alternating spins in a crystal lattice.

(220) The color of embolite can vary depending on impurities present in the crystal lattice.

Short & Simple Example Sentence For "Crystal Lattice" | "Crystal Lattice" Sentence

(221) The homological structure of the crystal lattice was analyzed using X-ray diffraction.

(222) The distance between atoms in a crystal lattice is typically measured in millimicrons.

(223) The trigonal prismatic shape of the crystal lattice was observed under the microscope.

(224) The aeolotropic nature of the crystal lattice affects the way light passes through it.

(225) The crystal lattice of a semiconductor material determines its electrical conductivity.

(226) The choice of dopant can determine the type of impurities present in a crystal lattice.

(227) The non-euclidean structure of this crystal lattice gives it unique optical properties.

(228) The polymorphs of the compound were found to have different crystal lattice structures.

(229) The uniserial structure of the crystal lattice gave the gemstone its unique properties.

(230) The formation of an ionic bond results in the formation of a crystal lattice structure.

(231) The arrangement of chromophores in a crystal lattice can affect its optical properties.

(232) The p-type layer is formed by introducing acceptor impurities into the crystal lattice.

(233) The diffractions of X-rays through a crystal lattice can produce a diffraction pattern.

(234) Isomorphous substitution occurs when one element replaces another in a crystal lattice.

(235) The color of nephelite can vary depending on impurities present in the crystal lattice.

(236) The cohesive energy of a crystal lattice is influenced by the arrangement of its atoms.

(237) The maximum density of a crystal lattice is determined by the arrangement of its atoms.

(238) The mineralogical structure of the crystal lattice was studied using X-ray diffraction.

(239) The octahedral symmetry of the crystal lattice is reflected in its diffraction pattern.

(240) The octahedral shape of the molecule allows for efficient packing in a crystal lattice.

How Do You Write A Good Sentence With "Crystal Lattice"?

(241) The aeolotropic structure of the crystal lattice was determined by electron microscopy.

(242) The bipyramidal symmetry of the crystal lattice is reflected in its physical properties.

(243) The tetrahedral shape of the molecule allows for efficient packing in a crystal lattice.

(244) The crystal lattice of a salt crystal is responsible for its characteristic cubic shape.

(245) The cubic lattice arrangement of atoms in the crystal lattice was studied by scientists.

(246) The crystal lattice structure allows the substance to crystallize in a specific pattern.

(247) The color of dawsonites can vary depending on impurities present in the crystal lattice.

(248) The color of uranophane can vary depending on impurities present in the crystal lattice.

(249) The p-type layer is formed by introducing trivalent impurities into the crystal lattice.

(250) The crystal lattice structure of the compound can be improved through recrystallization.

(251) The spectral purity of the crystal lattice was determined through X-ray crystallography.

(252) Scalenohedra can be used as a tool for determining the orientation of a crystal lattice.

(253) The isomorphous substitution of ions in the crystal lattice affects the mineral's color.

(254) The anharmonicity of the crystal lattice affects the thermal conductivity of a material.

(255) The spacing between adjacent layers in a crystal lattice is often measured in angstroms.

(256) The molecules in the crystal lattice were arranged hexagonally, giving it its structure.

(257) The binding energy of a crystal lattice is the energy required to break its ionic bonds.

(258) The ionicity of the crystal lattice structure was the reason for its high melting point.

(259) The octahedral shape of the molecule allows for efficient packing in the crystal lattice.

(260) The crystal lattice of a protein determines its three-dimensional structure and function.

English Sentences With Audio Using The Word "Crystal Lattice".

(261) The crystal lattice of a crystal can be visualized using computer simulations and models.

(262) X-ray diffraction can be used to determine the arrangement of atoms in a crystal lattice.

(263) The higherdimensional geometry of the crystal lattice determined its physical properties.

(264) The metallic bond is influenced by the arrangement of metal atoms in the crystal lattice.

(265) The hyperfine structure of ions in a crystal lattice can affect their optical properties.

(266) The interionic bonding in the crystal lattice gave rise to its unique optical properties.

(267) The tetrahedral arrangement of the ions in the crystal lattice creates a regular pattern.

(268) Van der Waals radii are used to estimate the distance between atoms in a crystal lattice.

(269) The mineralogical structure of the crystal lattice was studied using electron microscopy.

(270) The bipyramidal shape of the molecule allows for efficient packing in the crystal lattice.

(271) The bivalencies of these ions allow them to attract each other and form a crystal lattice.

(272) The crystal lattice of ice determines its hexagonal shape and allows it to float on water.

(273) The color of baddeleyites can vary depending on impurities present in the crystal lattice.

(274) The fluorescence of willemite is due to the presence of impurities in the crystal lattice.

(275) The color of pyromorphite can vary depending on impurities present in the crystal lattice.

(276) The coordination number of a metal in a crystal lattice determines its packing efficiency.

(277) The physicist analyzed a cross section of a crystal lattice to study its atomic structure.

(278) The columbic interaction between the ions in the crystal lattice determines its stability.

(279) The rhombohedral crystal lattice is often used as a reference for other crystal structures.

(280) The crystallographic data supported the hypothesis of a dislocation in the crystal lattice.

How To Use "Crystal Lattice" With Example Sentences.

(281) The microstructural examination showed the presence of dislocations in the crystal lattice.

(282) The topologic arrangement of atoms in a crystal lattice determines its physical properties.

(283) The color of rensselaerite can vary depending on impurities present in the crystal lattice.

(284) The unique color of erythrite is due to the presence of cobalt ions in its crystal lattice.

(285) The anharmonic behavior of a crystal lattice affects its thermal and mechanical properties.

(286) The distance between two adjacent atoms in a crystal lattice can be measured in picometers.

(287) The cohesive energy of a crystal lattice can be determined by measuring its lattice energy.

(288) The distance between two adjacent atoms in a crystal lattice can be measured in picometres.

(289) The intergranular spacing in the crystal lattice affects the material's optical properties.

(290) The tetrahedral symmetry of the crystal lattice gives rise to its piezoelectric properties.

(291) The distance between two adjacent sulfur atoms in a crystal lattice is about 3.7 angstroms.

(292) The distance between two adjacent oxygen atoms in a crystal lattice is about 2.8 angstroms.

(293) The equiaxial symmetry of the crystal lattice was evident in its X-ray diffraction pattern.

(294) The equiaxial symmetry of the crystal lattice contributed to its high thermal conductivity.

(295) The interlamellar spacing in the crystal lattice affects the material's optical properties.

(296) As a crystallographer, she was fascinated by the intricate patterns of the crystal lattice.

(297) The metastable state of the crystal lattice made it prone to sudden changes in temperature.

(298) The crystalline structure of a crystal lattice can be visualized using computer simulations.

(299) The crystal lattice of a rock salt crystal consists of alternating sodium and chloride ions.

(300) The columbic interaction between ions in a crystal lattice determines its overall stability.

(301) The trigonal arrangement of atoms in the crystal lattice determines its physical properties.

(302) The formation of scalenohedra is influenced by the crystal lattice structure of the mineral.

(303) The growth of a crystal lattice can be understood through lawlike crystal growth mechanisms.

(304) The anharmonicity of the crystal lattice affects the lattice dynamics and phonon dispersion.

(305) The steric interactions between the molecules affected their packing in the crystal lattice.

(306) The bipyramidal arrangement of the atoms in the crystal lattice creates a repeating pattern.

(307) The presence of defects in a crystal lattice can affect the formation of specific polytypes.

(308) The anharmonic oscillator model is used to study the behavior of atoms in a crystal lattice.

(309) The intermolecular forces between molecules in a crystal lattice give it a regular structure.

(310) The octahedral arrangement of the atoms in the crystal lattice creates a strong bond network.

(311) The close-packed nature of the atoms in a crystal lattice determines its physical properties.

(312) The atomistic model allows us to study the behavior of individual atoms in a crystal lattice.

(313) Crystallography allows scientists to visualize the arrangement of atoms in a crystal lattice.

(314) The growth of crystallites can be hindered by the presence of defects in the crystal lattice.

(315) The biaxal arrangement of the atoms in the crystal lattice determined its optical dispersion.

(316) The trigonal arrangement of atoms in the crystal lattice determines its thermal conductivity.

(317) The monocyclic structure of the compound allows for efficient packing in the crystal lattice.

(318) The green color of olivenite is caused by the presence of copper ions in its crystal lattice.

(319) The interlamellar distance between the layers of a crystal lattice can affect its properties.

(320) The molecules in a crystal lattice accrete with respect to atomic bonding and lattice energy.

(321) The martensitic phase is formed when carbon atoms are trapped in the crystal lattice of iron.

(322) The bipyramidal symmetry of the crystal lattice is reflected in its X-ray diffraction pattern.

(323) The rhombohedral crystal lattice can be described as a three-dimensional arrangement of atoms.

(324) Calculating distances between molecules in a crystal lattice is important in material science.

(325) The steric clash between the bulky groups prevented the formation of a stable crystal lattice.

(326) Researchers used crystallographic techniques to determine the symmetry of the crystal lattice.

(327) The formation of an ionic bond results in the formation of a stable crystal lattice structure.

(328) The trigonal arrangement of atoms in the crystal lattice determines its mechanical properties.

(329) The interdiffusion of atoms in a crystal lattice can lead to the formation of solid solutions.

(330) The anharmonicity of the crystal lattice affects the thermal expansion behavior of a material.

(331) The p-type doping process involves adding impurities that create holes in the crystal lattice.

(332) The molecular structure of a diamond is made up of carbon atoms arranged in a crystal lattice.

(333) The close-packed arrangement of atoms in a crystal lattice results in a highly dense structure.

(334) The birefringence of the crystal lattice affects the propagation of light through the material.

(335) The centrosymmetric nature of the molecule allows for efficient packing in the crystal lattice.

(336) The isomorphous substitution of elements in the crystal lattice affects the mineral's hardness.

(337) The anharmonic effects in the crystal lattice can lead to changes in the material's properties.

(338) The close-packed arrangement of atoms in a crystal lattice can lead to the formation of defects.

(339) The tetragonal arrangement of atoms in the crystal lattice resulted in high mechanical strength.

(340) The interionic forces between the particles determined their arrangement in the crystal lattice.

(341) The fluorescence of greenockite can vary depending on impurities present in the crystal lattice.

(342) The fluorescence of zincite can vary depending on the impurities present in the crystal lattice.

(343) The electron lens enables scientists to visualize the arrangement of atoms in a crystal lattice.

(344) The atoms in a crystal lattice accrete with respect to lattice vibrations and thermal expansion.

(345) The electrovalence of the ions in the crystal lattice determined its melting and boiling points.

(346) The multiparticle excitations in a crystal lattice can be studied using spectroscopy techniques.

(347) The close-packed arrangement of atoms in a metallic crystal lattice gives metals their ductility.

(348) The crystal lattice of a diamond is composed of carbon atoms arranged in a tetrahedral structure.

(349) The optical properties of cerite can vary depending on impurities present in the crystal lattice.

(350) The x-ray diffraction pattern exhibited sharp peaks, indicating a highly ordered crystal lattice.

(351) The spacing between atoms in a metallic crystal lattice is often on the order of a few angstroms.

(352) The debye temperature is often used to characterize the behavior of phonons in a crystal lattice.

(353) The interlamellar distance in the crystal lattice affects the material's electrical conductivity.

(354) The electron beam was diffracting through the crystal lattice, revealing its molecular structure.

(355) The crystal lattice of a protein can be determined using techniques such as X-ray crystallography.

(356) The crystal lattice of a diamond gives it its exceptional brilliance and ability to reflect light.

(357) The biaxal arrangement of the atoms in the crystal lattice determined its electrical conductivity.

(358) The trigonal pyramid geometry of the molecule allows for efficient packing in the crystal lattice.

(359) The binding energy of a metal ion in a crystal lattice is influenced by its coordination geometry.

(360) The intergranular migration of defects in the crystal lattice affects its electrical conductivity.

(361) The dipole-dipole interactions between molecules contribute to the stability of a crystal lattice.

(362) The interatomic forces between the atoms in the crystal lattice determine its physical properties.

(363) The equimolecular distribution of atoms in the crystal lattice was confirmed by X-ray diffraction.

(364) The isomorphous substitution of ions in the crystal lattice affects the properties of the mineral.

(365) The distance between two carbon atoms in a diamond crystal lattice is approximately 154 picometers.

(366) The interlamellar arrangement of atoms in a crystal lattice determines its electrical conductivity.

(367) The interlamellar distance between the layers of a crystal lattice affects its magnetic properties.

(368) The intergranular spacing in the crystal lattice determines the material's electrical conductivity.

(369) The close-packed arrangement of particles in a crystal lattice can result in anisotropic properties.

(370) The close-packed arrangement of atoms in a metallic crystal lattice gives metals their malleability.

(371) The close-packed arrangement of atoms in a crystal lattice can result in the formation of vacancies.

(372) The crystal lattice structure of electrovalent compounds gives them their characteristic properties.

(373) The interlamellar distance between the layers of a crystal lattice affects its mechanical stability.

(374) The tetrahedral arrangement of the atoms in the crystal lattice creates a three-dimensional network.

(375) The cohesive energy of a crystal lattice can be affected by the presence of impurities or vacancies.

(376) The close-packed arrangement of atoms in a diamond crystal lattice gives it its exceptional hardness.

(377) The crystal lattice of a metal can be modified through processes such as alloying and heat treatment.

(378) The cohesive energy of a crystal lattice can be visualized as the energy required to break its bonds.

(379) The interlamellar arrangement of atoms in a crystal lattice determines its crystallographic symmetry.

(380) College students can use the diffractometer to determine the atomic arrangement in a crystal lattice.

(381) The deep blue color of embolite is caused by the presence of trace impurities in its crystal lattice.

(382) The crystal lattice was so complex that it took years of research to fully understand its properties.

(383) The crystal lattice of a mineral can be affected by external factors such as temperature and pressure.

(384) The behavior of phonons can be affected by the presence of defects or impurities in a crystal lattice.

(385) The epitaxy process involves depositing atoms or molecules onto a substrate to form a crystal lattice.

(386) The interionic potential energy between the ions in the crystal lattice determines the lattice energy.

(387) The close-packed arrangement of atoms in a crystal lattice can result in the formation of dislocations.

(388) The freezing point of a substance can be affected by the presence of impurities in the crystal lattice.

(389) The collisional process between the atoms in the solid state led to the formation of a crystal lattice.

(390) The interparticle distance between the atoms in the crystal lattice determines its physical properties.

(391) The wurtzite crystal lattice can be described as a repeating pattern of tetrahedrally coordinated atoms.

(392) The anisotropic nature of the crystal lattice affects the way light is transmitted through the material.

(393) The crystal lattice of a semiconductor material can be engineered to have specific electrical properties.

(394) The centrosymmetric arrangement of molecules in the crystal lattice allows for efficient energy transfer.

(395) The clinopinacoid crystal structure is determined by the arrangement of atoms within the crystal lattice.

(396) Gettering is a process used in semiconductor manufacturing to remove impurities from the crystal lattice.

(397) The chemical compound recrystallizes into a different crystal lattice when exposed to certain conditions.

(398) The magnetic conductivity of a substance can be affected by impurities or defects in its crystal lattice.

(399) The close-packed arrangement of atoms in a crystal lattice can affect the thermal expansion of a material.

(400) The isomorphous substitution of ions in the crystal lattice affects the mineral's electrical conductivity.

(401) The isomorphous substitution of elements in the crystal lattice affects the mineral's magnetic properties.

(402) The interionic distance between the ions in the crystal lattice determines the strength of the ionic bond.

(403) The interlamellar distance between the layers of a crystal lattice can be measured using X-ray diffraction.

(404) Phonon is a quantum mechanical concept that describes the vibrational motion of atoms in a crystal lattice.

(405) The formation of suboxides can be influenced by the presence of defects or vacancies in the crystal lattice.

(406) The interionic attraction between the oppositely charged ions results in the formation of a crystal lattice.

(407) The close-packed arrangement of atoms in a diamond crystal lattice gives it its exceptional refractive index.

(408) The close-packed arrangement of atoms in a crystal lattice can result in the formation of interstitial sites.

(409) The magnetic ordering in ferrimagnetism can be influenced by the arrangement of atoms in the crystal lattice.

(410) X-ray crystallography can determine the positions of atoms within a crystal lattice to within a few angstroms.

(411) The close-packed arrangement of atoms in a diamond crystal lattice gives it its exceptional optical properties.

(412) The close-packed arrangement of atoms in a crystal lattice can affect the electrical conductivity of a material.

(413) The crystal lattice of a quartz crystal is composed of silicon and oxygen atoms arranged in a repeating pattern.

(414) The close-packed arrangement of atoms in a metallic crystal lattice gives metals their characteristic properties.

(415) The interaction between excitons and phonons (vibrational modes of the crystal lattice) affects their properties.

(416) The behavior of phonons can be affected by the presence of dislocations or grain boundaries in a crystal lattice.

(417) With the transmission electron microscope, researchers could study the arrangement of atoms in a crystal lattice.

(418) Pyroelectricity is a result of the change in the dipole moment of the crystal lattice due to temperature changes.

(419) The close-packed arrangement of atoms in a crystal lattice can affect the material's response to external stimuli.

(420) The crystal lattice of quartz gives it its unique ability to generate an electric charge when pressure is applied.

(421) The crystal lattice of a semiconductor material can be doped with impurities to alter its electrical conductivity.

(422) With the transmission electron microscope, scientists can visualize the arrangement of atoms in a crystal lattice.

(423) Anisotropic materials can be difficult to manufacture due to the need for precise alignment of the crystal lattice.

(424) The conversion of potassium into a solid crystal lattice structure is important for certain electronic applications.

(425) The fluorescence of olivenite under ultraviolet light can vary depending on impurities present in the crystal lattice.

(426) Crystallizing in the presence of impurities, the crystal lattice structure was disrupted and the crystal became flawed.

(427) The crystal lattice of a rock salt crystal can be analyzed using techniques such as electron microscopy and spectroscopy.

(428) The process of doping involves introducing dopant atoms into a crystal lattice, which can alter its electronic properties.

(429) The anelasticity of the crystal lattice resulted in a delayed recovery of its original shape after being subjected to stress.

(430) Allomorphic modifications can affect the crystal lattice arrangement, and they can also impact the packing density of molecules.

(431) Antiferromagnets can exhibit magnetostriction if their crystal lattice undergoes a distortion in the presence of a magnetic field.

(432) Understanding bisymmetries is essential in the field of crystallography to determine the arrangement of atoms in a crystal lattice.

(433) The clinopinacoid crystal structure is determined by the arrangement of atoms within the crystal lattice and their bonding patterns.

(434) The spacing between atoms in a crystal lattice can be measured using X-ray diffraction to determine the interatomic distances in angstroms.

(435) The substitutional doping of semiconductors involves replacing some of the atoms in the crystal lattice with impurities to alter their electrical properties.

(436) The catenulate arrangement of the molecules in the crystal lattice determines its physical properties, and it can be modified by changing the conditions of crystallization.

Learning English Faster Through Complete Sentences With "Crystal Lattice"

Sentences are everywhere.
Without sentences, language doesn’t really work.

When you first started learning English, you may have memorized words such as English meaning of the word "Crystal Lattice"; But now that you have a better understanding of the language, there’s a better way for you to learn meaning of "Crystal Lattice" through sentence examples.

True, there are still words that you don’t know. But if you learn whole sentences with "Crystal Lattice", instead of the word "Crystal Lattice" by itself, you can learn a lot faster!

Focus Your English Learning On Sentences With "Crystal Lattice".

Why Is Focusing on Sentences Important?
Sentences are more than just strings of words. They’re thoughts, ideas and stories. Just like letters build words, words build sentences. Sentences build language, and give it personality.

Again, without sentences, there’s no real communication. If you were only reading words right now, you wouldn’t be able to understand what I’m saying to you at all.

- The Word "Crystal Lattice" in Example Sentences.
- "Crystal Lattice" in a sentence.
- How to use "Crystal Lattice" in a sentence.
- 10 examples of sentences "Crystal Lattice".
- 20 examples of simple sentences "Crystal Lattice".

All the parts of speech in English are used to make sentences. All sentences include two parts: the subject and the verb (this is also known as the predicate). The subject is the person or thing that does something or that is described in the sentence. The verb is the action the person or thing takes or the description of the person or thing. If a sentence doesn’t have a subject and a verb, it is not a complete sentence (e.g., In the sentence “Went to bed,” we don’t know who went to bed).

Four Types Of Sentence Structure.

Simple Sentences With "Crystal Lattice"

A simple sentence with "Crystal Lattice"contains a subject and a verb, and it may also have an object and modifiers. However, it contains only one independent clause.

Compound Sentences With "Crystal Lattice"

A compound sentence with "Crystal Lattice" contains at least two independent clauses. These two independent clauses can be combined with a comma and a coordinating conjunction or with a semicolon.

Complex Sentences With "Crystal Lattice"

A complex sentence with "Crystal Lattice" contains at least one independent clause and at least one dependent clause. Dependent clauses can refer to the subject (who, which) the sequence/time (since, while), or the causal elements (because, if) of the independent clause.

Compound-Complex Sentences With "Crystal Lattice"

Sentence types can also be combined. A compound-complex sentence with "Crystal Lattice" contains at least two independent clauses and at least one dependent clause.