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Models of the packing of molecules in two molecular solids, carbon dioxide or Dry ice (a),[1] and caffeine (c).[2] The gray, red, and purple balls represent carbon, oxygen, and nitrogen, respectively. Images of carbon dioxide (b) and caffeine (d) in the solid state at room temperature and atmosphere. The gaseous phase of the dry ice in image (b) is visible because the molecular solid is subliming.

A molecular solid is a solid consisting of discrete atoms and/or molecules held together by a collection of intermolecular interactions.[3][4][5][6][7][8][9] Examples of intermolecular interactions include van der Waals forces, dipole-dipole interactions, quadrupole interactions, π-π interactions, hydrogen bonding, halogen bonding, London dispersion forces, and in some molecular solids, coulombic interactions.[3][4][5][6][7][8][9][10][11][12] Van der Waals, dipole interactions, quadrupole interactions, π-π interactions, hydrogen bonding, and halogen bonding (2-127 kJ mol-1)[12] are typically much weaker than the forces holding together other solids: metallic (metallic bonding, 400-500 kJ mol-1),[4] ionic (Coulomb’s forces, 700-900 kJ mol-1),[4] and network solids (covalent bonds, 150-900 kJ mol-1).[4][12] Intermolecular interactions, typically do not involve delocalized electrons, unlike metallic and certain covalent bonds. Exceptions are charge-transfer complexes such as the tetrathiofulvane-tetracyanoquinodimethane (TTF-TCNQ), a radical ion salt.[5] These differences in the strength of force (i.e. covalent vs. van der Waals) and electronic characteristics (i.e. delocalized electrons) from other types of solids give rise to the unique mechanical, electronic, and thermal properties of molecular solids.[3][4][5][8]

For instance, molecular solids such as coronene have low conductivity (ρ = 1 x 10-12 to 1 x 10-18 Ω-1 cm-1)[13] making them poor electrical conductors.[4][5] As mentioned there are exceptions such as TTF-TCNQ (ρ = 5 x 102 Ω-1 cm-1),[5] but it still substantially less than the conductivity of copper (ρ = 6 x 105 Ω-1 cm-1).[8] Molecular solids tend to have lower fracture toughness (sucrose, KIc = 0.08 MPa m1/2)[14] than metal (iron, KIc = 50 MPa m1/2),[14] ionic (sodium chloride, KIc = 0.5 MPa m1/2),[14] and covalent solids (diamond, KIc = 5 MPa m1/2).[15] Molecular solids have low melting (Tm) and boiling (Tb) points compared to metal (iron), ionic (sodium chloride), and covalent solids (diamond).[4][5][8][16] Examples of molecular solids with low melting and boiling temperatures include argon, water, naphthalene, nicotine, and caffeine (see table below).[16][17] The constituents of molecular solids range in size from condensed monoatomic gases[18] to small molecules (i.e. naphthalene and water)[19][20] to large molecules with tens of atoms (i.e. fullerene with 60 carbon atoms).[21]

Melting and boiling points of metallic, ionic, covalent, and molecular solids.
Type of Solid Material Tm (°C) Tb (°C)
Metallic Iron 1,538[16] 2,861[16]
Ionic Sodium chloride 801[16] 1,465[16]
Covalent Diamond 4,440[16] -
Molecular Argon -189.3[16] -185.9[16]
Molecular Water 0[16] 100[16]
Molecular Naphthalene 80.1[16] 217.9[16]
Molecular Nicotine -79[16] 491[16]
Molecular Caffeine 235.6[16] 519.9[17]

Composition and Structure

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Molecular solids may consist of single atoms, diatomic, and/or polyatomic molecules.[1][2][3][4][5][6][7] The intermolecular interactions between the constituents dictate how the crystal lattice of the material is structured.[22][23][24] All atoms and molecules can partake in van der Waals and London dispersion forces (sterics). It is the lack or presence of other intermolecular interactions based on the atom or molecule that affords materials unique properties.[22]

Van der Waals Forces

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Van der Waals and London dispersion forces guide iodine to condense into a solid at room temperature.[25] (a) A lewis dot structure of iodine and an analogous structure as a spacefill model. Purple balls represent iodine atoms. (b) Demonstration of how van der Waals and London dispersion forces guide the organization of the crystal lattice from 1D to 3D (bulk material).

Argon, is a noble gas that has a full octet, no charge, and is nonpolar.[3][4][7][8] These characteristics make it unfavorable for Argon to partake in metallic, covalent, and ionic bonds as well as most intermolecular interactions.[3][4][7][8] It can though partake in van der Waals and London dispersion forces.[3][4] These weak self-interactions are isotropic and result in the long-range ordering of the atoms into face centered cubic packing when cooled below -189.3.[16] Similarly iodine, a linear diatomic molecule has a net dipole of zero and can only partake in van der Waals interactions that are fairly isotropic.[3][4][7][8] This results in the bipyramidal symmetry.

Dipole-Dipole and Quadrupole Interactions

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The dipole-dipole interactions between the acetone molecules partially guide the organization of the crystal lattice structure.[26] (a) A dipole-dipole interaction between acetone molecules stacked on top of one another. (b) A dipole-dipole interaction between acetone molecules in front and bock of each other in the same plane. (c) A dipole-dipole interaction between acetone molecules flipped in direction, but adjacent to each other in the same plane. (d) Demonstration of how quadrupole-quadrupole interactions are involved in the the crystal lattice structure.

For acetone dipole-dipole interactions are a major driving force behind the structure of its crystal lattice. The negative dipole is caused by oxygen. Oxygen is more electronegative than carbon and hydrogen,[16] causing a partial negative (δ-) and positive charge (δ+) on the oxygen and remainder of the molecule, respectively.[3][5] The δ- orienttowards the δ+ causing the acetone molecules to prefer to align in a few configurations in a δ- to δ+ orientation (pictured left). The dipole-dipole and other intermolecular interactions align to minimize energy in the solid state and determine the crystal lattice structure.

The quadrupole-guadrupole interactions between the naphthalene molecules partially guide the organization of the crystal lattice structure.[27] (a) A lewis dot structure artificially colored to provide a qualitative map of of where the partial charges exist for the quadrupole. A 3D representation of naphthalene molecules and quadrupole. (b) A 3D representation of the quadrupole from two naphthalene molecules interacting. (c) A dipole-dipole interaction between acetone molecules flipped in direction, but adjacent to each other in the same plane. (c) Demonstration of how quadrupole-quadrupole interactions are involved in the the crystal lattice structure.

A quadrupole, like a dipole, is a permanent pole but the electric field of the molecule is not linear as in acetone, but in two dimensions.[28] Examples of molecular solids with quadrupoles are octafluoronaphthalene and naphthalene.[20][28] Naphthalene consists of two joined conjugated rings. The electronegativity of the atoms of this ring system and conjugation cause a ring current resulting in a quadrupole. For naphthalene, this quadrupole manifests in a δ- and δ+ accumulating within and outside the ring system, respectively.[4][5][6][12][28] Naphthalene assembles through the coordination of δ- of one molecules to the δ+ of another molecule.[4][5][6] This results in 1D columns of naphthalene in a herringbone configuration. These columns then stack into 2D layers and then 3D bulk materials. Octafluoronaphthalene follows this path of organization to build bulk material except the δ- and δ+ are on the exterior and interior of the ring system, respectively.[5]

Hydrogen and Halogen Bonding

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The hydrogen bonding between the acetic acid molecules partially guides the organization of the crystal lattice structure.[29] (a) A lewis dot structure with the partial charges and hydrogen bond denoted with blue dashed line. A ball and stick model of acetic acid with hydrogen bond denoted with blue dashed line. (b) Four acetic acid molecules in zig-zag hydrogen bonding in 1D. (c) Demonstration of how hydrogen bonding are involved in the the crystal lattice structure.

A hydrogen bond is a specific dipole where a hydrogen atom has a partial positive charge (δ+) to due a neighboring electronegative atom or functional group.[9][12] Hydrogen bonds are amongst the strong intermolecular interactions know other than ion-dipole interactions.[12] For intermolecular hydrogen bonds the δ+ hydrogen interacts with a δ- on an adjacent molecule. Examples of molecular solids that hydrogen bond are water, amino acids, and acetic acid.[3][5][8][12] For acetic acid, the hydrogen (δ+) on the alcohol moeity of the carboxylic acid hydrogen bonds with other the carbonyl moeity (δ-) of the carboxylic on the adjacent molecule. This hydrogen bond leads a string of acetic acid molecules hydrogen bonding to minimize free energy.[12][29] These strings of acetic acid molecules then stack together to build solids.

The halogen bonding between the bromine and 1,4-dioxane molecules partially guides the organization of the crystal lattice structure.[30] (a) A lewis dot structure and ball and stick model of bromine and 1,4-dioxane. The halogen bond is between the bromine and 1,4-dioxane. (b) Demonstration of how halogen bonding can guide the crystal lattice structure.

A halogen bond is when an electronegative halide participates in a noncovalent interaction with a less electronegative atom on an adjacent molecule.[12][31] Examples of molecular solids that halogen bond are hexachlorobenzene[14][32] and a cocrystal of bromine 1,4-dioxane.[30] For the second example, the δ- bromine atom in the diatomic bromine molecule is aligning with the less electronegative oxygen in the 1,4-dioxane. The oxygen in this case is viewed as δ+ compared to the bromine atom. This coordination results in a chain-like organization that stack into 2D and then 3D.[30]

Coulombic Interactions

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The partial ionic bonding between the TTF and TCNQ molecules partially guides the organization of the crystal lattice structure. The van der Waals interactions of the core for TTF and TCNQ guide adjacent stacked columns.[33] (a) A lewis dot structure and ball and stick model of TTF and TCNQ. The partial ionic bond is between the cyano- and thio- motifs. (b) Demonstration of how van der Waals and partial ionic bonding guide the crystal lattice structure.

A coulombic interaction is a force between two charged particles exert on each other. It is proportional the two charges involved and inversely proportional to the square of the distance between them.[3][4][6][7][8][9] Coulombic interactions are seen in some molecular solids. A well-studied example is the radical ion salt TTF-TCNQ with a conductivity of 5 x 102 Ω-1 cm-1,[5] much closer to copper (ρ = 6 x 105 Ω-1 cm-1)[8] than many molecular solids (e.g. coronene, ρ = 1 x 10-12 to 1 x 10-18 Ω-1 cm-1).[10][13][21][34] The coulombic interaction in TTF-TCNQ stems from the large partial negative charge (δ = -0.59) on the cyano- moeity on TCNQ at room temperature.[5] For reference, a completely charged molecule δ = ±1.[5] This partial negative charge leads to a strong interaction with the thio- moeity of the TTF. The strong interaction leads to favorable alignment of these functional groups adjacent to each other in the solid state.[5][34] While π-π interactions cause the TTF and TCNQ to stack in separate columns.[12][33]

Allotropes

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One form of an element may be a molecular solid, but another form of that same element may not be a molecular solid.[3][4][5] For example, solid phosphorus can crystallize as different allotropes called "white", "red", and "black" phosphorus. White phosphorus forms molecular crystals composed of tetrahedral P4 molecules.[35] Heating at ambient pressure to 250 °C or exposing to sunlight converts white phosphorus to red phosphorus where the P4 tetrahedra are no longer isolated, but connected by covalent bonds into polymer-like chains.[36] Heating white phosphorus under high (GPa) pressures converts it to black phosphorus which has a layered, graphite-like structure.[37][38]

The structural transitions in phosphorus are reversible: upon releasing high pressure, black phosphorus gradually converts into the red phosphorous, and by vaporizing red phosphorus at 490 °C in an inert atmosphere and condensing the vapor, covalent red phosphorus can be transformed into the molecular solid, white phosphorous.[39]

White, red, violet, and black phosphorus samples Structure unit
of white phosphorus
Structures of red violet and black phosphorus

Similarly, yellow arsenic is a molecular solid composed of As4 units; it is metastable and gradually transforms into gray arsenic upon heating or illumination.[40] Some forms of sulfur and selenium are composed of S8 (or Se8) units and are molecular solids at ambient conditions, but converted into covalent allotropes having atomic chains extending throughout the crystal.[41][42]

Properties

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Since molecular solids are held together by relatively weak forces they tend to have low melting and boiling points, low mechanical strength, low electrical conductivity, and poor thermal conductivity.[3][4][5][6][7][8] Also, depending on the structure of the molecule the intermolecular forces may have directionality leading to anisotropy of certain properties.[4][5][8]

Melting and Boiling Points

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The characteristic melting point of metals and ionic solids is ~ 1000 °C and greater, while molecular solids typically melt closer to 300 °C (see table), thus many corresponding substances are either liquid (ice) or gaseous (oxygen) at room temperature.[4][6][7][8][43] This is due to the elements involved, the molecules they form, and the weak intermolecular interactions of the molecules.

Allotropes of phosphorus are useful to further demonstrate this structure-property relationship. White phosphorus, a molecular solid, has a relatively low density of 1.82 g/cm3 and melting point of 44.1 °C; it is a soft material which can be cut with a knife. When it is converted to the covalent red phosphorus, the density goes to 2.2–2.4 g/cm3 and melting point to 590 °C, and when white phosphorus is transformed into the (also covalent) black phosphorus, the density becomes 2.69–3.8 g/cm3 and melting temperature ~200 °C. Both red and black phosphorus forms are significantly harder than white phosphorus.[46]

Mechanical Properties

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Molecular solids can be either ductile or brittle, or a combination depending on the crystal face stressed.[5][14] Both ductile and brittle solids undergo elastic deformation till they reach the yield stress.[8][14] Once the yield stress is reached ductile solids undergo a period of plastic deformation, and eventually fracture. Brittle solids fracture promptly after passing the yield stress.[8][14] Due to the asymmetric structure of most molecules, many molecular solids have directional intermolecular forces.[14] This phenomenon can lead to anisotropic mechanical properties. Typically a molecular solid is ductile when it has directional intermolecular interactions. This allows for dislocation between layers of the crystal much like metals.[5][8][14]

One example of a ductile molecular solid, that can be bent 180°, is hexachlorobenzene (HCB).[14][32] In this example the π-π interactions between the benzene cores are stronger than the halogen interactions of the chlorides. This difference leads to its flexibility.[14][32] This flexibility is anisotropic; to bend HCB to 180° you must stress the [001] face of the crystal.[32] Another example of a flexible molecular solid is 2-(methylthio)nicotinic acid (MTN).[14][32] MTN is flexible due to its strong hydrogen bonding and π-π interactions creating a rigid set of dimers that dislocate along the alignment of their terminal methyls.[32] When stressed on the [010] face this crystal will bend 180°.[32] Note, not all ductile molecular solids bend 180° and some may have more than one bending faces.[32]

Electrical Properties

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Many molecular solids have a large band gap making them insulators.[5][21] For example, coronene has band gap of 2.4 eV.[47] This large band gap (compared to Germanium at 0.7 eV)[8] is due to the discrete nature of the molecules and relatively weak intermolecular interactions.[5][21] These factors result in low charge carrier mobility and thus conductivity.[5][21] There are cases though in which molecular solids can be relatively good conductors: 1) when the molecules partake in ion-radical chemistry and 2) when the solids are doped with atoms, molecules, or materials.[5][21] A well-known example of such an ion radical salt is TTF-TCNQ.[5][10] TTF-TCNQ (ρ = 5 x 102 Ω-1 cm-1)[5] is more conductive than other molecular solids (i.e. coronene, ρ = 1 x 10-12 to 1 x 10-18 Ω-1 cm-1)[13]) because the TCNQ charge donor has such a strong partial negative charge (δ = 0.59)[5] making the intermolecular interactions more coulombic in electronic character.[5] This partial charge increase with decreasing temperature.[5] The coulombic major component of the lattice energy causing the electrical conduction of the crystal to be anisotropic.[5] Fullerenes are an example of how a molecular solid can be doped to become a conductor.[5][21] A solid purely consisting of fullerenes is an insulator because the valence electrons of the carbon atoms are primarily involved in the covalent bonds within the individual carbon molecules. However, inserting (intercalating) alkali metal atoms between the fullerene molecules provides extra electrons, which can be easily ionized from the metal atoms and make the material conductive.[5][21][48]

Thermal Properties

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Molecular solids have many thermal properties: specific heat capacity, thermal expansion, and thermal conductance to name a few.[3][5][6][7][8] These thermal properties are determined by the intra- and intermolecular vibrations of the atoms and molecules of the molecular solid. While transitions of an electron do contribute to thermal properties, their contribution is negligible compared to the vibrational contribution.[5][8]

Examples of molecular solids

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Molecular solids include many pharmaceuticals, at least in their pure form, such as ibuprofen and menthol. Other molecular solids are chalcogens (O2), pnictogens (N2), and various hydrocarbons (CnHm) (i.e. diamondoids and fullerenes).[21][49][50] Pictured below are a range of molecular crystals with images giving molecular level and macro detail on the top and bottom row, respectively.

See also

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References

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  2. ^ a b Lehmann, C. W.; Stowasser, Frank (2007). "The Crystal Structure of Anhydrous Beta-Caffeine as Determined from X-ray Powder-Diffraction Data". Chemistry A European Journal. 10: 2908–2911.
  3. ^ a b c d e f g h i j k l m n Hall, George (1965). Molecular Solid State Physics. Berlin, Germany: Springer-Verlag.
  4. ^ a b c d e f g h i j k l m n o p q r s t Fahlman, B. D. (2011). Materials Chemistry. Berlin, Germany: Springer.
  5. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag ah ai aj Schwoerer, M.; Wolf, H. C. (2007). Organic Molecular Solids. Weinheim, Germany: Wiley-VCH.
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  11. ^ El-Ghayoury, A.; Mézière, C.; Simonov first3=S.; Zorina, L.; Cobián, M.; Canadell, E.; Rovira, C.; Náfrádi, B.; Sipos, B.; Forró, L.; Batail, P. (2010). "A Neutral Zwitterionic Molecular Solid". Chemistry A European Journal. 16: 14051–14059. {{cite journal}}: Missing pipe in: |last3= (help)CS1 maint: numeric names: authors list (link)
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Category:Chemical compounds