Hydrophobe

 ( Chemical Properties ) 

In chemistry, hydrophobicity is the chemical property of a molecule (called a hydrophobe) that is seemingly repelled from a mass of water.

In contrast, are attracted to water.

Hydrophobic molecules tend to be nonpolar and, thus, prefer other neutral molecules and nonpolar . Because water molecules are polar, hydrophobes do not dissolve well among them. Hydrophobic molecules in water often cluster together, forming . Water on hydrophobic surfaces will exhibit a high contact angle.

Examples of hydrophobic include the , , , and greasy substances in general. Hydrophobic materials are used for oil removal from water, the management of , and chemical separation processes to remove non-polar substances from polar compounds.

The term hydrophobic—which comes from the Ancient Greek ὑδρόφοβος (), "having a fear of water", constructed Liddell, H.G. & Scott, R. (1940). A Greek-English Lexicon. revised and augmented throughout by Sir Henry Stuart Jones. with the assistance of. Roderick McKenzie. Oxford: Clarendon Press.—is often used interchangeably with lipophilic, "fat-loving". However, the two terms are not synonymous. While hydrophobic substances are usually lipophilic, there are exceptions, such as the silicones and .

---

Physicochemical basis For small solutes, the hydrophobic interaction is mostly an entropy effect originating from the disruption of the highly dynamic between molecules of liquid water by the nonpolar solute, causing the water to compensate by forming a clathrate-like cage structure around the non-polar molecules. This structure is more highly ordered than free water molecules due to the water molecules arranging themselves to interact as much as possible with themselves, and thus results in a lower entropic state at the interface. This causes non-polar molecules to clump together to reduce the surface area exposed to water and thereby increase the entropy of the system.

(2012). 9781133106296, Cengage Learning. ISBN 9781133106296

Thus, the two immiscible phases (hydrophilic vs. hydrophobic) will change so that their corresponding interfacial area will be minimal. This effect can be visualized in the phenomenon called phase separation.

For larger nonpolar solutes that cannot be adequately "clathrated" by the hydrogen-bond network of water, the disruption of these bonds becomes inevitable, leading to a high enthalpic cost. Under ambient conditions, this transition from an entropy-dominated regime to one governed by enthalpy occurs at around ~1 nm in size, reflecting a shift in hydration free energy behavior from scaling with the solute volume to depending on the exposed surface area. Patel AJ et al., Proc. Natl. Acad. Sci. U.S.A. /ref> Rajamani S et al., Proc. Natl. Acad. Sci. U.S.A. /ref>

In this context, a quantitative molecular definition of hydrophobicity has been proposed, based on the energetic cost for a system to induce hydrogen-bond defects in its hydration shell. According to this approach, a system is considered hydrophobic if it cannot compensate for the missing hydrogen bonds with an energy at least as favorable as the cost of generating such a defect in pure water, a value known as the Defect Interaction Threshold (DIT), estimated at approximately −6 kJ/mol (around 30% of the typical energy of a hydrogen bond). This criterion coincides with the classical 90° contact angle threshold, thus providing a molecular justification for the transition to hydrophobic behavior. Loubet NA, Verde AR & Appignanesi GA, J. Chem. Phys. /ref> Accordino SR, Menendez CA, Loubet NA, Alarcon LM & Appignanesi GA, J. Phys.: Condens. Matter /ref>

Additionally, the DIT helps determine the regimes of filling, partial filling, and drying in nanoconfined water, depending on how many of the water molecule's interaction sites (among its four tetrahedral sites) exceed this threshold. This analysis for quantifying hydrophobicity or wetting can be performed using a structural indicator, the V_4S index, which reveals the existence of two inherently preferential interaction states for water. Loubet NA, Verde AR & Appignanesi GA, J. Chem. Phys. /ref>

---

See also

• Wetting – discusses how hydrophobicity affects spreading and contact angles
• Contact angle – classical macroscopic measure linked to hydrophobicity via the DIT molecular criterion

---

Superhydrophobicity Superhydrophobic surfaces, such as the leaves of the lotus plant, are those that are extremely difficult to wet. The of a water droplet exceeds 150°. This is referred to as the lotus effect, and is primarily a physical property related to interfacial tension, rather than a chemical property.

---

Theory In 1805, Thomas Young defined the contact angle θ by analyzing the forces acting on a fluid droplet resting on a solid surface surrounded by a gas.

$\backslash gamma\_\backslash text\{SG\}\backslash \; =\backslash gamma\_\backslash text\{SL\}+\backslash gamma\_\backslash text\{LG\}\backslash cos\backslash theta\; \backslash ,$

where

$\backslash gamma\_\backslash text\{SG\}\backslash$ = Interfacial tension between the solid and gas

$\backslash gamma\_\backslash text\{SL\}\backslash$ = Interfacial tension between the solid and liquid

$\backslash gamma\_\backslash text\{LG\}\backslash$ = Interfacial tension between the liquid and gas

θ can be measured using a contact angle goniometer.

Wenzel determined that when the liquid is in intimate contact with a microstructured surface, θ will change to θ_W*

$\backslash cos\backslash theta\_W*\; =\; r\; \backslash cos\backslash theta\; \backslash ,$

where r is the ratio of the actual area to the projected area. Wenzel's equation shows that microstructuring a surface amplifies the natural tendency of the surface. A hydrophobic surface (one that has an original contact angle greater than 90°) becomes more hydrophobic when microstructured – its new contact angle becomes greater than the original. However, a hydrophilic surface (one that has an original contact angle less than 90°) becomes more hydrophilic when microstructured – its new contact angle becomes less than the original.

Cassie and Baxter found that if the liquid is suspended on the tops of microstructures, θ will change to θ_CB*:

$\backslash cos\backslash theta\_\backslash text\{CB\}*\; =\; \backslash varphi(\backslash cos\backslash theta\; +\; 1)\; -\; 1\; \backslash ,$

where φ is the area fraction of the solid that touches the liquid. Liquid in the Cassie–Baxter state is more mobile than in the Wenzel state.

We can predict whether the Wenzel or Cassie–Baxter state should exist by calculating the new contact angle with both equations. By a minimization of free energy argument, the relation that predicted the smaller new contact angle is the state most likely to exist. Stated in mathematical terms, for the Cassie–Baxter state to exist, the following inequality must be true.

A recent alternative criterion for the Cassie–Baxter state asserts that the Cassie–Baxter state exists when the following 2 criteria are met:1) Contact line forces overcome body forces of unsupported droplet weight and 2) The microstructures are tall enough to prevent the liquid that bridges microstructures from touching the base of the microstructures.

A new criterion for the switch between Wenzel and Cassie-Baxter states has been developed recently based on surface roughness and surface energy. The criterion focuses on the air-trapping capability under liquid droplets on rough surfaces, which could tell whether Wenzel's model or Cassie-Baxter's model should be used for certain combination of surface roughness and energy.

Contact angle is a measure of static hydrophobicity, and contact angle hysteresis and slide angle are dynamic measures. Contact angle hysteresis is a phenomenon that characterizes surface heterogeneity. When a pipette injects a liquid onto a solid, the liquid will form some contact angle. As the pipette injects more liquid, the droplet will increase in volume, the contact angle will increase, but its three-phase boundary will remain stationary until it suddenly advances outward. The contact angle the droplet had immediately before advancing outward is termed the advancing contact angle. The receding contact angle is now measured by pumping the liquid back out of the droplet. The droplet will decrease in volume, the contact angle will decrease, but its three-phase boundary will remain stationary until it suddenly recedes inward. The contact angle the droplet had immediately before receding inward is termed the receding contact angle. The difference between advancing and receding contact angles is termed contact angle hysteresis and can be used to characterize surface heterogeneity, roughness, and mobility. Surfaces that are not homogeneous will have domains that impede motion of the contact line. The slide angle is another dynamic measure of hydrophobicity and is measured by depositing a droplet on a surface and tilting the surface until the droplet begins to slide. In general, liquids in the Cassie–Baxter state exhibit lower slide angles and contact angle hysteresis than those in the Wenzel state.

---

Research and development Dettre and Johnson discovered in 1964 that the superhydrophobic lotus effect phenomenon was related to rough hydrophobic surfaces, and they developed a theoretical model based on experiments with glass beads coated with paraffin or TFE telomer. The self-cleaning property of superhydrophobic micro-nanotechnology surfaces was reported in 1977.

(1977). 9783515026208 ISBN 9783515026208

Perfluoroalkyl, perfluoropolyether, and RF plasma -formed superhydrophobic materials were developed, used for electrowetting and commercialized for bio-medical applications between 1986 and 1995. Other technology and applications have emerged since the mid-1990s. A durable superhydrophobic hierarchical composition, applied in one or two steps, was disclosed in 2002 comprising nano-sized particles ≤ 100 nanometers overlaying a surface having micrometer-sized features or particles ≤ 100 micrometers. The larger particles were observed to protect the smaller particles from mechanical abrasion.

In recent research, superhydrophobicity has been reported by allowing alkylketene dimer (AKD) to solidify into a nanostructured fractal surface. Many papers have since presented fabrication methods for producing superhydrophobic surfaces including particle deposition, sol-gel techniques, plasma treatments, vapor deposition, and casting techniques. Current opportunity for research impact lies mainly in fundamental research and practical manufacturing. Debates have recently emerged concerning the applicability of the Wenzel and Cassie–Baxter models. In an experiment designed to challenge the surface energy perspective of the Wenzel and Cassie–Baxter model and promote a contact line perspective, water drops were placed on a smooth hydrophobic spot in a rough hydrophobic field, a rough hydrophobic spot in a smooth hydrophobic field, and a hydrophilic spot in a hydrophobic field. Experiments showed that the surface chemistry and geometry at the contact line affected the contact angle and contact angle hysteresis, but the surface area inside the contact line had no effect. An argument that increased jaggedness in the contact line enhances droplet mobility has also been proposed.

Many hydrophobic materials found in nature rely on Cassie's law and are biphasic on the submicrometer level with one component air. The lotus effect is based on this principle. Biomimetics, many functional superhydrophobic surfaces have been prepared.

An example of a bionics or biomimetics superhydrophobic material in nanotechnology is nanopin film.

One study presents a vanadium pentoxide surface that switches reversibly between superhydrophobicity and superhydrophilicity under the influence of UV radiation. According to the study, any surface can be modified to this effect by application of a suspension of rose-like V₂O₅ particles, for instance with an inkjet printer. Once again hydrophobicity is induced by interlaminar air pockets (separated by 2.1 nanometer distances). The UV effect is also explained. UV light creates electron-hole pairs, with the holes reacting with lattice oxygen, creating surface oxygen vacancies, while the electrons reduce V⁵⁺ to V³⁺. The oxygen vacancies are met by water, and it is this water absorbency by the vanadium surface that makes it hydrophilic. By extended storage in the dark, water is replaced by oxygen and hydrophilicity is once again lost.

A significant majority of hydrophobic surfaces have their hydrophobic properties imparted by structural or chemical modification of a surface of a bulk material, through either coatings or surface treatments. That is to say, the presence of molecular species (usually organic) or structural features results in high contact angles of water. In recent years, rare earth oxides have been shown to possess intrinsic hydrophobicity. Tribonet: Rare earth oxides make water repellent surfaces that last The intrinsic hydrophobicity of rare earth oxides depends on surface orientation and oxygen vacancy levels, and is naturally more robust than coatings or surface treatments, having potential applications in condensers and catalysts that can operate at high temperatures or corrosive environments.

---

Applications and potential applications Hydrophobic concrete has been produced since the mid-20th century.

Active recent research on superhydrophobic materials might eventually lead to more industrial applications.

A simple routine of coating cotton fabric with silica or titanium dioxide particles by sol-gel technique has been reported, which protects the fabric from UV light and makes it superhydrophobic.

An efficient routine has been reported for making polyethylene superhydrophobic and thus self-cleaning. 99% of dirt on such a surface is easily washed away.

Patterned superhydrophobic surfaces also have promise for lab-on-a-chip microfluidic devices and can drastically improve surface-based bioanalysis.

In pharmaceuticals, hydrophobicity of pharmaceutical blends affects important quality attributes of final products, such as drug dissolution and hardness. Methods have been developed to measure the hydrophobicity of pharmaceutical materials.

The development of hydrophobic passive daytime radiative cooling (PDRC) surfaces, whose effectiveness at solar reflectance and thermal emittance is predicated on their cleanliness, has improved the "self-cleaning" of these surfaces. Scalable and sustainable hydrophobic PDRCs that avoid VOCs have further been developed.

---

See also

---

External links

• What are superhydrophobic surfaces?

Post Comment