Adsorption

 ( Surface Science ) 

1. All of the adsorption sites are equivalent, and each site can only accommodate one molecule.
2. The surface is energetically homogeneous, and adsorbed molecules do not interact.
3. There are no .
4. At the maximum adsorption, only a monolayer is formed. Adsorption only occurs on localized sites on the surface, not with other adsorbates.

These four assumptions are seldom all true: there are always imperfections on the surface, adsorbed molecules are not necessarily inert, and the mechanism is clearly not the same for the first molecules to adsorb to a surface as for the last. The fourth condition is the most troublesome, as frequently more molecules will adsorb to the monolayer; this problem is addressed by the BET isotherm for relatively flat (non-microporous) surfaces. The Langmuir isotherm is nonetheless the first choice for most models of adsorption and has many applications in surface kinetics (usually called Langmuir–Hinshelwood kinetics) and thermodynamics.

Langmuir suggested that adsorption takes place through this mechanism: $A\_\backslash text\{g\}\; +\; S\; \backslash rightleftharpoons\; AS$, where A is a gas molecule, and S is an adsorption site. The direct and inverse rate constants are k and k₋₁. If we define surface coverage, $\backslash theta$, as the fraction of the adsorption sites occupied, in the equilibrium we have:

$K\; =\; \backslash frac\{k\}\{k\_\{-1\}\}\; =\; \backslash frac\{\backslash theta\}\{(1\; -\; \backslash theta)P\},$

or

$\backslash theta\; =\; \backslash frac\{KP\}\{1\; +\; KP\},$

where $P$ is the partial pressure of the gas or the molar concentration of the solution. For very low pressures $\backslash theta\; \backslash approx\; KP$, and for high pressures $\backslash theta\; \backslash approx\; 1$.

The value of $\backslash theta$ is difficult to measure experimentally; usually, the adsorbate is a gas and the quantity adsorbed is given in moles, grams, or gas volumes at standard temperature and pressure (STP) per gram of adsorbent. If we call v_mon the STP volume of adsorbate required to form a monolayer on the adsorbent (per gram of adsorbent), then $\backslash theta\; =\; \backslash frac\{v\}\{v\_\backslash text\{mon\}\}$, and we obtain an expression for a straight line:

$\backslash frac\{1\}\{v\}\; =\; \backslash frac\{1\}\{Kv\_\backslash text\{mon\}\}\backslash frac\{1\}\{P\}\; +\; \backslash frac\{1\}\{v\_\backslash text\{mon\}\}.$

Through its slope and y intercept we can obtain v_mon and K, which are constants for each adsorbent–adsorbate pair at a given temperature. v_mon is related to the number of adsorption sites through the ideal gas law. If we assume that the number of sites is just the whole area of the solid divided into the cross section of the adsorbate molecules, we can easily calculate the surface area of the adsorbent. The surface area of an adsorbent depends on its structure: the more pores it has, the greater the area, which has a big influence on reactions on surfaces.

If more than one gas adsorbs on the surface, we define $\backslash theta\_E$ as the fraction of empty sites, and we have:

$\backslash theta\_E\; =\; \backslash dfrac\{1\}\{1\; +\; \backslash sum\_\{i=1\}^n\; K\_i\; P\_i\}.$

Also, we can define $\backslash theta\_j$ as the fraction of the sites occupied by the j-th gas:

$\backslash theta\_j\; =\; \backslash dfrac\{K\_j\; P\_j\}\{1\; +\; \backslash sum\_\{i=1\}^n\; K\_i\; P\_i\},$

where i is each one of the gases that adsorb.

Note:

1) To choose between the Langmuir and Freundlich equations, the enthalpies of adsorption must be investigated.Burke GM, Wurster DE, Buraphacheep V, Berg MJ, Veng-Pedersen P, Schottelius DD. Model selection for the adsorption of phenobarbital by activated charcoal. Pharm Res. 1991;8(2):228-231. doi:10.1023/a:1015800322286 While the Langmuir model assumes that the energy of adsorption remains constant with surface occupancy, the Freundlich equation is derived with the assumption that the heat of adsorption continually decrease as the binding sites are occupied.Physical Chemistry of Surfaces. Arthur W. Adamson. Interscience (Wiley), New York 6th ed The choice of the model based on best fitting of the data is a common misconception.

2) The use of the linearized form of the Langmuir model is no longer common practice. Advances in computational power allowed for nonlinear regression to be performed quickly and with higher confidence since no data transformation is required.

A_(g) + S ⇌ AS,

A_(g) + AS ⇌ A₂S,

A_(g) + A₂S ⇌ A₃S and so on.

The derivation of the formula is more complicated than Langmuir's (see links for complete derivation). We obtain:

$\backslash frac\{x\}\{v(1\; -\; x)\}\; =\; \backslash frac\{1\}\{v\_\backslash text\{mon\}c\}\; +\; \backslash frac\{x(c\; -\; 1)\}\{v\_\backslash text\{mon\}c\},$

where x is the pressure divided by the vapor pressure for the adsorbate at that temperature (usually denoted $P/P\_0$), v is the STP volume of adsorbed adsorbate, v_mon is the STP volume of the amount of adsorbate required to form a monolayer, and c is the equilibrium constant K we used in Langmuir isotherm multiplied by the vapor pressure of the adsorbate. The key assumption used in deriving the BET equation that the successive heats of adsorption for all layers except the first are equal to the heat of condensation of the adsorbate.

The Langmuir isotherm is usually better for chemisorption, and the BET isotherm works better for physisorption for non-microporous surfaces.

These factors were included as part of a single constant termed a "sticking coefficient", k_E, described below:

$k\_\backslash text\{E\}\; =\; \backslash frac\{S\_\backslash text\{E\}\}\{k\_\backslash text\{ES\}\; S\_\backslash text\{D\}\}.$

As S_D is dictated by factors that are taken into account by the Langmuir model, S_D can be assumed to be the adsorption rate constant. However, the rate constant for the Kisliuk model ( R') is different from that of the Langmuir model, as R' is used to represent the impact of diffusion on monolayer formation and is proportional to the square root of the system's diffusion coefficient. The Kisliuk adsorption isotherm is written as follows, where θ_{( t)} is fractional coverage of the adsorbent with adsorbate, and t is immersion time:

$\backslash frac\{d\backslash theta\_\{(t)\}\}\{dt\}\; =\; R\text{'}(1\; -\; \backslash theta)(1\; +\; k\_\backslash text\{E\}\backslash theta).$

Solving for θ_{( t)} yields:

$\backslash theta\_\{(t)\}\; =\; \backslash frac\{1\; -\; e^\{-R\text{'}(1\; +\; k\_\backslash text\{E\})t\}\}\{1\; +\; k\_\backslash text\{E\}\; e^\{-R\text{'}(1\; +\; k\_\backslash text\{E\})t\}\}.$

$\backslash left(\; \backslash frac\{\backslash partial\; \backslash ln\; K\}\{\backslash partial\; \backslash frac\{1\}\{T\}\}\; \backslash right)\_\backslash theta\; =\; -\backslash frac\{\backslash Delta\; H\}\{R\}.$

As can be seen in the formula, the variation of K must be isosteric, that is, at constant coverage. If we start from the BET isotherm and assume that the entropy change is the same for liquefaction and adsorption, we obtain

$\backslash Delta\; H\_\backslash text\{ads\}\; =\; \backslash Delta\; H\_\backslash text\{liq\}\; -\; RT\backslash ln\; c,$

$\backslash Gamma=\; 2AC\backslash sqrt\{\backslash frac\{Dt\}\{\backslash pi\}\}$

where $A$ is the surface area (unit m²), $C$ is the number concentration of the molecule in the bulk solution (unit #/m³), $D$ is the diffusion constant (unit m²/s), and $t$ is time (unit s). Further simulations and analysis of this equation show that the square root dependence on the time is originated from the decrease of the concentrations near the surface under ideal adsorption conditions. Also, this equation only works for the beginning of the adsorption when a well-behaved concentration gradient forms near the surface. Correction on the reduction of the adsorption area and slowing down of the concentration gradient evolution have to be considered over a longer time. Under real experimental conditions, the flow and the small adsorption area always make the adsorption rate faster than what this equation predicted, and the energy barrier will either accelerate this rate by surface attraction or slow it down by surface repulsion. Thus, the prediction from this equation is often a few to several orders of magnitude away from the experimental results. Under special cases, such as a very small adsorption area on a large surface, and under chemical equilibrium when there is no concentration gradience near the surface, this equation becomes useful to predict the adsorption rate with debatable special care to determine a specific value of $t$ in a particular measurement.

The desorption of a molecule from the surface depends on the binding energy of the molecule to the surface and the temperature. The typical overall adsorption rate is thus often a combined result of the adsorption and desorption.

$\backslash theta=(\backslash chi-\backslash chi\_c)U(\backslash chi-\backslash chi\_c)$

where U is the unit step function. The definitions of the other symbols is as follows:

$\backslash theta:=n\_\backslash text\{ads\}/n\_m\; ,\backslash quad\; \backslash chi\; :=\; -\backslash ln\backslash bigl(-\backslash ln\backslash bigl(P/P\_\backslash text\{vap\}\backslash bigr)\backslash bigr)$

where "ads" stands for "adsorbed", "m" stands for "monolayer equivalence" and "vap" is reference to the vapor pressure of the liquid adsorptive at the same temperature as the solid sample. The unit function creates the definition of the molar energy of adsorption for the first adsorbed molecule by:

$\backslash chi\_c\; =:-\backslash ln\backslash bigl(-E\_a/RT\backslash bigr)$

The plot of $n\_\{ads\}$ adsorbed versus $\backslash chi$ is referred to as the chi plot. For flat surfaces, the slope of the chi plot yields the surface area. Empirically, this plot was noticed as being a very good fit to the isotherm by Michael Polanyi and also by Jan Hendrik de Boer and Cornelis Zwikker but not pursued. This was due to criticism in the former case by Albert Einstein and in the latter case by Brunauer. This flat surface equation may be used as a "standard curve" in the normal tradition of comparison curves, with the exception that the porous sample's early portion of the plot of $n\_\{ads\}$ versus $\backslash chi$ acts as a self-standard. Ultramicroporous, microporous and mesoporous conditions may be analyzed using this technique. Typical standard deviations for full isotherm fits including porous samples are less than 2%.

Notice that in this description of physical adsorption, the entropy of adsorption is consistent with the Dubinin thermodynamic criterion, that is the entropy of adsorption from the liquid state to the adsorbed state is approximately zero.

• Oxygen-containing compounds – Are typically hydrophilic and polar, including materials such as silica gel, limestone (calcium carbonate) and .
• Carbon-based compounds – Are typically hydrophobic and non-polar, including materials such as activated carbon and graphite.
• Polymer-based compounds – Are polar or non-polar, depending on the functional groups in the polymer matrix.

Silica is used for drying of process air (e.g. oxygen, natural gas) and adsorption of heavy (polar) hydrocarbons from natural gas.

They are manufactured by hydrothermal synthesis of sodium aluminosilicate or another silica source in an autoclave followed by ion exchange with certain cations (Na⁺, Li⁺, Ca²⁺, K⁺, NH₄⁺). The channel diameter of zeolite cages usually ranges from 2 to 9 angstrom. The ion exchange process is followed by drying of the crystals, which can be pelletized with a binder to form macroporous pellets.

Zeolites are applied in drying of process air, CO₂ removal from natural gas, CO removal from reforming gas, air separation, catalytic cracking, and catalytic synthesis and reforming.

Non-polar (siliceous) zeolites are synthesized from aluminum-free silica sources or by dealumination of aluminum-containing zeolites. The dealumination process is done by treating the zeolite with steam at elevated temperatures, typically greater than . This high temperature heat treatment breaks the aluminum-oxygen bonds and the aluminum atom is expelled from the zeolite framework.

Activated carbon is a highly porous, amorphous solid consisting of microcrystallites with a graphite lattice, usually prepared in small pellets or a powder. It is non-polar and cheap. One of its main drawbacks is that it reacts with oxygen at moderate temperatures (over 300 °C).

Activated carbon can be manufactured from carbonaceous material, including coal (bituminous, subbituminous, and lignite), peat, wood, or nutshells (e.g., coconut). The manufacturing process consists of two phases, carbonization and activation.Spessato, L. et al. KOH-super activated carbon from biomass waste: Insights into the paracetamol adsorption mechanism and thermal regeneration cycles. Journal of Hazardous Materials, Vol. 371, Pages 499-505, 2019.Spessato, L. et al. Optimization of Sibipiruna activated carbon preparation by simplex-centroid mixture design for simultaneous adsorption of rhodamine B and metformin. Journal of Hazardous Materials, Vol. 411, Page 125166, 2021. The carbonization process includes drying and then heating to separate by-products, including tars and other hydrocarbons from the raw material, as well as to drive off any gases generated. The process is completed by heating the material over in an oxygen-free atmosphere that cannot support combustion. The carbonized particles are then "activated" by exposing them to an oxidizing agent, usually steam or carbon dioxide at high temperature. This agent burns off the pore blocking structures created during the carbonization phase and so, they develop a porous, three-dimensional graphite lattice structure. The size of the pores developed during activation is a function of the time that they spend in this stage. Longer exposure times result in larger pore sizes. The most popular aqueous phase carbons are bituminous based because of their hardness, abrasion resistance, pore size distribution, and low cost, but their effectiveness needs to be tested in each application to determine the optimal product.

Activated carbon is used for adsorption of organic substances and non-polar adsorbates and it is also usually used for waste gas (and waste water) treatment. It is the most widely used adsorbent since most of its chemical (e.g. surface groups) and physical properties (e.g. pore size distribution and surface area) can be tuned according to what is needed. Its usefulness also derives from its large micropore (and sometimes mesopore) volume and the resulting high surface area. Recent research works reported activated carbon as an effective agent to adsorb cationic species of toxic metals from multi-pollutant systems and also proposed possible adsorption mechanisms with supporting evidences.

In sorption enhanced water gas shift (SEWGS) technology a pre-combustion carbon capture process, based on solid adsorption, is combined with the water gas shift reaction (WGS) in order to produce a high pressure hydrogen stream. The CO₂ stream produced can be stored or used for other industrial processes.

Although there are similarities between adsorption chillers and absorption refrigeration, the former is based on the interaction between gases and solids. The adsorption chamber of the chiller is filled with a solid material (for example zeolite, silica gel, alumina, active carbon or certain types of metal salts), which in its neutral state has adsorbed the refrigerant. When heated, the solid desorbs (releases) refrigerant vapour, which subsequently is cooled and liquefied. This liquid refrigerant then provides a cooling effect at the evaporator from its enthalpy of vaporization. In the final stage the refrigerant vapour is (re)adsorbed into the solid.