Stoichiometry
Definition of Terms
| Atomic Mass | Isotopes | Atomic Weight |
| The Mole | Molecular Weight | Avogadro's Constant |
| Converting Grams Into Moles | ||
Stoichiometry /ˌstɔɪkiˈɒmᵻtri/ is the calculation of relative quantities of reactants and products in chemical reactions.
Stoichiometry is founded on the law of conservation of mass where the total mass of the reactants equals the total mass of the products leading to the insight that the relations among quantities of reactants and products typically form a ratio of positive integers. This means that if the amounts of the separate reactants are known, then the amount of the product can be calculated. Conversely, if one reactant has a known quantity and the quantity of product can be empirically determined, then the amount of the other reactants can also be calculated.
This is illustrated in the image here, where the balanced equation is:
- CH
4 + 2 O
2 → CO
2 + 2 H
2O.
Because of the well known relationship of moles to atomic weights, the ratios that are arrived at by stoichiometry can be used to determine quantities by weight in a reaction described by a balanced equation. This is called composition stoichiometry.
Gas stoichiometry deals with reactions involving gases, where the gases are at a known temperature, pressure, and volume and can be assumed to be ideal gases. For gases, the volume ratio is ideally the same by the ideal gas law, but the mass ratio of a single reaction has to be calculated from the molecular masses of the reactants and products. In practice, due to the existence of isotopes, molar masses are used instead when calculating the mass ratio.
Definition
A stoichiometric amount [1] or stoichiometric ratio of a reagent is the optimum amount or ratio where, assuming that the reaction proceeds to completion:- All of the reagent is consumed
- There is no deficiency of the reagent
- There is no excess of the reagent.
Chemical reactions, as macroscopic unit operations, consist of simply a very large number of elementary reactions, where a single molecule reacts with another molecule. As the reacting molecules (or moieties) consist of a definite set of atoms in an integer ratio, the ratio between reactants in a complete reaction is also in integer ratio. A reaction may consume more than one molecule, and the stoichiometric number counts this number, defined as positive for products (added) and negative for reactants (removed).[2]
Different elements have a different atomic mass, and as collections of single atoms, molecules have a definite molar mass, measured with the unit mole (6.02 × 1023 individual molecules, Avogadro's constant). By definition, carbon-12 has a molar mass of 12 g/mol. Thus, to calculate the stoichiometry by mass, the number of molecules required for each reactant is expressed in moles and multiplied by the molar mass of each to give the mass of each reactant per mole of reaction. The mass ratios can be calculated by dividing each by the total in the whole reaction.
Elements in their natural state are mixtures of isotopes of differing mass, thus atomic masses and thus molar masses are not exactly integers. For instance, instead of an exact 14:3 proportion, 17.04 kg of ammonia consists of 14.01 kg of nitrogen and 3 × 1.01 kg of hydrogen, because natural nitrogen includes a small amount of nitrogen-15, and natural hydrogen includes hydrogen-2 (deuterium).
A stoichiometric reactant is a reactant that is consumed in a reaction, as opposed to a catalytic reactant, which is not consumed in the overall reaction because it reacts in one step and is regenerated in another step.
Converting grams to moles
Stoichiometry is not only used to balance chemical equations but also used in conversions, i.e., converting from grams to moles using molar mass as the conversion factor, or from grams to milliliters using density. For example, to find the amount of NaCl (sodium chloride) in 2.00 g, one would do the following:Molar proportion
Stoichiometry is often used to balance chemical equations (reaction stoichiometry). For example, the two diatomic gases, hydrogen and oxygen, can combine to form a liquid, water, in an exothermic reaction, as described by the following equation:- 2 H
2 + O
2 → 2 H
2O
The molar ratio allows for conversion between moles of one substance and moles of another. For example, in the reaction
- 2 CH
3OH + 3 O
2 → 2 CO
2 + 4 H
2O
3OH is obtained using the molar ratio between CH
3OH and H
2O of 2 to 4.
Determining amount of product
Stoichiometry can also be used to find the quantity of a product yielded by a reaction. If a piece of solid copper (Cu) were added to an aqueous solution of silver nitrate (AgNO3), the silver (Ag) would be replaced in a single displacement reaction forming aqueous copper(II) nitrate (Cu(NO3)2) and solid silver. How much silver is produced if 16.00 grams of Cu is added to the solution of excess silver nitrate?The following steps would be used:
- Write and balance the equation
- Mass to moles: Convert grams of Cu to moles of Cu
- Mole ratio: Convert moles of Cu to moles of Ag produced
- Mole to mass: Convert moles of Ag to grams of Ag produced
- Cu + 2 AgNO
3 → Cu(NO
3)
2 + 2 Ag
Further examples
For propane (C3H8) reacting with oxygen gas (O2), the balanced chemical equation is:- C
3H
8 + 5 O
2 → 3 CO
2 + 4 H
2O
Stoichiometric ratio
Stoichiometry is also used to find the right amount of one reactant to "completely" react with the other reactant in a chemical reaction – that is, the stoichiometric amounts that would result in no leftover reactants when the reaction takes place. An example is shown below using the thermite reaction,- Fe
2O
3 + 2 Al → Al
2O
3 + 2 Fe
Limiting reagent and percent yield
Main articles: Limiting reagent and Yield (chemistry)
The limiting reagent is the reagent that limits the amount of product
that can be formed and is completely consumed when the reaction is
complete. An excess reactant is a reactant that is left over once the
reaction has stopped due to the limiting reactant being exhausted.Consider the equation of roasting lead(II) sulfide (PbS) in oxygen (O2) to produce lead(II) oxide (PbO) and sulfur dioxide (SO2):
- 2 PbS + 3 O
2 → 2 PbO + 2 SO
2
In reality, the actual yield is not the same as the stoichiometrically-calculated theoretical yield. Percent yield, then, is expressed in the following equation:
Example
Consider the following reaction, in which iron(III) chloride reacts with hydrogen sulfide to produce iron(III) sulfide and hydrogen chloride:- 2 FeCl
3 + 3 H
2S → Fe
2S
3 + 6 HCl
To find what mass of excess reagent (H2S) remains after the reaction, we would set up the calculation to find out how much H2S reacts completely with the 90.0 g FeCl3:
Different stoichiometries in competing reactions
Often, more than one reaction is possible given the same starting materials. The reactions may differ in their stoichiometry. For example, the methylation of benzene (C6H6), through a Friedel–Crafts reaction using AlCl3 as a catalyst, may produce singly methylated (C6H5CH3), doubly methylated (C6H4(CH3)2), or still more highly methylated (C6H6−n(CH3)n) products, as shown in the following example,- C6H6 + CH3Cl → C6H5CH3 + HCl
- C6H6 + 2 CH3Cl → C6H4(CH3)2 + 2 HCl
- C6H6 + n CH3Cl → C6H6−n(CH3)n + n HCl
Stoichiometric coefficient
In lay terms, the stoichiometric coefficient (or stoichiometric number in the IUPAC nomenclature[3]) of any given component is the number of molecules that participate in the reaction as written.For example, in the reaction CH4 + 2 O2 → CO2 + 2 H2O, the stoichiometric coefficient of CH4 is −1, the stoichiometric coefficient of O2 is −2, for CO2 it would be +1 and for H2O it is +2.
In more technically precise terms, the stoichiometric coefficient in a chemical reaction system of the ith component is defined as
The extent of reaction ξ can be regarded as [the amount of] a real (or hypothetical) product, one molecule of which produced each time the reaction event occurs. It is the extensive quantity describing the progress of a chemical reaction equal to the number of chemical transformations, as indicated by the reaction equation on a molecular scale, divided by the Avogadro constant (in essence, it is the amount of chemical transformations). The change in the extent of reaction is given by dξ = dnB/νB, where νB is the stoichiometric number of any reaction entity B (reactant or product) and nB is the corresponding amount.[5]The stoichiometric coefficient νi represents the degree to which a chemical species participates in a reaction. The convention is to assign negative coefficients to reactants (which are consumed) and positive ones to products. However, any reaction may be viewed as going in the reverse direction, and all the coefficients then change sign (as does the free energy). Whether a reaction actually will go in the arbitrarily selected forward direction or not depends on the amounts of the substances present at any given time, which determines the kinetics and thermodynamics, i.e., whether equilibrium lies to the right or the left.
In reaction mechanisms, stoichiometric coefficients for each step are always integers, since elementary reactions always involve whole molecules. If one uses a composite representation of an overall reaction, some may be rational fractions. There are often chemical species present that do not participate in a reaction; their stoichiometric coefficients are therefore zero. Any chemical species that is regenerated, such as a catalyst, also has a stoichiometric coefficient of zero.
The simplest possible case is an isomerization
- A → B
There are usually multiple reactions proceeding simultaneously in any natural reaction system, including those in biology. Since any chemical component can participate in several reactions simultaneously, the stoichiometric coefficient of the ith component in the kth reaction is defined as
With complex reaction systems, it is often useful to consider both the representation of a reaction system in terms of the amounts of the chemicals present { Ni } (state variables), and the representation in terms of the actual compositional degrees of freedom, as expressed by the extents of reaction { ξk }. The transformation from a vector expressing the extents to a vector expressing the amounts uses a rectangular matrix whose elements are the stoichiometric coefficients [ νi k ].
The maximum and minimum for any ξk occur whenever the first of the reactants is depleted for the forward reaction; or the first of the "products" is depleted if the reaction as viewed as being pushed in the reverse direction. This is a purely kinematic restriction on the reaction simplex, a hyperplane in composition space, or N‑space, whose dimensionality equals the number of linearly-independent chemical reactions. This is necessarily less than the number of chemical components, since each reaction manifests a relation between at least two chemicals. The accessible region of the hyperplane depends on the amounts of each chemical species actually present, a contingent fact. Different such amounts can even generate different hyperplanes, all sharing the same algebraic stoichiometry.
In accord with the principles of chemical kinetics and thermodynamic equilibrium, every chemical reaction is reversible, at least to some degree, so that each equilibrium point must be an interior point of the simplex. As a consequence, extrema for the ξs will not occur unless an experimental system is prepared with zero initial amounts of some products.
The number of physically-independent reactions can be even greater than the number of chemical components, and depends on the various reaction mechanisms. For example, there may be two (or more) reaction paths for the isomerism above. The reaction may occur by itself, but faster and with different intermediates, in the presence of a catalyst.
The (dimensionless) "units" may be taken to be molecules or moles. Moles are most commonly used, but it is more suggestive to picture incremental chemical reactions in terms of molecules. The Ns and ξs are reduced to molar units by dividing by Avogadro's number. While dimensional mass units may be used, the comments about integers are then no longer applicable.
Stoichiometry matrix
Main article: Chemical reaction network theory
In complex reactions, stoichiometries are often represented in a more
compact form called the stoichiometry matrix. The stoichiometry matrix
is denoted by the symbol N.If a reaction network has n reactions and m participating molecular species then the stoichiometry matrix will have correspondingly m rows and n columns.
For example, consider the system of reactions shown below:
- S1 → S2
- 5 S3 + S2 → 4 S3 + 2 S2
- S3 → S4
- S4 → S5
Often the stoichiometry matrix is combined with the rate vector, v, and the species vector, S to form a compact equation describing the rates of change of the molecular species:
Gas stoichiometry
Gas stoichiometry is the quantitative relationship (ratio) between reactants and products in a chemical reaction with reactions that produce gases. Gas stoichiometry applies when the gases produced are assumed to be ideal, and the temperature, pressure, and volume of the gases are all known. The ideal gas law is used for these calculations. Often, but not always, the standard temperature and pressure (STP) are taken as 0 °C and 1 bar and used as the conditions for gas stoichiometric calculations.Gas stoichiometry calculations solve for the unknown volume or mass of a gaseous product or reactant. For example, if we wanted to calculate the volume of gaseous NO2 produced from the combustion of 100 g of NH3, by the reaction:
- 4 NH
3(g) + 7 O
2(g) → 4 NO
2(g) + 6 H
2O(l)
and
- P = absolute gas pressure
- V = gas volume
- n = amount (measured in moles)
- R = universal ideal gas law constant
- T = absolute gas temperature
- ρ = gas density at T and P
- m = mass of gas
- M = molar mass of gas
Stoichiometric air-to-fuel ratios of common fuels
See also: Air–fuel ratio and Combustion
In the combustion
reaction, oxygen reacts with the fuel, and the point where exactly all
oxygen is consumed and all fuel burned is defined as the stoichiometric
point. With more oxygen (overstoichiometric combustion), some of it
stays unreacted. Likewise, if the combustion is incomplete due to lack
of sufficient oxygen, fuel remains unreacted. (Unreacted fuel may also
remain because of slow combustion or insufficient mixing of fuel and
oxygen – this is not due to stoichiometry). Different hydrocarbon fuels
have different contents of carbon, hydrogen and other elements, thus
their stoichiometry varies.| Fuel | Ratio by mass [6] | Ratio by volume [7] | Percent fuel by mass |
|---|---|---|---|
| Gasoline | 14.7 : 1 | — | 6.8% |
| Natural gas | 17.2 : 1 | 9.7 : 1 | 5.8% |
| Propane (LP) | 15.67 : 1 | 23.9 : 1 | 6.45% |
| Ethanol | 9 : 1 | — | 11.1% |
| Methanol | 6.47 : 1 | — | 15.6% |
| n-Butanol | 11.2 : 1 | — | 8.2% |
| Hydrogen | 34.3 : 1 | 2.39 : 1 | 2.9% |
| Diesel | 14.5 : 1 | — | 6.8% |
| Methane | 17.19 : 1 | 9.52 : 1 | 5.5% |
What is the law of mass conservation?
BalasHapusThe law of conservation of mass or principle of mass conservation states that for any system closed to all transfers of matter and energy, the mass of the system must remain constant over time, as system mass cannot change quantity if it is not added or removed. Hence, the quantity of mass is "conserved" over time
HapusExplain what is meant All reagents consumed There is no shortage of reagentsNo excess reagents?
BalasHapusThe meant is When there is not enough of one reactant in a chemical reaction, the reaction stops abruptly. To figure out the amount of product produced, it must be determined reactant will limit the chemical reaction (the limiting reagent) and which reactant is in excess (the excess reagent). One way of finding the limiting reagent is by calculating the amount of product that can be formed by each reactant; the one that produces less product is the limiting reagent.
HapusWhat is stoichiometric understanding? What are the principles underlying Stoichiometry? How to apply the concept of stoichiometry?
BalasHapusStoichiometry is a subject in chemistry involving the linkage of reactants and products in a chemical reaction to determine the quantity of each reacting agent.
HapusApply the concept of stoichiometry that is by making a cup of delicious coffee, needed a recipe that is 9 cube sugar with 3 spoons of coffee.
This is a fix and patent recipe. So what if we have 12 sugar cubes and three spoons of coffee powder, how many cups of coffee can be made?
Yes! The answer is 1 cup of coffee, with the remaining ingredients 3 cube sugar.
How about we have 27 sugar cube and 8 spoons of coffee. How many cups of coffee can be made?
Of course 2 glasses of coffee with the remaining 9 sugar cube and 2 coffee spoons. All absolutely must follow the recipe.
The key is that all must follow the prescription, if in stoichiometry, the equivalent reaction equation is the recipe, so we must follow the recipe.
How to calculate the number of molecules in the reaction?
BalasHapusWhen you react one carbon atom (C) with one molecule of oxygen (O2) it will form one molecule of CO2. But actually what you react is not a single carbon atom with one molecule of oxygen, but a large number of carbon atoms and a large number of oxygen molecules. Since the number of atoms or the number of molecules that react is so great then to say it, the chemists use "mol" as the unit of the number of particles (molecules, atoms, or ions).
HapusOne mole is defined as the number of substances containing the particles of the substance as much as the atoms present in 12,000 g of carbon atoms -12.
Thus, in one mole of a substance there are 6.022 x 1023 particles. The value of 6.022 x 1023 particles per mole is called the Avogadro constant, with the symbol L or N. In everyday life, the mole can be analogous to "dozen". If it's a dozen
States the number of 12 pieces, the mole states the amount of 6.022 x 10 23 particles of the substance. The word particles in NaCl, H2O, and N2 can be expressed with ions and molecules, whereas in elements like Zn, C, and Al can be expressed with atoms.
Give example Hydrogen as alternative fuel, do you know ???
BalasHapusPlease give an example to balance the chemical equations
BalasHapusCH4 + O2 = CO2 + H2O
HapusA. Set the coefficient CH4 = 1, The other with the letter.
1 CH4 + a O2 = b CO2 + c H20
B. Equivalence of C and H atoms
Atomic Equation C
The number of C atoms on the left side = 1 and on the right-hand side = b, means b = 1
The atomic equivalent of H
The number of H atoms on the left side = 4 and on the right-hand side = 2c, means 2c = 4 or c = 2
With b = 1 and c = 2, the equation of the reaction becomes:
1CH4 + a O2 = 1 CO2 + 2 H20
C. Equalization of atoms O
The number of O atoms on the left-hand side = 2a and on the right-hand side = 2 + 2 = 4 means 2a = 4 or a = 2
Thus the equation is equivalent:
1CH4 + 2 O2 = 1 CO2 + 2 H20
Try to explain the law of definite proportion (ie the law of constant composition), the law of double proportion and the law of mutual proportion?
BalasHapus1. In chemistry, the fixed comparative law, sometimes called Proust law, states that chemical compounds always contain elements of the same mass ratio. This is consistent with the law of constant composition, which states that all chemical compounds have the same elemental composition as their mass. Comparative law remains part of the basic laws of chemistry. Together with the law of multiple comparisons, comparative law still forms the basis of stoichiometry.
Hapus2. the law of double proportion states when two elements form a series of compounds, the mass mass of one element joining a certain mass of the other is an integral ratio to one another.
3. law of mutual proportion states If A and B can form compounds, and each can form compounds with other elements, for example AC and BC, the same mausoleum of element C in both compounds will cause A and B in AC and BC is equal to the ratio of Adan B in compound AB or simple multiple thereof.
avery solution have a volume,and in the reaction have a comparison of mole. what is there relation in the reaction?
BalasHapusHow to get avogadro value?
BalasHapus