Answer: A newly discovered amino acid could act as a buffer at pH values within the range of its two ionizable forms, pk1 and pk2.
The newly discovered amino acid can act as a buffer within the pH range between its two ionizable forms. An amino acid contains two functional groups; the amino group (-NH2) and the carboxyl group (-COOH).
These two groups of atoms, being acidic and basic respectively, behave like a weak acid and a weak base. Consequently, the amino acid solution can function as a buffer at the pH value equal to the sum of the two pKa values.
The pKa of the amino group is known as pk1, and the pKa of the carboxyl group is known as pk2. The pKa of an acid is the pH at which half the acid is ionized and half is not. In other words, pKa is a measure of the acidity of an acid. The lower the pKa, the stronger the acid is.
When the pH is equal to the pKa value of the amino acid, the concentration of acid and conjugate base will be the same. When the pH is one unit higher than the pKa value, the proportion of basic form increases by tenfold compared to the acidic form.
When the pH is one unit lower than the pKa value, the concentration of acidic form is tenfold greater than the concentration of basic form.
Therefore, a newly discovered amino acid could act as a buffer at pH values within the range of its two ionizable forms, pk1 and pk2.
The pH range over which buffering is most effective is between pk1 and pk2. The pKa values of an amino acid will determine the range of pH values over which it can act as a buffer.
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the amount of kinetic energy required to strain the chemical bonds in substrates so they can achieve the transition state is the definition of ?
The amount of kinetic energy required to strain the chemical bonds in substrates so they can achieve the transition state is the definition of activation energy.
What is Activation Energy?
Activation energy is the amount of energy required for a chemical reaction to occur. The energy that must be provided to molecules in order for them to react with one another is known as activation energy.
This can be accomplished in a variety of ways, such as by increasing the temperature or pressure, adding a catalyst, or irradiating the reactants with light.
Activation energy is defined as the energy required for the reaction to begin. It's the energy that molecules require to overcome the initial barrier so that a reaction may proceed.
When a chemical reaction occurs, the reactants must collide with one another with sufficient force and in the appropriate orientation to form products.
It's critical to note that activation energy is a form of potential energy that isn't included in the overall energy change of a reaction.
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it is found that, when equilibrium is reached at a certain temperature, hi is 40. percent dissociated. calculate the equilibrium constant kc for the reaction at this temperature.
The equilibrium constant (Kc) is the ratio of the concentration of the products to the reactants at equilibrium. The value of Kc changes with the temperature but is constant at a given temperature.
The expression for the equilibrium constant Kc can be defined as follows:-
Kc = [C]^c[D]^d/[A]^a[B]^b
where [ ] denotes the molar concentration of the respective species. a, b, c, and d are the coefficients of the balanced chemical equation for the species A, B, C, and D.
If a chemical reaction is at equilibrium at a given temperature, the concentration of reactants and products remains constant over time. In other words, the rate of the forward reaction and the rate of the reverse reaction is equal.
The reaction for which we need to find the equilibrium constant is:-
HI(g) ↔ H(g) + I(g)
Now, assume that initially there were 'x' moles of HI in the reaction mixture. After the dissociation of HI, the concentration of H and I will be equal to 'x - y' moles. The concentration of HI will be equal to 'x - y' moles.
Here, y is the number of moles of HI that dissociated. According to the given statement, HI is 40% dissociated. Therefore, the number of moles of HI that dissociated will be 0.4x. Similarly, the number of moles of H and I that will be formed will also be 0.4x.
The equation for the dissociation of HI can be written as:-
HI(g) ↔ H(g) + I(g)
The initial number of moles = x Moles dissociated = 0.4x
At equilibrium, the number of moles of HI = x - 0.4x = 0.6x
Number of moles of H = 0.4x
Number of moles of I = 0.4x
Finally, substitute these values in the expression for the equilibrium constant:-
Kc = [H][I]/[HI]
Kc = (0.4x)(0.4x)/(0.6x)²
Kc = 0.16/0.36Kc = 0.4444 (approximately)
Therefore, the equilibrium constant Kc for the given reaction is 0.4444 (approximately).
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