Question

In nonaqueous solvents, it is possible to react HF to create \(\mathrm{H}_{2} \mathrm{~F}^{+} .\) Which of these statements follows from this observation? (a) HF can act like a strong acid in nonaqueous solvents, (b) HF can act like a base in nonaqueous solvents, (c) HF is thermodynamically unstable, \((\mathbf{d})\) There is an acid in the nonaqueous medium that is a stronger acid than HE.

Short answer

Statements (a) and (d) are correct: HF acts as a strong acid in nonaqueous solvents, and there's a stronger acid present.

Step-by-step solution

Analyze Reaction Formation

Consider the chemical reaction: \ \[ \mathrm{2HF \rightarrow H_{2}F^{+} + F^{-}} \]. \ This reaction shows that HF can give a proton \( H^+ \) to another HF molecule, forming \( \mathrm{H_2F^+} \). This implies HF behaves like an acid, donating protons in the process.

Examine Role of HF

Since HF donates a proton to form \( \mathrm{H_2F^+} \), it acts as an acid, not as a base. An acid is a substance that can donate protons, while a base accepts them. Therefore, the statement that HF can act as a base is not supported.

Evaluate Statement about Nonaqueous Solvents

In nonaqueous solvents, substances that can donate protons readily, like HF in this case, may act as strong acids. The formation of \( \mathrm{H_2F^+} \) shows that HF can ionize strongly in these solvents, suggesting it behaves like a strong acid.

Consider Thermodynamic Stability

The thermodynamic stability of HF itself isn't directly assessed from its ability to form \( \mathrm{H_2F^+} \). Instead, the reaction formation indicates the acid strength in a medium rather than its stability.

Analyze the Presence of Stronger Acids

The creation of \( \mathrm{H_2F^+} \) hints that there is another entity in the medium acting effectively to allow the ionization, suggesting the presence of a stronger acid in the nonaqueous solvent to facilitate this.

Key concepts

Acid-Base Reactions

Acid-base reactions are fundamental in chemistry as they involve the transfer of protons between substances. In a typical acid-base reaction, an acid will donate a proton while a base will accept that proton. This interchange is crucial because it determines the reactivity and interaction of chemical species.
When discussing nonaqueous solvents, the behavior of acids and bases may differ from their behavior in water. This is evident in the exercise concerning HF. HF, or hydrogen fluoride, acts differently in nonaqueous environments than it might in water. Instead of behaving as a weak acid as in water, HF can display strong acid characteristics due to the nature of the solvent and the ability of HF molecules to interact with one another.
This unique reaction in nonaqueous solvents opens up possibilities for various applications and reactions that are not typically feasible in aqueous solutions. Understanding how the interchange of protons occurs in different mediums enhances our comprehension of chemical reactivity and equilibrium in diverse environments.

Proton Donation

Proton donation is a defining characteristic of acids. According to the Brønsted-Lowry theory, an acid is defined as a substance that can donate a proton ( H^+ ). This concept is crucial in understanding the behavior of HF in nonaqueous solvents.
In the exercise example, HF is shown to donate a proton to another HF molecule, resulting in the formation of H_2F^+ and F^- . This shows not just the capability of HF to donate protons, but also its role in establishing a medium where dynamic proton exchange is possible. This process underlines the importance of inter-molecular interactions in facilitating such proton transfers.
Proton donation is not only a matter of intrinsic properties of the acid but also is influenced by the solvent environment, which can enhance or hinder the acid's ability to donate protons. This adaptability is what makes chemistry in nonaqueous environments intriguing and diverse.

Acid Strength Analysis

Analyzing acid strength involves evaluating how readily an acid donates its protons in a given environment. In nonaqueous solvents, this property may differ significantly from those in aqueous solutions due to the absence of water acting both as a solvent and a participant in proton transfer.
The exercise demonstrates that in a nonaqueous medium, HF can ionize completely, forming H_2F^+ ions, which suggests a higher acid strength. This behavior contrasts with water, where HF shows weak acidic behavior.
It is important to note that the presence of another acid in the medium can also play a crucial role in the expression of acid strength. A stronger acid present may facilitate the ionization of a weaker acid like HF by attracting its protons more effectively. Thus, acid strength is not solely an intrinsic property but is influenced by the surrounding chemical environment.

• Intrinsic properties of acids
• Environmental impact on acidity
• Role of stronger acids in nonaqueous solvents

Understanding these concepts enable chemists to predict and manipulate reactions effectively across various media, leading to innovations in synthetic and industrial chemistry.