15 Facts About HNO3 + BeCO3: How This Combination Works

The main motive for chemical reactions is to learn about chemical products. Nitric acid is an inorganic compound.Let us discuss some reactions and properties of HNO₃ and BeCO₃.

HNO₃ is a strong electrolyte or acid.It is a strong oxidizing agent that has highly reactive properties. Beryllium carbonate is an anhydrous unstable compound.It is an organic carbonic compound. It is soluble in water and it decomposes easily.

In this article, we will discuss some interesting facts about HNO₃+BeCO₃ like Buffer solution, intermolecular forces, redox reaction, etc.

What is the product of HNO₃ and BeCO₃ ?

HNO₃ and BeCO₃ form beryllium nitrate, carbon dioxide and water molecules.

2HNO₃ +  BeCO₃   →  Be(NO₃)₂  +  CO₂  + H₂O

What type of reaction is HNO₃+ BeCO₃

It is a double displacement reaction.

How to balance HNO₃ + BeCO₃

The unbalanced equation for the reaction HNO₃ + BeCO₃ is

HNO₃  +  BeCO₃   →   Be(NO₃)₂ + CO₂ + H₂O

To balance this equation, we should follow these steps-

• In this reaction, Be and C atoms are the same on both reactant and product sides of the equation.
• The N, H, and O atoms are not equal on both reactant and product sides.
• The number of NO3 atoms, before and after the reaction is 1 and 2, respectively 
• HNO₃  +  BeCO₃   →   Be(NO₃)₂+ CO₂ + H₂O
• So we will multiply HNO3 by 2, so the number of Be atoms becomes the same.
• 2HNO₃  +  BeCO₃   →   Be(NO₃)₂+ CO₂ + H₂O
• Now, the number of H atoms will automatically become equal on both the reactant and product sides.
• Under this condition, the total number of O atom 9 on both side 
• Finally the balanced equation is –
• 2HNO₃  +  BeCO₃ →  Be(NO₃)₂  + CO₂  + H₂O

HNO₃ + BeCO₃ titration

To determine the amount of the insoluble salt BeCO₃ by HNO₃, we have to do titration.  

Apparatus

• Volumetric flask
• Beaker
• Burette
• Conical flask
• Pippate
• Burette stand
• HNO₃ is used as a titrant, whose concentration is known.
• BeCO₃ is used as titre, whose concentration is unknown.

Indicator

Methyl orange is used as an indicator because this titration occurs between strong acid and weak base.

Procedure

• In the very first step weigh the sample of beryllium carbonate and dissolve in water and mix it well in a conical flask.
• Now add this sample into the burette.
• The titrant is taken into the pipette and poured into the conical flask.
• Now add an unknown sample drop wise and add it into the conical flask where this reaction occurs.
• The indicator methyl orange is added to the conical flask.
• And the endpoint occurs when it turns into a red color.
• The above procedure is repeated three times for consistent reading.
• The concentration of this solution is calculated by a₁M₁V₁= a₂M₂V₂, where a is number of moles, M is molarity and V is volume.

HNO₃ + BeCO₃ net ionic equation

The net ionic equation of HNO₃ and BeCO₃ is-

BeCO₃(s) +  2H⁺(aq) + 2NO₃^–(aq)  →  Be⁺²(aq) + 2NO3^–(aq) + CO₂(g) + H₂O(l)

Follow the below-mentioned steps to get a net ionic equation.

• In this reaction HNO₃ and BeCO₃ both are soluble in water as cations and anions

• The complete ionic equation is written as follows.
• Be⁺²(aq) + CO₃^-2(aq) + 2H⁺(aq) + 2NO₃^–(aq)  →  Be⁺²(aq) + 2NO₃^–(aq) + CO₂(g) + H₂O(l)
• In this reaction NO₃^– ion is a spectator ion that is canceled from both sides.
• After canceling the spectator ion from both sides, we get the net ionic equation.
• Thus, the net ionic equation is –
• 2H⁺(aq) + BeCO₃(s)  →  Be⁺²(aq) +CO₂(g) + H₂O

HNO₃ + BeCO₃ conjugate pairs

In HNO₃ and BeCO₃ the following conjugate pairs are available

• The conjugate acid of HNO₃ = NO₃^–
• The conjugate acid of H₂O = OH^–

HNO₃ and BeCO₃ intermolecular forces

HNO₃ and BeCO₃ reaction has following intermolecular forces

• HNO₃ is having dipole-dipole interaction because hydrogen and nitrate ions have differences in interaction. It is also containing London dispersion forces.
• BeCO₃ contains ionic forces and the carbonate ions are nonpolar in nature because it contains trigonal planar structure of the molecule.

HNO₃ + BeCO₃ reaction enthalpy

The enthalpy reaction of HNO₃ and BeCO₃ is around -1357.88 KJ/mole. The calculations using value are listed below.

• The reaction enthalpy is calculated using the formula-
• Reaction enthalpy = ΣΔHf°(products) – ΣΔHf° (reactants)  
• [(-1025) + (-285.8) + (-393.5)] – [2(-173.21)]KJ/mole
• -1357.88 KJ/mole

Is HNO₃ + BeCO₃ a buffer solution

The reaction HNO₃ and BeCO₃ does not produce a buffer solution. Because HNO₃ acts as a strong acid and BeCO₃ acts as base so they are not able to make a buffer solution.

Is HNO₃ + BeCO₃ a complete reaction

HNO₃ and BeCO₃ is a complete reactions because after the formation of Be(NO₃)₂ , CO₂ and H₂O as products there is no further reaction possible.

Is HNO3 + BeCO3 an exothermic or endothermic reaction

The reaction of HNO₃ + BeCO₃ is an exothermic reaction in nature because overall reaction enthalpy is -1357.88KJ/mole, thereby releasing energy in the form of heat.

Is HNO₃ + BeCO₃ a redox reaction

HNO₃ + BeCO₃ is not redox type reactions because the oxidation state of both side reactant and product are similar and the atoms do not change their state.

Is HNO₃ + BeCO₃ a precipitation reaction

The reaction between HNO₃ + BeCO₃ is not a precipitation reaction because beryllium nitrate is soluble in water and this product is present in aqueous medium.

Is HNO₃ + BeCO₃ reversible or irreversible reaction

The reaction of HNO₃ + BeCO₃ is an irreversible reaction because the product Be(NO₃)₂ is soluble in water hence it cannot be reversed back.

Is HNO₃ + BeCO₃ displacement reaction

HNO3 + BeCO3 is a double displacement reaction in which cations and anions both are formed in this reaction, where –

• Be⁺² ions are replaced H⁺ ions in the acid.
• The hydrogen combines with OH ions and forms a water molecule.

Conclusion

Beryllium carbonate forms beryllium nitrite that is toxic in nature and it is a water soluble inorganic compound and it is yellow color solid. It is a chemical reagent that is used in labs and industries. Nitric acid is a strong acid used for strong oxidizing agents.

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