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Hydrides — Ionic, Covalent, and Metallic

Hydrogen: Hydrides — Ionic, Covalent, and Metallic

Hydrides — Ionic, Covalent, and Metallic

Hydrogen — Hydrides: Ionic, Covalent, and Metallic

What you'll learn

  • Classify hydrides into ionic, covalent, and metallic (interstitial) types with examples
  • Explain why ionic hydrides contain H⁻ and act as strong reducing agents
  • Compare covalent hydrides of p-block elements and explain their volatile, molecular nature
  • Describe metallic/interstitial hydrides and their non-stoichiometric compositions
  • Analyse bond angle trends (NH₃ > H₂O > H₂S) using lone pair repulsion and electronegativity
  • Compare reducing character trends in Group 16 and Group 17 hydrides

Key concepts

Level 1 — Foundations

Classification of Hydrides

TypeFormed byExamplesKey Feature
Ionic (saline)s-block metals (Groups 1, 2)NaH, CaH₂, LiHContains H⁻ (hydride ion); high mp; salt-like
Covalent (molecular)p-block elementsCH₄, NH₃, H₂O, HFMolecular; volatile; low bp
Metallic (interstitial)d-block & f-block metalsPdH₀.₆, TiH₁.₇, LaH₂.₈₇Non-stoichiometric; H in metal lattice interstices

Ionic Hydrides

  • Formed when s-block metals (Na, K, Ca, Ba, etc.) react with H₂: 2Na+H22NaH2\text{Na} + \text{H}_2 \rightarrow 2\text{NaH} Ca+H2CaH2\text{Ca} + \text{H}_2 \rightarrow \text{CaH}_2

  • Contain H⁻ (hydride ion) — hydrogen has gained one electron

  • High melting points (ionic lattice): NaH mp = 800°C

  • React violently with water → H₂ gas evolved: NaH+H2ONaOH+H2\text{NaH} + \text{H}_2\text{O} \rightarrow \text{NaOH} + \text{H}_2 \uparrow

  • Strong reducing agents (H⁻ donates electrons easily): LiAlH4 (lithium aluminium hydride) — used in organic chemistry to reduce aldehydes, ketones\text{LiAlH}_4 \text{ (lithium aluminium hydride) — used in organic chemistry to reduce aldehydes, ketones}

  • BeH₂ and MgH₂ are exceptions — they have polymeric covalent character due to high charge density of Be²⁺/Mg²⁺

Covalent Hydrides

  • p-block elements (Groups 14–17) form molecular hydrides
  • Properties depend on electronegativity and lone pairs:
GroupExamplesTrend in bpReason
14CH₄ < SiH₄ < GeH₄ < SnH₄IncreasesVan der Waals forces ↑ with mass
15NH₃ >> PH₃ < AsH₃ < SbH₃NH₃ anomalously highH-bonding in NH₃
16H₂O >> H₂S < H₂Se < H₂TeH₂O anomalously highH-bonding in H₂O
17HF >> HCl < HBr < HIHF anomalously highH-bonding in HF

Metallic/Interstitial Hydrides

  • d-block metals absorb H₂ into their crystal lattice (interstitial positions)
  • Non-stoichiometric: composition varies — PdH₀.₆, TiH₁.₇
  • Metallic lustre and conductivity retained
  • Useful for hydrogen storage (hydrogen economy)
  • Pd can absorb up to 900× its own volume of H₂
  • Note: Group 7 and 8 metals (Mn, Fe, Co, Ni) do NOT readily form hydrides — this is the "hydride gap"

Bond Angle Trends in Hydrides

MoleculeBond AngleLone Pairs on Central Atom
NH₃107°1
H₂O104.5°2
PH₃93.3°1
H₂S92.1°2

NH₃ (107°) > H₂O (104.5°): Water has 2 lone pairs vs NH₃'s 1 lone pair → greater lp–lp repulsion compresses bond angle further in H₂O.

NH₃ (107°) >> PH₃ (93.3°): P is larger and less electronegative → P–H bonding pairs are more diffuse and farther from P → less bp–bp repulsion → smaller bond angle.

Level 2 — JEE Depth

Why Bond Angles Decrease: Lone Pair Repulsion + Electronegativity

VSEPR predicts repulsion order: lp–lp > lp–bp > bp–bp

For NH₃ vs PH₃:

  • N is small and highly electronegative (3.0) → bond pairs held close to N → strong bp–bp repulsion → angle = 107°
  • P is larger and less electronegative (2.1) → bond pairs drawn towards H → less bp–bp repulsion → angle = 93.3°

The s-character of the lone pair also matters (Bent's Rule): with lower electronegativity of central atom, lone pair occupies orbital with more s-character (more stable), pushing bond pairs into orbitals with more p-character → smaller angles.

For H₂O vs H₂S:

  • O (electronegativity 3.5, small) → 2 lp close to O → bond angle = 104.5°
  • S (electronegativity 2.5, large) → 2 lp more diffuse → bp drawn to H → angle = 92.1°

Reducing Character of Hydrides

Group 16 (H₂O < H₂S < H₂Se < H₂Te):

Reducing character increases down the group. The E–H bond strength decreases down the group (O–H > S–H > Se–H > Te–H) — weaker bonds are easier to break → easier to lose H (or electrons) → stronger reducing agent.

Bond energies: O–H (459 kJ/mol) > S–H (363 kJ/mol) > Se–H (276 kJ/mol) > Te–H (238 kJ/mol)\text{Bond energies: O–H (459 kJ/mol) > S–H (363 kJ/mol) > Se–H (276 kJ/mol) > Te–H (238 kJ/mol)}

H₂O is the weakest reducing agent (O–H bond very strong). H₂Te is the strongest.

Group 17 (HF < HCl < HBr < HI):

Similarly, reducing character increases HF < HCl < HBr < HI: Bond energies: H–F (569 kJ/mol) > H–Cl (431 kJ/mol) > H–Br (364 kJ/mol) > H–I (297 kJ/mol)\text{Bond energies: H–F (569 kJ/mol) > H–Cl (431 kJ/mol) > H–Br (364 kJ/mol) > H–I (297 kJ/mol)}

HI is the strongest reducing agent among hydrogen halides — it reduces H₂SO₄ to H₂S: 8HI+H2SO4H2S+4I2+4H2O8\text{HI} + \text{H}_2\text{SO}_4 \rightarrow \text{H}_2\text{S} + 4\text{I}_2 + 4\text{H}_2\text{O}

HCl reduces H₂SO₄ only to SO₂: 2HCl+H2SO4SO2+Cl2+2H2O2\text{HCl} + \text{H}_2\text{SO}_4 \rightarrow \text{SO}_2 + \text{Cl}_2 + 2\text{H}_2\text{O}

Polymeric Structure of BeH₂ and AlH₃

BeH₂ is not ionic (Be²⁺ has too high charge density — polarises H⁻ to become H). Instead, it forms a polymeric chain:

  • Each Be bridges two H atoms through 3-centre 2-electron (3c-2e) bonds
  • Similar to electron-deficient boron compounds

...Be–H–Be–H–Be–H...\text{...Be–H–Be–H–Be–H...} (polymeric chain with bridging H atoms)(\text{polymeric chain with bridging H atoms})

This is why BeH₂ and MgH₂ behave more like covalent polymers despite being Group 2 hydrides.

Palladium Hydride — Hydrogen Storage

Pd+xH2PdH2x(x0.3 at room temp, up to 0.6 under pressure)\text{Pd} + x\text{H}_2 \rightarrow \text{PdH}_{2x} \quad (x \approx 0.3 \text{ at room temp, up to } 0.6 \text{ under pressure})

H atoms occupy octahedral interstitial sites in the FCC Pd lattice. The process is reversible — Pd releases H₂ on heating. This is the basis of Pd-membrane hydrogen purification and solid-state hydrogen storage research.

Worked example

Example 1: Classify the following as ionic, covalent, or metallic hydrides and give one distinguishing property of each: (a) NaH (b) SiH₄ (c) TiH₁.₇ (d) CaH₂

(a) NaH — IONIC HYDRIDE
  - Na is a Group 1 alkali metal (s-block)
  - Contains H⁻ ion; Na⁺H⁻
  - High melting point (~800°C); reacts with water to give H₂
  - Strong reducing agent

(b) SiH₄ (Silane) — COVALENT HYDRIDE
  - Si is a Group 14 p-block element
  - Molecular; covalent Si–H bonds
  - Volatile gas (bp = −112°C); no ionic character
  - Used in semiconductor deposition (CVD)

(c) TiH₁.₇ — METALLIC/INTERSTITIAL HYDRIDE
  - Ti is a d-block (transition) metal
  - Non-stoichiometric (1.7 ≠ simple integer)
  - H atoms trapped in Ti crystal lattice interstitially
  - Retains metallic properties (lustre, conductivity)

(d) CaH₂ — IONIC HYDRIDE
  - Ca is a Group 2 alkaline earth metal (s-block)
  - Contains Ca²⁺ and 2H⁻
  - Reacts vigorously with water: CaH₂ + 2H₂O → Ca(OH)₂ + 2H₂↑
  - Used as a drying agent and H₂ source

Example 2: PH₃ has a bond angle of 93.3° while NH₃ has 107°. Explain. Also predict the bond angle of AsH₃ and justify whether it will be greater than, equal to, or less than PH₃.

NH₃ vs PH₃:
  Both have 1 lone pair and 3 bond pairs on the central atom.
  Ideal tetrahedral angle = 109.5°; lone pair compresses this.

  N: small atom, high electronegativity (3.0)
  → bond pairs held close to N → strong bp–bp repulsion
  → bond angle = 107° (close to tetrahedral)

  P: larger atom, lower electronegativity (2.1)
  → bond pairs pulled towards H, away from P
  → reduced bp–bp repulsion near P
  → bond angle = 93.3° (close to 90°, approaching p-orbital geometry)

AsH₃:
  As is below P in Group 15; even larger, even less electronegative (2.0)
  → bond pairs even more displaced towards H
  → bp–bp repulsion near As even smaller
  → bond angle < 93.3°

  Experimental: AsH₃ bond angle = 91.8° ✓ (less than PH₃)

Conclusion: Bond angles in Group 15 hydrides: NH₃ (107°) > PH₃ (93.3°) > AsH₃ (91.8°) > SbH₃ (91.3°)

Common mistakes

MistakeWhy it happensFix
Calling all Group 2 hydrides ionicBeH₂ looks like it should be ionicBeH₂ and MgH₂ are polymeric covalent due to high charge density of Be²⁺/Mg²⁺ polarising H⁻
Saying reducing character increases up the group (hydrides)Confusing with metallic character trendFor hydrides, reducing character INCREASES DOWN the group (weaker E–H bond → easier oxidation)
Thinking metallic hydrides are stoichiometricMetal hydrides look like MH or MH₂ in formulaeMetallic hydrides are non-stoichiometric — PdH₀.₆, TiH₁.₇ — H fills interstitial sites randomly
Confusing bond angle in H₂O with that in H₂SBoth have 2 lone pairs so angles "should be equal"H₂O = 104.5°, H₂S = 92.1° — S is larger with less electronegative bonds; lone pairs are more diffuse

Quick check

  • Q1: Write the reaction of CaH₂ with water. What type of hydride is it and what is the role of CaH₂ in this reaction?
  • Q2: Arrange Group 17 hydrides in order of increasing reducing power: HCl, HBr, HI, HF.
  • Q3: Why is PdH₀.₆ considered a non-stoichiometric compound?
  • Q4: Explain why H₂O has a larger bond angle than H₂S despite both having 2 lone pairs on the central atom.
  • Stretch: Q5: LiH, NaH, KH are ionic hydrides. Yet BeH₂ and MgH₂, despite being Group 2 compounds, are NOT truly ionic. Explain using polarisation/Fajans' rules. Also explain why LiH is more covalent than NaH by the same argument. Predict which is a stronger reducing agent: LiAlH₄ or NaBH₄, giving a reason based on hydride ion donor ability.

NCERT Chapter 9 link: Hydrogen — Section 9.6 (Hydrides — Types and Properties), Section 9.4 (Properties of Hydrogen)

Exam connections: JEE Mains tests classification of hydrides and bond angle trends regularly. JEE Advanced asks mechanistic explanations for reducing character trends with thermochemical justification. NEET: type identification and water/ammonia comparison. Board: classification table with examples and properties.

Study strategy: Draw a 3-column classification table first (ionic/covalent/metallic), fill in examples from s-, p-, d-blocks. Then separately memorise bond angle trends as two rows: Group 15 (NH₃ > PH₃ > AsH₃) and Group 16 (H₂O > H₂S). Link reducing character to bond energy — lower bond energy = stronger reducer.

Interactive Exploration Suggestions (Drishti Live Worlds)

  • Hydride Classification Sorter: Drag-and-drop element cards into ionic/covalent/metallic buckets; system checks classification; reveals ionic radius, electronegativity, and group number as hints if stuck.
  • Bond Angle Explorer: 3D VSEPR model builder — add lone pairs one at a time to central atom and observe bond angle compression; compare NH₃, PH₃, H₂O, H₂S side by side with numerical angle display.
  • Reducing Power Ladder: Interactive electrochemical series for hydrides; add reducing agents one by one; observe which can reduce H₂SO₄ to SO₂ vs H₂S; connect to bond energy data.

AI Mentor Prompts (Socratic, Board-Adaptive)

  • "NaH reacts with water to give H₂ gas. In this reaction, is the H in NaH being oxidised or reduced? Track the oxidation state of H from NaH to H₂ to H₂O. Can you tell me what NaH's role is?"
  • "If I give you a mystery hydride with a non-integer formula like MH₁.₄, what type of hydride is it? What does a non-integer ratio tell you about how hydrogen is incorporated into the structure?"
  • "Group 17 hydrides: HF has the strongest bond yet it's the weakest reducing agent — HI has the weakest bond but strongest reducer. This seems backwards from what you might expect about 'strong bonds = stable compound = poor reducer.' Can you reconcile this — is stability the same as reducing power?"

Gamification, Portfolio & Parent Visibility

  • Complete the core practice + one extension activity (photo, table, short reflection, or mini-project) for base XP + topic badge.
  • 5-7 day streak or family discussion note = multiplier + visible artifact in parent/principal dashboard.
  • Best real-world application stories (anonymised) featured on class or national leaderboard.

Robotics, STEM & Future Skills Bridges

  • Hydrogen storage for green energy: Metallic hydrides (TiFeH, LaNi₅H₆) are candidate materials for solid-state hydrogen storage tanks in hydrogen fuel cell vehicles — engineers balance H₂ absorption capacity, weight, and desorption temperature to design practical tanks.
  • NaBH₄ in portable power: Sodium borohydride (NaBH₄) releases H₂ on contact with water catalytically — this compact hydride system powers portable fuel cells for drones and military electronics; chemists optimise the catalyst to control H₂ release rate.
  • LiAlH₄ in pharmaceutical synthesis: Ionic hydride H⁻ from LiAlH₄ is a nucleophile that reduces C=O, C=N, NO₂ groups — used industrially to manufacture drugs like ibuprofen and antihistamines; understanding H⁻ as a nucleophile bridges inorganic hydride chemistry to organic synthesis.

NEP 2020 & Full Education OS Alignment

This material emphasises experiential "learning by doing", competency (apply/create/analyse), vocational exposure, critical thinking, and multidisciplinary connections. Designed to feed live worlds, AI Mentor (with memory), gamification, robotics, parent analytics, and future skills — not just exam prep.

Portfolio Evidence Idea: Your photo/table/reflection/project + one sentence on "How this helps me in real life or a possible future path."

Open the Practice tab for aligned questions (easy/medium/hard + case-based) with full AI scaffolding.

See curriculum for cross-links and the full future-skills/robotics chapters.

Key Takeaways (TL;DR)

  • What you'll learn
  • Key concepts
  • Worked example
  • Common mistakes

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