Technical articles

NiMH Nickel–Metal Hydride Batteries: A Full View of the MH (Metal Hydride) Negative Electrode—Working Mechanism, Materials Families, and a Selection Map (with Tables 1–2)

In nickel–metal hydride (NiMH) batteries, the “MH” in the name does not mean a hydrogen gas tank, nor a chemical reducing agent. It refers to the metal hydride phase (MH) formed in the negative electrode after charging: hydrogen enters the alloy lattice in atomic form, “resides” in interstitial sites, and then “moves out” during discharge to deliver electrons.

 

Key trade-offs in NiMH—power capability, cycle life, low-temperature performance, and self-discharge—are strongly coupled to the crystal structure and surface behavior of the MH negative electrode. At the materials level, the negative electrode sets the upper bound for reversible hydrogen storage capacity and kinetic performance. However, in sealed-cell designs, the negative electrode is often made with excess capacity to enable oxygen recombination under overcharge and protection under over-discharge. As a result, the usable cell capacity is often jointly constrained by the positive electrode and overall electrode balancing.

 

1.What is a NiMH battery?

1.1 Three core components define a “water-based, sealed, rechargeable” secondary battery

A NiMH battery can be summarized by three functional units: the positive electrode (Ni(OH)/NiOOH), the negative electrode (M/MHₓ hydrogen-storage alloy), and an alkaline electrolyte (often KOH). Sealing and safety” additionally rely on the separator, can/casing, safety vent, and—critically—electrode balancing plus gas recombination design.

 

  • Positive electrode: Ni(OH) / NiOOH nickel electrode (responsible for reversible nickel redox)
  • Negative electrode: hydrogen-storage alloy electrode M / MH (responsible for reversible hydrogen absorption/desorption)
  • Electrolyte: alkaline aqueous solution (typically KOH), providing an ionic-conduction environment

Summary:

  • The “hydrogen” in NiMH is not stored as H gas. It is mainly stored as atomic hydrogen (H, not molecular H) inserted into interstitial lattice sites of the hydrogen-storage alloy, forming a reversible hydrogen-containing phase—abbreviated as MH (metal hydride).
  • The essence of NiMH charging is inserting hydrogen into the alloy (M → MH), and discharging is releasing/de-inserting hydrogen (MH → M) to output electrons.

1.2 Key reactions

In alkaline electrolyte, the reactions are commonly written as:

1. Positive electrode:

Ni(OH) + OH  NiOOH + HO + e

2. Negative electrode:

M + HO + e  MH + OH

3. Overall reaction:

Ni(OH) + M  NiOOH + MH

 

1.3 Why it is called “Ni–MH”

  • Ni” comes from the nickel-based positive electrode system.
  • MH” comes from the metal hydride phase formed in the negative electrode after charging.
  • Because the negative electrode must deliver the core function of reversible solid-state hydrogen storage (M  MH), many of NiMH’s major advantages (high power, safety, abuse tolerance) and key trade-offs (life fade, self-discharge, low-temperature/fast-charge behavior) are strongly correlated with the structure and surface behavior of the hydrogen-storage alloy—although the positive electrode and electrolyte/process conditions also influence final performance.

 

2.What is a metal hydride, and what role does it play in NiMH?

2.1 Materials essence of MH: reversible “site occupancy” of hydrogen in a lattice

In NiMH negative-electrode materials (hydrogen-storage alloys), “metal hydride” typically means that hydrogen enters alloy interstitial sites in atomic form, producing a reversible hydrogen-containing phase. In engineering and materials contexts it is more often written as MHₓ, because x is not a fixed constant—it varies with alloy composition, temperature, and state of charge/discharge.

 

Therefore, evaluating an MH negative-electrode material is not about whether you can write down a neat chemical formula, but whether it can achieve under electrochemical conditions:

  • an appropriate thermodynamic window (hydrogen absorption/desorption equilibrium neither “too tight” nor “too loose”),
  • sufficiently fast kinetics (rapid hydrogen diffusion in the alloy and fast interfacial reaction rates),
  • long-term structural and surface stability (resistance to corrosion/pulverization in strong alkaline electrolyte; impedance should not rise rapidly).

2.2 In NiMH, “MHₓ is the operating state of the negative electrode: charge/discharge via solid-state hydrogen storage

In a NiMH battery, the negative electrode does not “generate and store hydrogen gas.” Instead, it stores and releases energy through reversible hydrogen uptake/release in the solid alloy:

  • Charge: alloy M absorbs hydrogen and transforms to MHₓ (energy stored as hydrogen occupying lattice sites” in the negative electrode)
  • Discharge: MHₓ releases hydrogen back to M while delivering electrons to the external circuit
  • This is paired with the reversible redox of the positive electrode Ni(OH) / NiOOH to complete energy conversion in the full cell.

3.What are NiMH applications?

NiMH, as an aqueous alkaline rechargeable battery, is often chosen not because it has the highest energy density, but because it offers a more robust combination in many scenarios: relatively high power output, long cycle life, and good tolerance to abnormal/abuse conditions (e.g., overcharge, short circuit, overheating, and other off-normal events).

 

3.1 Portable sealed cells (AA/AAA, etc.): everyday replaceable batteries and “grab-and-go” use

The most common NiMH application is rechargeable replaceable batteries in portable devices—typically AA/AAA cylindrical cells (also some small prismatic/button cells and packs built from these cells).

 

Typical devices/scenarios:

  • High current pulses: camera flashes, toys, electric RC devices, some wireless devices (large instantaneous current)
  • Long storage with occasional use: mice, remote controls, clocks, flashlights, etc. (most sensitive to “losing charge while sitting”)

Why NiMH is used in these scenarios (three key reasons):

  • Standardized and replaceable: AA/AAA formats are universal; when depleted or failed, you can directly swap the same format.
  • More stable at medium-to-high rates: compared with primary alkaline batteries, NiMH better sustains high-current discharge without voltage collapsing too quickly (especially noticeable for flash devices).
  • Low self-discharge (LSD / ready-to-use) NiMH: designed for “store long yet still have charge” usage—lower storage loss, usable right off the shelf, while still handling some high-current devices.

 

Note: These portable sealed NiMH cells/packs are standardized under IEC 61951-2, with unified marking, testing, and requirements—making them more standardized, interchangeable, and comparable.

 

3.2 Industrial/high-power and backup-power scenarios: “instant high current” plus high reliability

In industrial and system-level use, NiMH is often valued for high-rate discharge capability and reliability/life, supporting the combined need for “high-power pulses + dependable supply”:

  • Examples include payment terminals, medical tools and devices, wireless terminals, security backup stations, miner’s lamps, and other applications sensitive to power and reliability.
  • Also includes infrastructure/system backup and high-rate discharge cells (using NiMH as one of the solutions for backup power and high-rate discharge).

3.3 Hybrid electric vehicles (HEVs): high power, long life, and abuse tolerance are key drivers

  • The U.S. DOE AFDC summary is clear: NiMH provides “reasonable specific energy and power capabilities,” relatively long cycle life, and is considered safe and abuse-tolerant, so it was widely used in HEVs for many years. AFDC also notes challenges: higher cost, higher self-discharge, heat generation at high temperature, and the need to control hydrogen loss.

4.Materials families and a selection map: how to understand and choose AB₅ / AB₂ / A₂B₇ (superlattice)

4.1 The three mainstream families (structure view): what do AB, AB, and AB represent?

In hydrogen-storage alloys, AB/AB/AB are family labels.

  • A is typically the element group that more strongly determines hydrogen-storage thermodynamics and lattice volume (in NiMH often rare earths La/Ce/Nd/Pr, or Ti/Zr, etc.).
  • B is typically the element group forming the alloy framework and tuning kinetics (Ni is central; commonly doped with Co/Mn/Al/Cr/V, etc.).
  • The subscripts 5, 2, 7 indicate typical atomic ratios (engineering materials can be doped and deviate somewhat, yet still be classified into the same family).

1) AB (the most mature baseline route)

  • Typical representatives: LaNi series, MmNi (mischmetalnickel) series, and formulations tuned by Co/Mn/Al doping on the Ni site.
  • One-sentence takeaway: mature, well-balanced overall, with a wide engineering window—therefore very common in many portable NiMH cells and mature systems.
  • Selection takeaway: AB is often a robust choice for life / consistency / manufacturability (but details still depend on formulation and processing).

2) AB (Laves-phase route: C14/C15 structures are common)

  • Typical representatives: Ti/Zr-based multicomponent alloy systems (often combined with V/Ni/Cr/Mn, etc.), whose main phase often belongs to Laves phases, commonly including C14 and C15 structure types.
  • One-sentence takeaway: large compositional design space; kinetic and rate capability potential is often emphasized—but corrosion resistance and structural stability depend more strongly on materials and electrode engineering.
  • Selection takeaway: C14/C15 are not “new material names,” but different crystal-structure variants under the same AB ratio; they can affect hydrogen diffusion and reaction kinetics, thereby influencing rate and low-temperature performance.

3) AB (superlattice route; often LaMgNi systems)

  • Typical representatives: rare-earth–Mg–Ni systems and doped variants, often classified as “AB / superlattice (essentially more complex stacking/layered structural combinations).
  • One-sentence takeaway: an upgrade route within the NiMH framework toward higher capacity or improved overall performance; frequently viewed in the literature as a promising negative-electrode direction.
  • Selection takeaway: phase composition/stacking structure is often strongly correlated with capacity, retention, and rate; evaluation should focus on a structure–performance evidence chain, not just a single chemical formula.

Summary:

  • AB tends to be the robust, mature baseline route.
  • AB tends to emphasize kinetics/rate potential + higher engineering demands.
  • AB/superlattice tends to be a capacity and overall-performance upgrade route.
  • Consumer cells more often use AB; AB and superlattice (AB/AB-type stacking) appear more frequently in HEV/high-power systems.

4.2 “Selection map” (goal view)

Table 2. Selection Map (Goal-Oriented View)

 

What do you want to optimize first?

More common materials route (empirical map)

Evidence/metrics to prioritize

Risk reminder

Life and stability (cycle retention, corrosion resistance, overall balance)

Often start with AB or mature formulation systems

Capacity fade curves; impedance (EIS) growth; electrode/powder pulverization and corrosion characterization; also consider how electrolyte and additives affect life

High-temperature behavior and self-discharge still require system-level engineering control (materials + electrode + process jointly determine outcomes)

High power/rate and low-temperature output

Often focus on AB (Laves-phase) phase structure and kinetics

High-rate discharge curves; low-temperature power retention; polarization and impedance; and evidence linking C14/C15 phase fraction/structural differences to kinetics

Usually more dependent on corrosion resistance and structural-stability engineering; otherwise, higher rate often comes at the cost of life

Higher capacity (capacity upgrade within the NiMH framework)

Common route: AB / superlattice (La–Mg–Ni, etc.)

Capacity and retention; correspondence between phase composition/stacking structure and electrochemical performance (many papers report “phase composition + performance” side-by-side)

Cost, process window, and long-term stability must be balanced; pay attention to structural consistency across batches

 

5.How does the metal hydride (MH) negative electrode work?

 

Functional role of the MH negative electrode

Materials/electrochemical rationale

Performance metrics directly affected

How to validate with data

Solid-state hydrogen storage: M  MHₓ (reversible site occupancy)

H enters interstitial sites of the alloy lattice in atomic form, forming a reversible hydrogen-containing phase; x varies with SOC/temperature/alloy composition (so MHₓ is more accurate)

Upper limit of usable capacity; plateau/voltage features; and—via electrode balancing—cell-level energy density

Alloy-electrode specific capacity (mAh·g⁻¹), discharge plateau/voltage profiles; interpret cell capacity by combining electrode balancing (positive-limited vs negative-excess)

Provides the main negative-electrode reaction pathway: M + HO + e  MH + OH

This reaction is reversible in alkaline electrolyte and pairs with the positive Ni(OH)/NiOOH reaction to complete the full-cell chemistry

Rate/power capability, polarization, low-temperature performance, efficiency

High-rate discharge curves; polarization (ΔV); EIS/internal resistance; dQ/dV (incremental capacity) to track polarization and reaction-feature changes

Enables sealed-cell operation: the “oxygen recombination / gas-management hub” under overcharge

Near end-of-charge, the positive electrode evolves O; O diffuses to the negative electrode and is reduced/recombined there to suppress pressure buildup. Therefore sealed NiMH typically requires negative-capacity excess to form an overcharge reserve (OCR), and also retains an overdischarge reserve (ODR) to reduce negative-electrode damage during deep discharge

Abuse tolerance (overcharge), pressure control, thermal behavior, cycle life

Overcharge tests: pressure/temperature-rise curves, gas-recombination efficiency; in design, examine OCR/ODR (negative excess) vs failure modes

Co-determines conductivity and operating window with the electrolyte (KOH concentration/additive system)

KOH provides high ionic conductivity; the primary migrating ion is OH (K mainly maintains electroneutrality and migration balance). Engineering practice often balances conductivity, low-temperature freezing point, and corrosion within ~20–36 wt% KOH, with ~30 wt% commonly used as one compromise point; additive strategies (e.g., LiOH/NaOH) may optimize low-temperature and life

Internal resistance, low-temperature power, charge/discharge efficiency

Conductivity/impedance vs concentration; low-temperature capacity and power retention; compare EIS and low-temperature discharge curves across electrolyte formulations

Determines life: corrosion/pulverization resistance, suppressing impedance growth and electrolyte dry-out cascades

A common failure signature is rising impedance. High temperature accelerates electrolyte dry-out and alloy corrosion → pulverization/active loss, and may induce micro-short networks. In many systems, “electrolyte dry-out” is often linked to high-temperature/overcharge venting plus electrode degradation, which elevates impedance and accelerates capacity fade

Cycle life, capacity fade rate, self-discharge/retention

Post-cycling EIS (impedance growth), SEM/cross-section morphology, XRD/phase evolution; correlate with temperature, gas management, and electrolyte loss

 

6.Product Selection Navigation Table | NiMH (Metal Hydride / MH Negative Electrode) Related Chemicals (Tables 1–2)

 

Need / scenario (typical research question)

Which table to check first

Why this table is more suitable

Representative products

You’ve confirmed your research target is the NiMH MH negative-electrode material: evaluate capacity/plateau pressure (voltage plateau), activation rate, cycle fade, etc.

Table 1

Hydrogen-storage active materials & direct metal hydrides

Table 1 concentrates materials that directly store/release hydrogen and are closest to electrode activity (MH alloys and hydrides), ideal for electrochemical and hydrogen-storage benchmarking

Build baseline references: benchmark AB standard reference / flagship material for comparison

Table 1

Hydrogen-storage active materials & direct metal hydrides

Table 1 includes classic references such as La–Ni alloys, helping place a new formulation’s capacity/plateau behavior into a comparable framework

Do “hydride state vs metal state” comparison: for the same element, should you use the metal source or the hydride (activation, hydrogen-release behavior, kinetic differences)?

Table 1 + Table 2 (start with Table 1)

Table 1 provides hydride-state materials (e.g., TiH/ZrH); Table 2 provides metal-state raw materials (e.g., Ti/Zr). You need both to complete the form-factor comparison

TiH, ZrH (hydride state); Ti (metal state), Zr (metal state)

Prepare alloys / modify formulations yourself (melting or mechanical alloying): add Ni/rare-earth/transition metals per recipe and explore compositional windows

Table 2

Alloying-element feedstocks & analytical/process control metals

Table 2 centers on “formulation knobs” and preparation feedstocks: rare-earth site substitution (La/Ce/Pr/Nd), AB tuning (Al/Mn/Co/Ni), AB/Laves routes (Ti/Zr/V/Cr)

Optimize AB (rare-earthNi) systems: examine how rare-earth-site substitution/mischmetal strategies affect plateau pressure, corrosion resistance, and cycling

Table 2

Alloying-element feedstocks & analytical/process control metals

Table 2 groups rare-earth metal sources together, enabling systematic screening of the “rare-earth-site knob”

Work on AB/Laves or Ti–Zr–V–Cr–Ni routes: tune plateau pressure/capacity/kinetics/corrosion via element combinations

Table 2

Alloying-element feedstocks & analytical/process control metals

Common AB/Laves framework + tuning elements (Ti/Zr/V/Cr/Ni) are all in Table 2, convenient for recipe-based batching

Troubleshoot “impurity/purity effects” or reproducibility: suspect cycle fade/self-discharge/activation differences stem from metal-source purity/impurities

Table 2

Alloying-element feedstocks & analytical/process control metals

Table 2 includes high-purity/spectroscopic-grade metal powders, helping separate intrinsic material behavior from impurity effects

You’re doing materials preparation/mechanism validation and need reducing metal powders/process controls or extra variables (not necessarily mainstream formulations)

Table 2

Alloying-element feedstocks & analytical/process control metals

Table 2 also includes process/control metals for methodology validation and boundary-condition exploration

Not sure whether to start from “buy ready-to-test active materials” or “build alloys from elements” (project just starting)

Table 1 first, then Table 2

Use Table 1 to quickly obtain measurable active materials/controls and establish a performance baseline; then move to Table 2 for formulation iteration and mechanism deconvolution

Table 1: baseline materials & hydride controls; Table 2: feedstock library for composition design and preparation iteration

 

Table 1 | Hydrogen-Storage Active Materials & Direct Metal Hydrides (Closer to NiMH MH Negative Electrode / Hydride-State Controls)

 

Category

CAS No.

Aladdin Cat. No.

Product name

Spec / purity

Product features & applications

Hydrogen-storage alloy / negative-electrode active material (MH alloy)

54426-34-5

M476229

Mischmetal–nickel alloy

Hydrogen-storage grade

A typical mischmetal (Mm)–Ni hydrogen-storage alloy family used for NiMH negative electrodes (an engineering-relevant AB-style route). Hydrogen-storage grade is suitable for comparing capacity, plateau behavior, activation rate, and cycling fade.

Hydrogen-storage alloy / negative-electrode active material (AB representative)

12196-72-4

L664992

Lanthanum–nickel alloy

≥99.9% (REO)

La–Ni alloys are commonly used as representative references for AB hydrogen-storage alloys (often serving as a baseline for plateau/capacity/activation in both engineering and research). Directly relevant to MH negative-electrode active-material studies and benchmarking.

Direct metal hydride (H source / activation / hydrogen-storage studies)

7704-98-5

T433831

Titanium dihydride

Hydrogen-storage grade

TiH is a classic metal hydride: can act as a hydrogen source / hydrogen-donor material, used to study hydrogen storage/release behavior, and is often used for activation and hydrogenation-related control experiments in alloy/electrode research (hydrogen-storage grade better matches capacity/kinetic testing).

Direct metal hydride (hydrogen storage / H-donor / activation control)

7704-99-6

Z119050

Zirconium dihydride

≥99.9% metals basis

ZrH is a typical metal hydride for hydrogen storage/release studies and hydrogenation-related controls; it can also serve as a different form comparison vs Zr metal (hydride state vs metal state). High purity benefits mechanistic studies.

Extended hydrogen-storage materials (Mg-based / control)

7439-95-4

M109153

Magnesium powder (explosive)

AR, ≥99.5%

Mg/MgH is a classic high-capacity hydrogen-storage system, more for “hydrogen-storage-material extension/control studies.” It is not commonly the primary material in mainstream commercial NiMH routes, but is often used in research as a control for capacity–kinetics–temperature-window comparisons and composite exploration (note flammability/explosion risk and oxidation).

 

Table 2 | Alloying-Element Feedstocks & Analytical/Process Control Metals (For Recipe Tuning, Melting/Mechanical Alloying, and Mechanistic Controls)

 

Category

CAS No.

Aladdin Cat. No.

Product name

Spec / purity

Product features & applications

AB / rare-earth system alloying element (La site)

7439-91-0

L105396

Lanthanum metal

≥99.9% metals basis

La is a core rare-earth element in AB (RENi) routes: used to prepare/modify hydrogen-storage alloys and establish rare-earth-site change  plateau pressure/capacity/corrosion resistance” comparisons. High-purity La is suitable for alloy preparation and impurity-sensitive studies.

AB / rare-earth system alloying element (Ce site / costperformance trade-off)

7440-45-1

C108772

Cerium metal

≥99.5% metals basis, ingot, 1–10 mm

Ce is often used for rare-earth-site substitution/mischmetal strategies, balancing cost, capacity, kinetics, and cycle stability. Ingot form suits melting-based recipes and engineering-route validation.

AB / rare-earth system alloying element (rare-earth tuning)

7440-10-0

P106105

Praseodymium metal

≥99.9% metals basis, powder

Pr can be used for rare-earth-site substitution/doping comparisons in RE–Ni (AB-style) systems, influencing plateau pressure, kinetics, and cycle stability. Powder form facilitates recipe exploration (note oxidation sensitivity).

AB / rare-earth system alloying element (rare-earth tuning)

7440-00-8

N118646

Neodymium ingot

≥99.9% metals basis, ingot (in mineral oil)

Nd is used for rare-earth-site substitution/doping (a common AB variable) to tune plateau pressure, corrosion resistance, and cycling. Stored in mineral oil indicates it is oxidation/reactivity sensitivehandle quickly with appropriate surface treatment and safety precautions.

Alloying feedstock (AB tuning: plateau pressure/corrosion/capacity)

7429-90-5

A105849

Aluminum powder (explosive)

PureSpectra™, spectroscopic grade, powder

Al is a common AB tuning element to adjust plateau pressure, corrosion resistance/pulverization tendency, and cycling stability. Spectroscopic grade supports impurity-effect exclusion and mechanistic controls (powder safety and oxidation prevention required).

Alloying feedstock (common in AB: rate/corrosion/cycle stability)

7439-96-5

M105836

Manganese powder

PureSpectra™, spectroscopic grade, powder

Mn is commonly used in AB systems to tune absorption/desorption plateau and kinetics, and to influence corrosion resistance and cycling. Spectroscopic grade is suitable for formulation-variable and impurity-sensitivity comparisons (oxidation-prone; store inertly and operate quickly).

Alloying feedstock (Ni source / Ni-based systems)

7440-02-0

N434833

Nickel

PrimorTrace™, ≥99.99% metals basis, powder, <150 μm

Ni is the core metal in MH alloys (especially AB/AB). High-purity Ni powder is suitable as melting/mechanical-alloying feedstock and for correlating purity vs cycle life/self-discharge.

Alloying feedstock (conductivity/catalysis/kinetics tuning)

7440-48-4

C434744

Cobalt

Carbon-coated magnetic material, nanopowder, <50 nm (TEM), ≥99%

Co is often used as an alloying/surface-kinetics tuning element to influence reaction kinetics, conductivity, and cycling stability (a common variable in research formulations). Nano form is more suited for mechanistic/contrast experiments and surface-focused studies.

Alloying feedstock (AB/Laves, Ti-based framework)

7440-32-6

T434731

Titanium

Sheet, thickness 5.0 mm, size 20 × 20 mm, tolerance 0.2

Ti is a key framework element in AB (Laves phase) / TiZrV hydrogen-storage alloys, important for plateau/capacity/kinetics design. Metal sheet is more suitable for melting-based preparation routes (arc/induction melting) and compositional-window exploration.

Alloying feedstock (AB/Laves: Zr-based)

7440-67-7

Z112792

Zirconium powder (explosive)

99.5% metals basis (Hf excluded), ≥200 mesh

Zr is a key element in AB (Laves phase) / TiZrV alloys, affecting capacity, plateau pressure, activation, and kinetics. Powder suits mechanical alloying and rapid recipe screening (powder safety and oxidation prevention required).

Alloying feedstock (AB/Laves: V framework/capacity contribution)

7440-62-2

V434856

Vanadium

≥99.9% metals basis, powder, >100 mesh

V is an important component in AB/Laves and many hydrogen-storage alloys, often used to increase capacity and tune plateau pressure. High-purity V powder suits mechanical alloying/melting recipe development and capacitycycling correlation studies.

Alloying feedstock (AB/Laves: corrosion resistance/plateau tuning)

7440-47-3

C105819

Chromium sheet

≥99.95% metals basis, thickness ~1 mm

Cr is common in AB routes (e.g., Ti/ZrVCrNi) to tune plateau pressure, corrosion resistance, and cycle stability. Sheet form suits melting preparation and compositional-window exploration.

Alloying/process control feedstock (Fe system)

7439-89-6

I116360

Reduced iron powder

Chemical pure (CP), 100 mesh

Fe can serve as a dopant or control element in some hydrogen-storage alloy/structural-material studies; “reduced iron powder” is also used as a process control in reductive or impurity-sensitive systems (Fe is not a typical primary variable in mainstream commercial NiMH formulations).

Analytical/control metal material

7440-31-5

T141462

Tin powder

For elemental analysis

Mostly used for elemental-analysis/method controls (instrument calibration, spiking controls, etc.). If doing trace Sn doping/contrast studies in MH alloy systems, it can also serve as a doping metal source, though this grade is oriented to analytical use.

 

Note: The above are representative Aladdin products. For more specifications, please refer to the product list at the end of the article, or search the Aladdin website by product name/CAS number.

 

Aladdin: https://www.aladdinsci.com/

Categories: Technical articles
Explore topics: NiMH MH Metal Hydride

Da — when not otherwise indicated, molecular weight units are daltons.   Mw — weight-average molecular weight.   Mn — number-average molecular weight.

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Cite this article

Aladdin Scientific. "NiMH Nickel–Metal Hydride Batteries: A Full View of the MH (Metal Hydride) Negative Electrode—Working Mechanism, Materials Families, and a Selection Map (with Tables 1–2)" Aladdin Knowledge Base, updated Jan 21, 2026. https://www.aladdinsci.com/us_en/faqs/nimh-nickel-metal-hydride-batteries-en.html
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