Are LR44 and 357 Batteries the Same? No, LR44 and 357 batteries are not the same, even though they share identical dimensions.
LR44 uses alkaline chemistry, while 357 is a silver-oxide cell. This small difference in composition results in meaningful variations in voltage stability, lifespan, and performance under load.
This article explains those technical differences in a clear and structured way—covering performance specs, compatibility, real-world use cases, and when it’s worth choosing one over the other.
What Are LR44 and 357 Batteries?
At first glance, LR44 and 357 batteries look identical. Both are small, round button cells with the same dimensions—11.6 mm in diameter and 5.4 mm in height—which means they are mechanically interchangeable in most devices. But under the hood, they’re fundamentally different power sources designed for different performance expectations.
| Specification | LR44 | 357 / SR44 |
|---|---|---|
| Chemistry | Alkaline (Zn/MnO₂) | Silver-oxide (Zn/Ag₂O) |
| Nominal Voltage | 1.5 V | 1.55 V |
| Typical Capacity | 90 – 175 mAh | 150 – 200 mAh |
| Shelf Life | 2–3 years | 4–5 years |
| Weight | 1.8 – 2.4 g | ~2.3 g |
| Common Aliases | A76, AG13, L1154 | SR44, SR44W, 303, 1131SO |
The key distinction lies in their chemical composition. LR44 batteries use an alkaline chemistry system zinc–manganese dioxide, which is known for being cost-effective and high in energy density—but less consistent in voltage output and long-term stability.
The 357 battery, on the other hand, is based on a silver-oxide chemistry zinc–silver oxide, delivering higher and more stable voltage, longer lifespan, and superior reliability in precision applications.
While they share the same size, they are not electrically identical, and this distinction becomes critical depending on the performance demands of your device.
LR44 vs 357 Batteries: Chemistry and Voltage Differences Explained
The chemistry of a battery is more than just an academic detail—it directly shapes its real-world performance. In the case of LR44 and 357 batteries, the core difference in electrochemical composition is what drives all the meaningful contrasts in voltage stability, usable capacity, and application suitability.
Voltage and Stability
Though the nominal voltage of LR44 is 1.5 V and 357 is 1.55 V, the real significance lies in how that voltage holds up under load. LR44’s alkaline chemistry tends to deliver a declining voltage curve—the output begins dropping from the moment the battery is in use.
This means that for devices requiring consistent voltage to function properly, the LR44 can quickly fall below the minimum required threshold, leading to reduced performance or premature shutdown.
By contrast, the silver-oxide chemistry of the 357 battery offers a much flatter discharge curve, keeping the voltage near 1.55 V for the majority of the battery’s life cycle. This is especially critical for precision instruments, such as calipers, medical devices, and high-sensitivity sensors, where stable voltage translates directly to accurate performance.
The 0.05 V difference may seem negligible—but in voltage-sensitive electronics, it’s the difference between smooth operation and signal drift.
Capacity and Load Consistency
Reported capacity for LR44 batteries varies significantly, typically ranging from 90 to 175 mAh, depending on the manufacturer and test conditions. This wide range highlights a key limitation of alkaline batteries: performance inconsistency under varying loads.
357 batteries, on the other hand, offer a more reliable capacity range—generally between 150 and 200 mAh. Silver-oxide chemistry inherently delivers better load handling efficiency, meaning its real-world capacity under actual working conditions remains closer to what’s advertised.
| Parameter | LR44 (Alkaline) | 357 (Silver-oxide) |
|---|---|---|
| Voltage Drop Rate | Gradual and early | Stable until near depletion |
| Effective Capacity Consistency | Highly variable | More predictable |
| Performance Under Load | Degrades with usage | Maintains accuracy |
because they fit doesn’t mean they function the same. Don’t let identical size fool you into choosing the wrong battery for the job.
Capacity & Lifespan: LR44 vs 357 Battery Performance
Operational runtime: how long before the lights go out?
Under the most common IEC test (6.8 kΩ @ 21 °C, continuous drain), the numbers speak for themselves:
| Metric | LR44 | 357 |
|---|---|---|
| Typical Capacity Range | 90–175 mAh | 150–200 mAh |
| Life under Load (6.8 kΩ) | ~600 h | ~730 h |
| Voltage Stability | Drops early | Low; chemistry resists leakage & oxidation |
That extra 130 hours of usable life is what keeps calipers in-spec, glucometers accurate an d production fixtures online between PM cycles.
Shelf life: how long can they sit on the parts rack?
| Storage, 20 °C | LR44 | 357 |
|---|---|---|
| Manufacturer rating | 3 – 5 years | 5 – 10 years |
| Self-discharge traits | Moderate; electrolyte dries & leaks faster | Low; chemistry resists leakage & oxidation |
Silver-oxide’s laid-back self-discharge lets you buy in volume without worrying that half the carton will expire before deployment.
What really shortens battery life?
Load profile – high pulse currents or heavy continuous drain nibble away at alkaline capacity faster than at silver-oxide.
Duty cycle – devices that “sleep” most of the day stretch battery life; ones that poll or transmit frequently don’t.
Temperature – every 10 °C rise roughly doubles self-discharge; silver-oxide handles heat a tad better.
If your device’s firmware sleeps at 3 µA but wakes to 15 mA radio bursts, spec the 357. Its internal resistance stays lower for longer, so those pulses don’t crater the voltage rail.
Load performance & application suitability
| Application tier | Power profile | Recommended cell | Why it matters |
|---|---|---|---|
| Precision / mission-critical (medical sensors, torque wrenches, micrometer calipers) |
Low average, high accuracy; must hold ≥ 1.3 V | 357 / SR44 | Flat voltage curve prevents drift, guarantees spec compliance |
| Everyday consumer gadgets (digital thermometers, basic calculators, LED toys) |
Low drain, tolerant of sag | LR44 | Cheapest run-time per cent; performance loss is acceptable |
| Mixed-load wearables (multi-function watches, small cameras) |
Steady trickle + pulse spikes | 357 | Handles spikes without rebooting MCU or dimming display |
| Disposable promo items | Single-use, brief life | LR44 | Keeps BOM razor-thin |
Cost, convenience & sustainability in one equation
Fewer swaps: A 357 often lasts 30 %–100 % longer, so techs open sealed compartments half as often.
Lower waste: Longer-lived cells mean fewer tossed buttons—good optics for ISO 14001 audits.
Total-cost-of-ownership: When you fold in labor, downtime and scrap, that $1.50 premium per 357 is a bargain.
Engineering takeaway: Fit is not the same as function. If the spec sheet calls for a 357, don’t “economize” with an LR44—your calibration lab (and your warranty budget) will thank you.
LR44 vs 357: Are They Interchangeable in All Devices?
Physically—yes. Functionally—not always.
LR44 and 357 batteries are the same size (11.6 mm × 5.4 mm), so they are mechanically interchangeable. But their chemistry, voltage stability, and performance under load differ—sometimes dramatically.
When can they be swapped?
357 → LR44? ✔️ Usually okay in low-power, non-critical devices.
LR44 → 357? ✔️ Yes, and often recommended.
| Device Type | Use LR44? | Use 357? | Best Choice |
|---|---|---|---|
| Medical devices / sensors | ✖️ | ✔️ | 357 |
| Digital calipers / instruments | ⚠️ | ✔️ | 357 |
| LED lights / toys / remotes | ✔️ | ✔️ | LR44 |
| Watches (digital or analog) | ✔️ | ✔️ | Depends |
357 batteries deliver higher capacity, longer lifespan, and stable voltage output, making them more reliable—especially in precision electronics like calipers, medical tools, or advanced watches.
LR44s, by contrast, work fine in basic calculators, toys, or LED gadgets, where slight voltage drops or shorter runtimes are acceptable.
LR44 vs 357 Battery Alternatives and Cross-Reference Chart
Battery naming conventions vary widely across regions and manufacturers, but understanding which models are equivalent can prevent confusion and sourcing delays.
Alkaline-LR44 Equivalents:
| IEC Code | ANSI Code | Common Names |
|---|---|---|
| LR1154 | 1166A | LR44, A76, AG13, L1154, G13, KA76, GP76A, 357A, RW82, V13GA |
Silver-Oxide -357 / SR44 Equivalents:
| IEC Code | ANSI Code | Common Names |
|---|---|---|
| LR1154 | 1166A | LR44, A76, AG13, L1154, G13, KA76, GP76A, 357A, RW82, V13GA |
Both LR44 and 357 have numerous alternative names, especially depending on whether you're sourcing from the U.S., EU, Japan, or China.
Conclusion
While LR44 and 357 batteries may look the same, they are built for different purposes. 357 (silver-oxide) offers superior voltage stability, longer lifespan, and higher capacity—making it the better choice for precision and mission-critical applications. LR44 (alkaline) remains a practical, cost-effective option for non-critical, consumer-grade devices. Understanding these differences helps ensure better device performance, fewer battery replacements, and smarter sourcing decisions.
