EXPLAINED: Tabless Vs. Traditional cells and the impact of cold temperatures

In brief, Tabless battery cells are lithium-ion cells engineered to eliminate the traditional single current-collector tabs used to carry power in and out of the cell. Instead of one or two discrete tabs, the electrode foils are laser-patterned or segmented and connected along its entire edge, creating parallel current paths in hundreds or thousands micro-connections.

What are Traditional CELLs?

What are they?

Standard cylindrical cells with tabs, such as the 18650, 21700 (Example: Samsung 40T, LG M50)

How are they built?

• The anode and cathode foils are wound into a jelly roll

• Each foil has one metal tab (sometimes two), welded to the anode and cathode foils inside the cell

• The tabs are electrical exit points for current

• Current must travel: through the electrode foil, toward the single tab, out of the cell

What are the Limitations?

• Current funnels into only one or two tab locations, causing localized concentration of heat at that tab

• There are limited contact points for power to exit the cell, causing electrical bottlenecking under higher current stress

• The concentration of heat at entry/exit points means that heat is not evenly distributed throughout the cell (jelly roll), creating a colder center

• Cold, imbalanced heat distribution makes the cell to inefficiently distribute power, therefore combating a higher internal resistance (DCIR)

• Cells with higher internal resistance (DCIR), especially during colder temperatures, will cause Higher Voltage Sag, reduced capacity and

• premature Battery Management Systems (BMS) cut-off

How do you calculate Power LOSS?

This equation describes how much energy is lost as heat inside a battery cell or battery pack.

P𝓁ℴ𝓈𝓈 = I² × R

Pₗₒₛₛ — Power Loss

• Measured in watts (W)

• Represents energy that does NOT go to the motor

• Instead, it becomes heat inside the cell

• Higher power loss = lower efficiency, more stress on the battery

I — Current

• Measured in amps (A)

• The amount of electrical flow the motor is demanding

• Higher power riding = higher current (hard acceleration, hills, cargo, winter riding)

Why current matters: Power loss increases with the square of the current, not linearly.

*** Double the current → 4× the heat loss

R — Resistance

• Measured in ohms (Ω)

• This is the battery’s internal resistance, often called DCIR

• Resistance exists in:

  • The cell chemistry

  • The electrode foils

  • Tabs or tabless connections

  • Welds, busbars, and pack construction

Key cold-weather fact: As temperature drops, R increases significantly.

What happens to all cold lithium-ion cells (≈ 0 °C / 32 °F and below)?

When batteries get cold:

• R increases (electrolyte and ion movement slow down)

• Voltage drops more under load

• Heat generation rises

• Usable capacity shrinks

Because the equation is:

P𝓁ℴ𝓈𝓈  = I² × R

Cold weather increases R, and high-power riding increases I, so:

Losses compound rapidly

Why High-Power Systems Are Hit Harder

High-power eBikes draw more current (I).

Since current is squared in the equation:

• Small increases in current cause large increases in heat loss

• Cold weather multiplies the effect by increasing resistance

This is why:

• Winter riding

• High-power motors

• Cargo and performance builds

are the most demanding scenarios for a battery.

How Tabless Cells Reduce These Losses

1. Lower Baseline Resistance (R)

Tabless architecture:

• Shortens electron travel paths

• Uses many parallel current exits

• Reduces total internal resistance

Lower R means lower power loss at all temperatures.

2. More Even Resistance Distribution

Traditional tabbed cells:

• Concentrate resistance at tab locations

• Create hot spots and current bottlenecks—worse in the cold

Tabless cells:

• Spread resistance evenly across the electrode edge

• Prevent localized heat spikes

• Improve overall efficiency

  
  

Why the Benefit Compounds

In cold, high-power conditions:

• R is already higher

• I is often high

• Power loss scales with I² × R

Tabless cells:

• Start with a lower R

• Avoid uneven resistance spikes

So as current and cold stress increase: The efficiency advantage grows, not shrinks

Simple takeaway

• Pₗₒₛₛ = wasted energy (heat)

• I = how hard you’re riding

• R = how hard the battery has to work internally

Cold weather raises R High power raises I²

Tabless cells reduce both the amount and unevenness of resistance—making them especially valuable for winter-ready, high-performance eBike batteries like those built by Bicycle Motor Works.

View our full collection of U.S. Made, Certified Premium Branded Winter-Ready eBike Batteries.

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