Climbing is not a collection of isolated muscle actions.
It is a system of connected segments transferring force through a chain.
Body tension is the mechanism that keeps this chain intact.
When tension is correct:
- force transfers efficiently from feet → hips → core → shoulders → hands
- holds feel “bigger”
- moves feel “lighter”
- dynamic motion stays controlled
- you waste less energy
When tension breaks:
- force leaks
- feet cut
- hips sag
- contact quality drops
- moves suddenly feel brutish or unstable
This article explains what body tension really is — not “squeezing the core,” but controlling force transmission through the kinetic chain.
1. The Body Is a Series of Connected Levers
Your limbs and torso form a linked mechanical system:
- feet drive force into the wall
- legs transmit that force upward
- hips act as a rotational hub
- the core stabilises the central mass
- the shoulders and arms direct the output
- the fingers anchor the final vector
If any link in this chain collapses, the system fails and the movement becomes inefficient or impossible.
This is why climbers with strong arms can still feel weak on steep ground:
the chain breaks long before the arm fails.
2. Body Tension = Force Continuity, Not Muscular Squeezing
Most climbers misunderstand body tension as “tighten your abs.”
That’s not how tension works mechanically.
Real tension is:
continuous force transmission across all joints that prevents segments from moving independently.
This means:
- a stable midsection that doesn’t sag
- hips that remain aligned with the force direction
- shoulders set in a position that doesn’t collapse
- feet that maintain contribution instead of going passive
- forearms and wrists that align force instead of leaking torque
Body tension is a structural property — not a muscular contraction.
3. The Chain Has Two Modes: Compression & Tension
Depending on your body position, the chain switches modes:
Compression mode
Used on slab and vertical terrain.
Force travels downward through locked joints into the feet.
Signs:
- straight hips
- extended legs
- stacked joints
- CoM over feet
- minimal muscular tension
- maximum use of geometry
Tension mode
Used on overhangs and roofs.
Force travels upward through engaged muscles into the hands.
Signs:
- bent knees
- hips pulled toward the wall
- active toes
- engaged core
- shoulders stabilised under load
Understanding which mode you are in determines how you apply tension.
Wrong mode = instant energy waste.
4. The Chain Always Fails at the Weakest Joint Angle
The chain doesn’t break randomly.
It fails exactly where:
- joint angles are poorly aligned
- muscles cannot support the torque
- the CoM pulls the segment out of position
- the force vector is inconsistent
- a rotational component is unaccounted for
Typical failure points:
- sagging hips on overhangs
- collapsing shoulders on sidepulls
- twisting knees on high steps
- wrist rotation on small edges
- core folding during foot cuts
Climbers often misdiagnose these as “weak core” or “weak fingers.”
In reality, it’s joint-angle failure in the kinetic chain.
5. Feet Are the Start of the Chain, Not the End
Most climbers think of feet as passive.
But feet are the first link in the chain:
- they anchor rotational control
- they deliver counterforce
- they stabilise the hips
- they allow hands to work with less torque
- they generate upward drive
When people say “engage your core,” what they usually mean is:
reconnect your feet to the chain.
Good climbers climb “through the feet,” not “from the arms.”
6. Tension Determines Movement Precision
Precision is not only about accuracy — it is about controlling the CoM and force direction during movement.
Without tension:
- the CoM moves unpredictably
- hand placements become unstable
- deadpoints become chaotic
- directional friction is lost
- contact mechanics degrade
- coordination timing collapses
With tension:
- the CoM follows a predictable path
- contact is stable on catch
- dynos feel “quiet”
- micro-adjustments happen automatically
- hands and feet act like a single system
Tension is not stiffness — it is controlled continuity.
7. Dynamic Movement Requires Timing of Tension
During dynamic moves:
- tension must relax enough to generate momentum
- tension must re-engage fast enough to catch the CoM
- the force chain must activate in the right order
The sequence is:
- release → accelerate → re-tension → absorb → stabilise
Not being strong enough is rarely the issue —
the real problem is delayed re-engagement of the chain.
This is why climbers “slap” holds instead of catching them quietly.
8. The Rule: Build the Chain Before the Move
The kinetic chain must be established before any forceful action.
Correct order:
- connect feet → hips → core → shoulders → hands
- ensure tension continuity
- align the force vector
- then pull, push, lock, or jump
Most technical errors come from initiating movement while the chain is incomplete.