The Su God of the Reopening of the Sports Arena

Chapter 2437, page 1075! A new record is set! History continues to move forward.

Chapter 2437, page 10.75! A new record is set! History continues to move forward.

"On your marks—"

The referee's instructions came through the loudspeaker.

All eight people bent over at the same time, placing their hands on the rubber surface in front of the starting blocks. Xu Meilin's palms were still covered in talcum powder, and her old spikes rubbed against the track a couple of times before finding a stable foothold. The old injury on her knee was throbbing slightly, causing her to subconsciously shift her weight back a little.

Tao Yujia, who was in the second row next to him, took a deep breath, trying to calm the rapid beating in her chest, but her eyes couldn't help but sweep over the figures on her right.

Wei Yongli, in the third lane, had already assumed her stance, her back taut like a fully drawn bowstring, her brand-new black compression suit clinging tightly to her muscle lines, exuding undeniable tension.

Chen Juan, in lane four, appeared exceptionally calm. Her hands were shoulder-width apart, her fingertips lightly touching the ground, as if she were feeling the elasticity of the track. The stray hairs at her temples were ruffled by the breeze, but her gaze did not waver in the slightest.

Yuan Qiqi, in lane five, tilted her head slightly, quickly glancing at her opponents on both sides, a fleeting smile playing on her lips. Her bright yellow tracksuit stood out starkly in the morning light, the click of her spikes piercing the rubber so soft they were almost inaudible, yet they found precise fits in the starting block grooves.

Ge Manqi, in lane six, took a deep breath and silently repeated the coach's pre-race instruction to "start steadily." She slightly adjusted the angle of her elbow to ensure that she would not interfere with Liang Xiaojing, who was next to her, when she swung her arm.

Liang Xiaojing, in lane seven, was completely immersed in her own rhythm, her eyes fixed on the ground markings 3 meters ahead. Her breathing was as even as a metronome during training, and only her clenched fists betrayed her inner tension.

In lane eight on the far outside, Kong Lingwei tiptoed slightly, keeping her muscles slightly tense, and looked across the track to the timer behind the finish line to determine her final direction.

"preparation--"

As the second command was given, the hips of all eight people rose simultaneously, their bodies forming a standard "bow" shape.

Xu Meilin could clearly feel the friction between the old spikes and the track. The talcum powder on her palms gave her a bit more confidence, but she also knew that this confidence was no longer the drive she had back then, but the obsession with "not making a mistake".

Tao Yujia's heart suddenly raced, and all she could hear was her own breathing, along with the oppressive feeling emanating from Wei Yongli on her right.
It reminded her of the awe she felt towards the veteran team members when she first joined the team.

Just now.

she was.

He became the one who was surpassed by the younger generation.

Wei Yongli's thigh muscles trembled slightly, a sign of excitement rather than nervousness. She could feel the power surging up from her ankles through her calves and thighs; the starting motion she had honed repeatedly during training was already etched into her muscle memory.

Chen Juan beside her remained calm; she could even hear Yuan Qiqi's soft breathing on her left. She subtly adjusted the angle of her foot, ensuring she could fully release the power when pushing off the ground.

This detail was something that her coach spent a whole month training with her on Ersha Island before it became a fixed rule.

Bang————————

The moment the starting gun fired.

The entire track and field seemed to have been silenced again, only to be shattered by the force of eight figures rushing out.

The starting blocks vibrated slightly as they were pushed off, and eight pairs of spikes left clear marks on the track at the same time.

They ran wildly in the same direction.

Game start!
When the "on your positions" command is given.

Chen Juan quickly locked her body posture at the golden angle of "90° knee angle + 45° torso forward lean".

This posture is not based on empirical judgment, but on precise calibration of the infrared motion capture system:
Through comparative analysis of her starting data at 120 different knee angles (80°-100°).

The team discovered that the tension distribution between the quadriceps and hamstrings is optimal at a 90° knee angle.

The quadriceps pretension is 380N, and the hamstring pretension is 290N. The torque difference between the two can improve the force transmission efficiency at the moment of pushing off the ground by 12%, avoiding the risk of hamstring strain caused by excessive knee angle or insufficient force caused by insufficient knee angle.

Her hands were strictly spaced within ±0.5cm of shoulder width, and her fingertips used a "micro-ground touch" support method. Su Shen's biomechanical experiments showed that excessive pressure on the ground would increase the peak value of the electromyographic signal of the hand flexor muscles to 180μV, resulting in a 0.003-second delay in the transmission of nerve signals from the brain to the lower limb muscle groups.

In micro-touch mode, the peak value of electromyography signal can be reduced to 120μV, and the nerve conduction delay is shortened to less than 0.001 seconds, ensuring that the starting reaction speed is stable at the international top level of 0.13 seconds.

This winter training mainly focused on refining the existing system.

The World Championships in Beijing are coming soon, and as a rising star and leading runner in the women's event, Chen Juan cannot afford to make any mistakes.

The moment the gun fired.

Chen Juan initiated a chain-like force generation mode of "ankle-knee-hip", which is a technological innovation of the traditional "ankle-dominant force generation".

Data from the plantar pressure sensor showed that the middle of her right foot touched the ground first, and the pressure rapidly increased from 0 to 1200N within 0.01 seconds. The force was then transmitted through the tibia to the knee joint, and the quadriceps contracted within 0.008 seconds, amplifying the force to 1800N. Finally, through the extension of the hip joint, the entire body's strength was gathered into a forward propulsive force.

This "bottom-up" force transmission path allows the utilization rate of the reaction force from pushing off the ground to reach 85%.

This is far higher than the traditional model of 72%.

This increases the stride length of the first step by 0.05 meters.

Meanwhile, she employs a "90° fixed elbow angle" strategy for her arm swing. High-speed cameras captured that the elbow angle fluctuates by no more than ±2° during the arm swing, a level of control precision derived from "resistance band arm swing training."

By binding elastic resistance bands to the elbows, the synergistic control of the biceps and deltoid muscles is enhanced, increasing the standardization rate of arm swing movements from 75% at the beginning of training to 98%.

A stable swing arm trajectory can reduce lateral airflow resistance by 0.8N.

This is equivalent to saving 0.002 seconds in a 100-meter sprint.

After the gunshot, Chen Juan's right foot contacted the track with an arc-shaped trajectory of "outer edge of the foot touching the ground first, middle of the foot providing the main support, and inner edge of the foot lifting off the ground later," which is fundamentally different from the traditional "whole foot flat contact with the ground."

Data from the plantar pressure distribution meter showed that 0.005 seconds after contact with the ground, the pressure on the outer edge of the palm rapidly increased to 800N, accounting for 65% of the total pressure.

This design stems from a biomechanical analysis of her arch structure: her arch height is 22mm, and the outer edge of the foot touches the ground first, allowing energy to be stored in advance through the elastic deformation of the arch.

This also avoids the risk of ankle inversion caused by the inner edge of the palm touching the ground first.

After 0.008 seconds, the center of pressure shifts to the middle of the foot, and the peak pressure reaches 1350N. At this time, the deformation of the arch of the foot reaches its maximum, like a compressed bow storing elastic potential energy.

The second step.

The inner edge of the palm exerts force to push off the ground, and the pressure rapidly decreases from 600N to 0. The entire contact process forms an arc-shaped pressure trajectory of "outer-middle-inner".

This reduces the ground contact time from the traditional 0.12 seconds to 0.105 seconds.

The frequency of pushing off the ground increased by 12.5%.

Two more steps; this is Chen Juan's redesign of the trajectory and pressure distribution at the moment of ground contact this year.

It is beginning to better conform to her current human biomechanics.

Bang bang bang.

After three steps, you will enter the acceleration zone.

To drive the arc-shaped push-off trajectory, Chen Juan activated the spiral contraction coordination system of the "peroneus longus - tibialis posterior - adductor muscles".

Electromyography (EMG) tests showed that when the outer edge of the palm touches the ground, the peroneus longus muscle contracts first, with an EMG signal peak of 190 μV, pulling the outer side of the foot upward and laying the foundation for the arc-shaped trajectory.

When the midfoot supports the body, the tibialis posterior muscle contracts in response, and the electromyographic signal rises to 210μV. By internally rotating the foot, the force line direction is adjusted, increasing the proportion of the horizontal component of the push-off reaction force from the traditional 68% to 78%.

When the inner edge of the palm pushes off, the adductor muscles of the thigh contract synchronously, and the electromyographic signal reaches 170μV, aided by the adduction movement of the hip joint.

It injects additional rotational torque into the push-off motion.

It increases the propulsion of the first step when accelerating from the start by 15%.

However, this spiral force generation...

It wasn't done particularly well.

There is still room for improvement.

It's not expensive, and it's much better than before, which is good.

It has come to this point.

Any breakthrough, even a small one.

It's all worth it.

The main purpose is to enhance the application of force lines.

Chen Juan is much better at this than she was in Moscow.

Bang bang bang bang bang.

Acceleration zone.

When she pushes off the ground at the start, her ankle, knee, and hip joints form a "dynamically concentric" force transmission path.

With 10° internal rotation of the ankle joint, 2° internal rotation of the knee joint, and 3° adduction of the hip joint, the spiral force line formed by these three elements forms a 43° angle with the ground, perfectly receiving the rotational torque generated by the arc-shaped push-off.

High-speed motion capture systems show that this force line transmission reduces the time it takes for the reaction force from the sole of the foot to be transmitted to the torso to 0.012 seconds.

It is 0.03 seconds faster than the traditional linear force line.

This avoids the loss of force at the joints.

The traditional model has a force loss rate of 18%, which is reduced to 8% after optimization.

At the same time, her pelvis maintains a stable "3° anterior tilt" posture through the continuous contraction of the transverse abdominis muscle.

The electromyographic signal stabilized at 160 μV.

The rotational torque transmitted from the lower limbs is converted into forward tilting force of the torso, rather than lateral swaying.

This theoretically improves body stability at the start of the race by 25%.

This avoids the risk of imbalance caused by excessive rotational torque when pushing off the ground.

20 m.

As Chen Juan entered the 20-50 meter acceleration phase, her push-off arc trajectory gradually transitioned from an "outward-leaning" type to a "neutral" type. The proportion of pressure on the outer edge of her foot upon contact with the ground decreased from 65% to 45%, while the proportion of pressure on the middle of her foot increased to 50%, and the proportion on the inner edge remained at 5%.

This adjustment is based on real-time feedback of speed changes:
As the speed increases from 8 m/s to 10 m/s, the lateral stabilizing force required by the body gradually decreases.

The demand for longitudinal propulsion has increased.

By reducing the radius of contact with the ground, the consumption of lateral forces can be reduced.

This increases the proportion of longitudinal propulsion from 78% to 82%.

Data from the foot movement trajectory tester during training showed that the radius of her push-off arc was 12cm at 20 meters and decreased to 8cm at 50 meters.

Therefore, the variation range of the arc trajectory should be controlled within ±1cm.

This precise adjustment stems from the closed-loop feedback of "visual-proprioceptive":

By observing the speed at which the track markings move, combined with the pressure signals transmitted by plantar sensors.

The brain completes the fine-tuning instructions for the push-off trajectory within 0.005 seconds.

Ensure that the arc-shaped push-off always adapts to the current speed requirements.

The speed continued to increase.

The dynamic adjustment mechanism for the ground contact radius is excellent.

20 to 30 meters.

During the acceleration phase, the depth of her push-off.

The soles of the feet sank into the depth of the plastic running track.

It should be controlled within the range of 8mm ± 0.5mm.

Su Shen's biomechanical experiment showed that if Chen Juan's acceleration push-off depth was too shallow (<6mm), it would lead to insufficient grip, while if the depth was too deep (>10mm), the energy loss from pushing off would increase by 10% due to the increased resistance of the plastic.

The 8mm depth was determined by testing different track hardness levels (70-90 Shore hardness).

The hardness of the BJ track and field's synthetic running track is 82 Shore A hardness.

At this depth, the runway's elastic potential energy feedback efficiency reaches its maximum (35%).

That is, the 100J of energy injected when pushing off the ground.

35J can bounce back to the body through the elasticity of the runway.

Reduce energy consumption by muscles.

To precisely control the depth of her push-off, she employed a "graded contraction" strategy for her calf muscles:
The gastrocnemius muscle contracts at 60% intensity upon initial contact with the ground to ensure the foot sinks smoothly into the track.

The strength of the support phase is increased to 85%, and energy is stored by leveraging the elasticity of the runway.

Reduce intensity to 70% during the push-off phase to avoid muscle fatigue caused by excessive exertion.

Electromyography data showed that this graded contraction reduced Chen Juan's calf muscle energy consumption by 18%.

To conserve energy for accelerating in the second half of the race.

Take the optimization of energy storage for this push-off depth, for example. Without the aid of technological equipment for testing, how could you possibly judge it so accurately with the naked eye?

Is it impossible?

The acceleration zone is beginning to transition into the mid-race phase.

The "arc-shaped buffer" technology for step transitions!
The transition between steps during the acceleration phase is key to speed improvement, and Chen Juan achieves a seamless transition through "forward push-off arc buffer".

When the front foot lifts off the ground, the back foot begins to swing forward in an arc, with the ball of the foot maintaining a height of 3cm from the ground, thus avoiding the increased air resistance caused by the traditional "high leg lift and swing".

The air resistance is 1.2N when the leg is raised high and swings, and only 0.5N when it swings in an arc.

At the same time, 0.01 seconds before the rear foot touches the ground, the ankle joint dorsiflexes 12° in advance, so that the foot forms a tilt angle of "lower in the front and higher in the back", and achieves a "soft landing" by means of an arc trajectory at the moment of contact with the ground.

The ground impact force was reduced from 1800N to 1400N.

It reduces the amount of impact transmitted to the knee joint by 22%.

This step-to-step transition technique is enhanced through "synchronous training on a high-frequency variable-speed treadmill":

This means setting the treadmill speed to a gradual range of 8-10 m/s.

Stick curved marking lines on the running belt.

The foot must be swung along the marked line when it touches the ground.

This reduces the interstep transition time from 0.08 seconds to 0.065 seconds.

To increase step frequency efficiency.

It is also a great tool for increasing step frequency in the future.

But now.

Excuse me.

This thing.

Currently, only Ersha Island has it.

The run begins.

Because of her bent-arm start, Chen Juan had already taken the lead.

just now……

She was completely in her own competitive state and rhythm.

There's no one left in all of Asia who can cause her trouble.

She's comparing herself to herself.

This year, I reduced the frequency of overseas competitions so that I could focus on making this final push.

in order.

It's about pushing your body to its limits.

To set a new national standard.

Creating the limits in Asia.

Pushing the limits of the yellow race.

at this point.

Li Xuemei and her team have been doing this for almost the entire major campaign cycle, ever since it ended in 2013.

After a year of reflection in 2014, this year...

That's when you need to do this.

And it has to be before the Bird's Nest battle.

Give it to yourself first.

Instill confidence.

What are your plans?

After discussing it with Su Shen, Chen Juan's team...

The chosen method is—

Maximize the efficiency of "stable arc-shaped push-off".

This is a manifestation of the curved buffer transition.

Chen Juan demonstrated symmetrical control of her left and right foot trajectories.

Bang bang bang bang bang.

Chen Juan's left and right foot push-off arc trajectory achieves "98% symmetry," a technological breakthrough achieved through "mirror training."

Traditional athletes often have a difference of more than 3cm in the arc of their left and right feet pushing off the ground due to the difference in strength between their left and right legs. However, she uses a "dual foot pressure synchronous acquisition system" in her training to compare the pressure trajectory of her left and right feet in real time and conduct targeted strengthening training for the weaker leg (left leg).

Attach a variable resistance device to the left ankle joint and perform arc-shaped push-off exercises.

This increased the strength of the left quadriceps muscle from 92% to 98% of that of the right leg. It also reduced the peak pressure difference between the left and right feet during push-off from 120N to 30N.

High-speed cameras can capture that the angle between Chen Juan's left and right feet touching the ground and the ground is consistently 68°±1°.

The push-off angle is 75°±1°.

This highly symmetrical push-off trajectory keeps the lateral sway of the body within ±0.8cm.

Air resistance is reduced by 15%.

Energy efficiency is improved by 10%.

Bang bang bang bang bang.

After achieving symmetrical control over the push-off trajectory of the left and right feet, the next step is...

The force is generated by the coordinated effort of pushing off the ground and rotating the torso.

Chen Juan's "arc-shaped push-off" works in conjunction with the slight rotation of her torso to further improve propulsion efficiency.

When the right foot pushes off the ground in an arc, the torso rotates 2° clockwise, aided by the contraction of the external oblique muscles.

The rotational torque generated by pushing off the ground is converted into forward propulsion.

In this way, when the left foot pushes off the ground, the torso rotates counterclockwise by 2°, and the internal oblique muscles of the abdomen take over the force to form a continuous rotational propulsion force.

Biomechanical analysis shows that this synergy can further increase the utilization rate of the ground reaction force by 5%.

This is equivalent to gaining an extra 40J of propulsion energy per step.

The torso rotation angle is strictly controlled within ±2°.

This is achieved through "rotational resistance training".

It is achieved by attaching an adjustable resistance rotating training belt around the waist.

This limits excessive trunk rotation.

This reduced the standard deviation of the rotation angle from 0.8° at the beginning of training to 0.3°.

Avoid energy waste due to excessive rotation or insufficient synergy due to insufficient rotation.

Then...

The power of technology.

The running shoes and the ground are designed specifically for this purpose.

The track here is exactly the same as the one used for the World Championships in Beijing.

After all, Su Shen is now very wealthy.

One runway needs repair.

It's worthless.

Because if you can achieve good results, the profits will be far more than just a little money.

In response to the elasticity of the Bird's Nest track and field's synthetic running track, Chen Juan optimized the "energy injection-rebound" rhythm when pushing off the ground.

Upon contact with the ground, her foot exerts pressure on the track at a speed of 0.8 m/s, causing the track to deform by 8 mm. The elastic potential energy stored during the deformation is approximately 50 J.

When pushing off, the foot exerts force at a speed of 1.2 m/s, and with the help of the 21 J of energy rebounded from the track, the propulsion force at the moment of push-off is increased by 12%.

This "leveraging" strategy is reinforced through "elastic mat simulation training": using elastic mats with different rebound coefficients (0.3-0.5) to perform arc-shaped push-off exercises, training the brain's ability to adapt to different elastic environments.

This allows her to adjust her push-off force based on track feedback within 0.003 seconds.

The utilization rate of elastic potential energy increased from 28% at the beginning of training to 42%.

of course.

Shoes are an important medium.

This has already been mentioned before.

No further explanation is needed.

It combines scientific technology with the most targeted and meticulous training.

It's now.

The reason why Chen Juan ran faster and faster.

Bang!
The second phase of the six-second burst!

let's go!

Once Chen Juan unleashed her full speed, she was truly unstoppable.

She is now taking classes at international competitions, where she is among those who can compete for medals.

On the Asian stage, it was simply—

One light.

In the high-speed zone, he instantly widened the gap with the others.

60 meters, 70 meters, 80 meters.

This speed is really too fast.

Even on the international stage.

Among active athletes, only players like Okabarre, with their super long legs, can probably suppress the effect to some extent due to their physiological impact.

Even this year.

Even they might not be able to suppress it.

After 80 meters.

The speed started to decrease.

The final sprint.

The fatigue resistance and power breakthrough of "extreme arc-shaped push-off".

This is the research topic her team has been working on for the past two years.

The new approach involves adjusting the "inward contraction reinforcement" of the push-off trajectory.

That's called the inward strengthening adjustment of the push-off trajectory.

Bang bang bang bang bang.

After 80 meters, they entered a state of fatigue.

Chen Juan's push-off arc trajectory changed from "neutral" to "inward-strengthening".

The pressure percentage of the inner edge of the foot increased from 5% to 15%, while the percentage of the outer edge decreased to 35%, with the middle of the foot still being the main support.

This adjustment is based on real-time feedback from electromyography data:
At this time, the lactate concentration in the quadriceps muscle rises to 9 mmol/L, the peak electromyographic signal drops from 210 μV to 170 μV, and the force exertion ability decreases by 19%. By strengthening the force exertion at the inner edge of the palm, the synergistic effect of the adductor muscles can be utilized.

The electromyographic signal increased from 170μV to 190μV.

The main purpose is to compensate for insufficient quadriceps muscle activation.

After the speed begins to decrease, the propulsive force from pushing off the ground in the sprint zone is maintained.

At the same time, her ankle internal rotation angle increased from 10° to 12°, further shortening the ground contact time.

It decreased from 0.105 seconds to 0.098 seconds.

By increasing the frequency of pushing off the ground.

To offset the speed loss caused by the shortened step size.

90 m.

The "compensatory synergy" mechanism of muscle group exertion!
Open!
During the sprint phase, when the main muscle groups, such as the quadriceps and gastrocnemius, become fatigued, Chen Juan activates the "secondary muscle group compensation" synergistic mode.

Electromyography (EMG) tests showed that the peak EMG signal of the gluteus maximus increased from 150 μV during the middle run to 190 μV, injecting additional power into the push-off motion through the hip extension.

At the same time, the erector spinae muscle contraction strength increases by 20%, maintaining the forward-leaning posture of the trunk and ensuring that the force transmission is uninterrupted when pushing off the ground.

This compensatory mechanism is enhanced through "extreme fatigue simulation training": running continuously at a speed of 10.5 m/s on a high-frequency variable speed treadmill until the lactate threshold is reached.

Then practice the arc-shaped push-off.

Train the ability to quickly activate secondary muscle groups.

This reduces the compensation response time from 0.01 seconds to 0.006 seconds.

Avoid disrupting the push-off rhythm due to fatigue of the primary muscle groups.

Bang bang bang bang bang.

The last ten meters.

The force line is focused on the "arc-shaped push-off" before crossing the finish line.

As the finish line drew ever closer.

Chen Juan further reduced the radius of the arc-shaped trajectory of her push-off to 6cm.

This makes the force line more focused on vertical advancement.

Plantar pressure data shows that at this point, the horizontal component of the reaction force from pushing off the ground reaches a peak of 85%, while the vertical component is only 15%, minimizing the energy consumption from the up-and-down movement of the body.

At the same time, her knee extension angle increased from 150° to 160°.

The duration of the force application was extended, increasing the propulsive energy of each step from 280J to 310J.

In the final step before crossing the finish line, she pushed off the ground with the inside edge of her palm, using the rapid internal rotation of her ankle joint.

It causes a slight forward tilting torque in the body.

This causes the torso to cross the finish line 0.005 seconds earlier than expected.

It was captured by a high-speed camera.

This move improved her finishing time by 0.008 seconds compared to the traditional straight-line push-off.

and this.

That's the key to breaking the Asian record.

Or, to put it another way, all of the above technical adjustments and optimizations.

These were all key factors in breaking the Asian record.

The finish line is now within reach.

It all depends on Chen Juan herself.

How did we surpass it?

The core of this transcendence lies in the underlying logic of technological upgrading...

Data-driven personalized refinement.

Chen Juan's "three-dimensional arc-shaped ground-pushing" technique was not created out of thin air, but rather formed based on a closed-loop system of "biomechanical testing - data modeling - targeted training - practical verification".

The coaching team used a 3D motion capture system to collect motion data from 120 different push-off trajectories, established a personalized biomechanical model, and accurately identified the three major shortcomings of traditional push-off techniques.

Force transmission loss is 18%, elastic potential energy utilization is 28%, and left and right foot symmetry is 82%.

To address these shortcomings, a three-stage training program was designed.

The foundational stage establishes the movement framework through "arc-shaped trajectory marking run"; the reinforcement stage enhances muscle group coordination efficiency through "elastic band resistance training".

During the practical phase, simulated matches were conducted in different venues to optimize the environmental adaptability of the technology.

After 28 weeks of systematic training, her ground reaction force utilization rate increased from 72% to 89%.

Ground contact time was reduced by 12.5%, and the symmetry between the left and right feet was improved to 98%!

The success of this "three-dimensional arc-shaped push-off" technology also confirms the core direction of sprint technique innovation—

Shift from "experience-driven" to "data-driven".

By deeply exploring the laws of human movement, every technical detail is transformed into quantifiable efficiency improvements.

Ultimately, in a race where victory is determined in milliseconds, they built an insurmountable technological barrier.

These are the coaches from the past.

Coaching team.

Things that are beyond human capability.

Things that are not visible to the naked eye.

We can only make new adjustments by relying on advanced scientific equipment, technology, and concepts.

This is Chen Juan now.

Training reports from the past two years.

This shot.

However, this is simply her final answer to the two years of hard training she has put in.

"Chen Juan ran faster and faster, and at this point no one could catch her. Her shot had only one target..."

"Let's see if we can break the Asian record that I and Li Xuemei hold!"

"Chen Juan, hold on fast! Right now, she only has herself to face!"

"Speed up! Hold on!"

"Lie down and press the line!!!!!!!!!"

Almost as soon as the wire bonding was finished, or rather, while the word "wire bonding" was still on my lips...

Yang Jian and the others had already moved their eyes to the lower left corner.

Because it's here.

What will be Chen Juan's score in this shot that is about to emerge?
one look.

Yang Jian and Li Tao.

Everyone felt a surge of passion.

It rushed straight from the dantian to the forehead.

"10...10.75!!!!!!!!!!!!"

"Best performance by an individual!!!!"

"A new national record has been set!!!!!"

"A new Asian record has been set!!!!!"

"Li Xuemei's nearly 20-year record has finally been broken!!!! The person who made this breakthrough is none other than the person he's currently leading!!!!!!!!!"

"Li Xuemei is right here on the sidelines!!!"

"Watching the young people in my team break my records, isn't that a kind of passing on of the torch?!"

"10.75!"

"The limits of Asian women!"

"We've pushed it to another level!!!"

"We've broken the Asian record again!!!"

Chen Juan looked at the grades.

With a flick of her ponytail, all fatigue seemed to vanish.

Content and pleased with oneself.

Smiling.

Answer the call from the audience.

Establish guidance.