Chinese physicists achieve 20x laser boost using quantum light

Physicists at East China Normal University demonstrated a 20-fold enhancement in laser interactions using “bright squeezed vacuum” quantum light, according to a study published in Nature.nature
The technique produced the same nonlinear ionization in sodium atoms as a conventional laser pulse with over 20 times the effective intensity, while using just 300 nanojoules of energy.interestingengineering
The approach could enable attosecond experiments at far lower energy costs, reducing the risk of thermal damage to targets and optical components.interestingengineering

Chinese Physicists Achieve 20x Laser Boost Using Quantum Light

A team of physicists in China has demonstrated that the quantum properties of light itself can substitute for raw laser power, achieving a 20-fold enhancement in ultrafast laser interactions without increasing the energy delivered to a target. The advance, published in Nature, could reshape how scientists probe matter at the shortest timescales.nature

Quantum Fluctuations as a Tool

Researchers led by Jian Wu at East China Normal University used a quantum light state called bright squeezed vacuum (BSV) to trigger tunneling ionization in sodium atoms. Unlike conventional laser pulses, where photons arrive at a relatively steady rate, BSV produces extreme fluctuations in photon density — creating short-lived bursts of very high instantaneous intensity even when average energy remains low.interestingengineering

The team found that a BSV pulse carrying just 300 nanojoules of average energy produced the same nonlinear ionization effect as a conventional laser pulse with more than 20 times the effective intensity. Crucially, the enhancement came without raising average power, reducing the risk of thermal or structural damage to targets and optical components.linkedin

Implications for Attosecond Science

Nonlinear optical processes — where multiple photons interact with matter nearly simultaneously — underpin fields from high-harmonic generation to attosecond physics, which tracks electron dynamics on timescales of billionths of a billionth of a second. These experiments typically push lasers close to the damage limits of the materials under study.interestingengineering

By engineering the quantum statistical properties of light rather than scaling up pulse energy, the researchers showed they could tune interaction strength independently of average power. The approach suggests that future attosecond experiments and extreme light-matter interactions could be conducted at far lower energy costs and with less collateral damage.nature

A Broader Shift in Optics

The work reflects a growing trend in quantum optics: treating quantum fluctuations not as noise to be suppressed but as a functional resource. While the technique remains highly experimental, it points toward a generation of ultrafast optical technology where carefully structured quantum states of light become as important as brute-force laser intensity.synapticreport