一款新型隐形眼镜使人眼无需夜视镜等笨重设备即可看到近红外光。该隐形眼镜包含金属纳米粒子，可以将通常不可见的波长“上转换”为可见波长，可能对救援人员和其他需要在低能见度条件下增强视力的人员有所帮助。该技术通过将特定纳米粒子集成到生物相容性聚合物材料中实现，这些材料类似于标准软性隐形眼镜中使用的材料。志愿者测试表明，佩戴这种隐形眼镜不会影响他们的正常视力，并且能够准确地检测闪烁的莫尔斯电码信号，甚至在闭眼时也能更清晰地感知。

🔬该隐形眼镜集成了金/NaGdF4: Yb3+, Er3+纳米粒子，直径约为45纳米。这些纳米粒子通过捕获低能量（长波长）的光子，并将其重新发射为高能量（短波长）的光子来工作，这个过程被称为上转换。

🐭在对小鼠进行的测试中，佩戴新型上转换隐形眼镜（UCLs）的小鼠表现出能够感知红外波长的行为。例如，当在暗箱和红外光照亮的箱子之间做出选择时，佩戴隐形眼镜的小鼠会迅速进入暗箱。

💡人体志愿者测试表明，近红外UCLs使参与者能够准确地检测闪烁的莫尔斯电码式信号，并感知近红外（NIR）光的入射方向。更令人惊讶的是，当志愿者闭上眼睛时，闪烁的图像显得更加清晰。

🌈通过用三色正交纳米粒子替换上转换纳米粒子，该团队成功地将近红外光转换为三个不同的光谱带，例如，他们将808、980纳米和1532纳米的红外波长分别转换为540、450和650纳米，人眼感知为绿色、蓝色和红色。

A new contact lens enables humans to see near-infrared light without night vision goggles or other bulky equipment. The lens, which incorporates metallic nanoparticles that “upconvert” normally-invisible wavelengths into visible ones, could have applications for rescue workers and others who would benefit from enhanced vision in conditions with poor visibility.

The infrared (IR) part of the electromagnetic spectrum encompasses light with wavelengths between 700 nm and 1 mm. Human eyes cannot normally detect these wavelengths because opsins, the light-sensitive protein molecules that allow us to see, do not have the required thermodynamic properties. This means we see only a small fraction of the electromagnetic spectrum, typically between 400‒700 nm.

While devices such as night vision goggles and infrared-visible converters can extend this range, they require external power sources. They also cannot distinguish between different wavelengths of IR light.

Photoreceptor-binding nanoparticles

In a previous work, researchers led by neuroscientist Tian Xue of the University of Science and Technology of China (USTC) injected photoreceptor-binding nanoparticles into the retinas of mice. While this technique was effective, it is too invasive and risky for human volunteers. In the new study, therefore, Xue and colleagues integrated the nanoparticles into biocompatible polymeric materials similar to those used in standard soft contact lenses.

The nanoparticles in the lenses are made from Au/NaGdF4: Yb³⁺, Er³⁺ and have a diameter of approximately 45 nm each. They work by capturing photons with lower energies (longer wavelengths) and re-emitting them as photons with higher energies (shorter wavelengths). This process is known as upconversion and the emitted light is said to be anti-Stokes shifted.

When the researchers tested the new upconverting contact lenses (UCLs) on mice, the rodents’ behaviour suggested they could sense IR wavelengths. For example, when given a choice between a dark box and an IR-illuminated one, the lens-wearing mice scurried into the dark box. In contrast, a control group of mice not wearing lenses showed no preference for one box over the other. The pupils of the lens-wearing mice also constricted when exposed to IR light, and brain imaging revealed that processing centres in their visual cortex were activated.

Flickering seen even with eyes closed

The team then moved on to human volunteers. “In humans, the near-infrared UCLs enabled participants to accurately detect flashing Morse code-like signals and perceive the incoming direction of near-infrared (NIR) light,” Xue says, referring to light at wavelengths between 800‒1600 nm. Counterintuitively, the flashing images appeared even clearer when the volunteers closed their eyes – probably because IR light is better than visible light at penetrating biological tissue such as eyelids. Importantly, Xue notes that wearing the lenses did not affect participants’ normal vision.

The team also developed a wearable system with built-in flat UCLs. This system allowed volunteers to distinguish between patterns such as horizontal and vertical lines; S and O shapes; and triangles and squares.

But Xue and colleagues did not stop there. By replacing the upconverting nanoparticles with trichromatic orthogonal ones, they succeeded in converting NIR light into three different spectral bands. For example, they converted infrared wavelengths of 808, 980 nm and 1532 nm into 540, 450, and 650 nm respectively – wavelengths that humans perceive as green, blue and red.

“As well as allowing wearers to garner more detail within the infrared spectrum, this technology could also help colour-blind individuals see wavelengths they would otherwise be unable to detect by appropriately adjusting the absorption spectrum,” Xue tells Physics World.

According to the USTC researchers, who report their work in Cell, the devices could have several other applications. Apart from providing humans with night vision and offering an adaptation for colour blindness, the lenses could also give wearers better vision in foggy or dusty conditions.

At present, the devices only work with relatively bright IR emissions (the study used LEDs). However, the researchers hope to increase the photosensitivity of the nanoparticles so that lower levels of light can trigger the upconversion process.

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