Diamonds are widely known as a material that resists scratches, is used to cut the hardest metals, and is often used as a metaphor for toughness. However, an international research team recently challenged this view, announcing that “nanoscale” diamonds can somehow become “rubbery.”

According to the study, published in the journal Physical Review X, researchers focused on what is known as “nanodiamonds”—extremely tiny crystals ranging in size from 4 to 13 nanometers (thousands of times smaller than the width of a human hair).

The surprise is that these crystals, despite being made of the same hard material we know, do not behave the same way at this scale. In fact, the smallest particles studied, at 4 nanometers in size, showed a reduction in hardness by about 30% compared to larger particles, while still maintaining high toughness.

These results came from extremely precise experiments. The researchers used a special tool known as a “diamond anvil cell,” where nanoparticles are placed between two diamond surfaces and then subjected to intense pressure.

At the same time, the team used a transmission electron microscope to observe what happens inside the material at the atomic level, while computer simulations supported these observations. This methodology allowed scientists to see how atoms actually move when diamond is subjected to pressure.

The idea to grow diamond into intricate shapes ⎯ including an owl, the university’s mascot ⎯ was prompted by wanting to have a special keepsake to give to distinguished guests. (Photo by Jorge Vidal/Rice University)
The team used a transmission electron microscope to observe what happens inside the material at the atomic level.

Promising Applications

According to the study, the researchers found that the real reason for this flexibility lies in a very thin layer located just beneath the surface. In this region, the carbon bonds are slightly different from those in the hard diamond core—they are less compact and relatively longer, making them mechanically weaker.

Thus, a three-part structure forms within the same diamond piece: a very hard inner core, a strong outer shell, and a relatively weaker intermediate layer. This intermediate layer acts as a microscopic cushion, according to the scientists, absorbing some of the pressure and giving the particle the ability to bend, somewhat like rubber.

However, according to the study, nanodiamonds do not become soft in the traditional sense, but they become more capable of withstanding stress without cracking.

This discovery holds promising practical applications. Combining high hardness with relative flexibility is a dream in the field of materials engineering, especially in nanoscale sensors, which require materials that can withstand vibration without breaking.

This technology could also benefit advanced computing, including quantum computing, where nanomaterials are used in highly sensitive environments, as well as in detecting viruses and gases through precise sensors that rely on small mechanical changes.

Physical Review X

Physical Review X is an online-only, open-access scientific journal published by the American Physical Society, launched in 2011. It was established to provide a high-quality, freely accessible platform for groundbreaking research across all areas of physics, with a rigorous peer-review process. The journal quickly became a leading venue for significant original research, reflecting the modern shift toward open-access publishing in the scientific community.

diamond anvil cell

The diamond anvil cell (DAC) is a scientific device used to create extremely high pressures by compressing a sample between two opposing diamond tips. Developed in the 1950s by researchers at the University of Chicago, it has become a crucial tool in physics and chemistry for studying the behavior of materials under conditions similar to those deep inside planets. By combining pressure with laser heating, scientists can mimic the Earth’s core or simulate the synthesis of new materials.

transmission electron microscope

The transmission electron microscope (TEM) is a powerful scientific instrument that uses a beam of electrons to image materials at the atomic scale, far beyond the limits of light microscopes. Its development began in the 1930s, with the first working TEM built by Ernst Ruska and Max Knoll in Germany, work for which Ruska later won the Nobel Prize. Today, TEMs are essential in fields like materials science and biology, allowing researchers to study the fine structure of cells, viruses, and crystals.