Boron deposition on Cu(111) surface and FER measurements. Credit: Science Advances (2025). DOI: 10.1126/sciadv.adv8385
More
than ten years ago, researchers at Rice University led by materials scientist
Boris Yakobson predicted that boron atoms would cling too tightly to copper to form borophene, a flexible,
metallic two-dimensional material with potential across electronics, energy and
catalysis. Now, new research shows that prediction holds up, but not in the
way anyone expected.
Unlike systems such as graphene on copper, where atoms may diffuse into the substrate without
forming a distinct alloy, the boron atoms in this case formed a defined 2D copper boride ⎯ a new compound with a distinct atomic structure. The
finding, published in Science Advances by
researchers from Rice and Northwestern University, sets the stage for further
exploration of a relatively untapped class of 2D materials.
"Borophene is still a material at
the brink of existence, and that makes any new fact about it important by
pushing the envelope of our knowledge in materials, physics and
electronics," said Yakobson, Rice's Karl F. Hasselmann Professor of Engineering
and professor of materials science and nanoengineering and chemistry. "Our
very first theoretical analysis warned that on copper, boron would bond too
strongly. Now, more than a decade later, it turns out we were right ⎯ and the result is not borophene, but something else entirely."
Previous studies successfully
synthesized borophene on metals like silver and gold, but copper remained an
open—and contested—case. Some experiments suggested boron might form
polymorphic borophene on copper, while others suggested it could phase-separate
into borides or even nucleate into bulk crystals. Resolving these possibilities
required a uniquely detailed investigation combining high-resolution imaging, spectroscopy and theoretical modeling.
"What my experimentalist colleagues
first saw were these rich patterns of atomic resolution images and spectroscopy
signatures, which required a lot of hard work of interpretation," Yakobson
said.
These efforts revealed a periodic zigzag
superstructure and distinct electronic signatures, both of which deviated
significantly from known borophene phases. A strong match between experimental
data and theoretical simulations helped resolve a debate about the nature of
the material that forms at the interface between the copper substrate and the
near-vacuum environment of the growth chamber.
Although copper boride was not the
material researchers set out to make, its discovery offers important insight
into how boron interacts with different metal substrates in two-dimensional
environments. The work expands the knowledge on the formation of atomically
thin metal boride materials ⎯ an area that could inform future studies of related
compounds, including those with known technological relevance, such as metal
borides among ultra-high temperature ceramics, which are of great interest for
extreme environments and hypersonic systems.
"2D copper boride is likely to be
just one of many 2D metal borides that can be experimentally realized. We look
forward to exploring this new family of 2D materials that have broad potential
use in applications ranging from electrochemical energy storage to quantum
information technology," said Mark Hersam , Walter P. Murphy Professor of
Materials Science and Engineering at Northwestern University, who is a
co-corresponding author on the study.
The
discovery comes shortly after another boron-related breakthrough by the same
Rice theory team. In a separate study published in ACS
Nano , researchers showed that borophene can form high-quality
lateral, edge-to-edge junctions with graphene and other 2D materials, offering
better electrical contact than even "bulky" gold. The juxtaposition
of the two findings highlights both the promise and the challenge of working
with boron at the atomic scale: its versatility allows for surprising
structures but also makes it difficult to control.
"Those images we initially saw in the experimental data looked quite mysterious," Yakobson said. "But in the end, it all fell into place and provided a logical answer ⎯ metal boride, bingo! This was unexpected at first, but now, it is settled—and science can move forward."
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