High-resolution
microscopy reveals that a benzene-like molecule known as HBC has a quantized
electron density around its ring framework (left). Theoretical calculations
show that the observed quantum states change with different tip positions
(right, upper/lower images, respectively).
Information within the bonds of molecules
known as super benzene oligomers pave the way for new types of quantum
computers
Scanning tunneling microscopy (STM) is
routinely employed by physicists and chemists to capture atomic-scale images of
molecules on surfaces. Now, an international team led by Christian Joachim and
co-workers from the A*STAR Institute of Materials Research and Engineering has
taken STM a step further: using it to identify the quantum states within ‘super
benzene’ compounds using STM conductance measurements1. Their results provide a
roadmap for developing new types of quantum computers based on information
localized inside molecular bonds.
To gain access to the quantum states of
hexabenzocoronene (HBC) — a flat aromatic molecule made of interlocked benzene
rings — the researchers deposited it onto a gold substrate. According to team
member We-Hyo Soe, the weak electronic interaction between HBC and gold is
crucial to measuring the system’s ‘differential conductance’ — an instantaneous
rate of current charge with voltage that can be directly linked to electron
densities within certain quantum states.
After cooling to near-absolute zero
temperatures, the team maneuvered its STM tip to a fixed location above the HBC
target. Then, they scanned for differential conductance resonance signals at
particular voltages. After detecting these voltages, they mapped out the
electron density around the entire HBC framework using STM. This technique provided
real-space pictures of the compound’s molecular orbitals — quantized states
that control chemical bonding.
When Joachim and co-workers tried mapping a
molecule containing two HBC units, a dimer, they noticed something puzzling.
They detected two quantum states from STM measurements taken near the dimer’s
middle, but only one state when they moved the STM tip to the dimer’s edge (see
image). To understand why, the researchers collaborated with theoreticians who
used high-level quantum mechanics calculations to identify which molecular
orbitals best reproduced the experimental maps.
Traditional theory suggests that STM
differential conductance signals can be assigned to single, unique molecular
orbitals. The researchers’ calculations, however, show that this view is
flawed. Instead, they found that observed quantum states contained mixtures of
several molecular orbitals, with the exact ratio dependent upon the position of
the ultra-sharp STM tip.
Soe notes that these findings could have a
big impact in the field of quantum computing. “Each measured resonance
corresponds to a quantum state of the system, and can be used to transfer
information through a simple energy shift. This operation could also fulfill
some logic functions.” However, he adds that advanced, many-body theories will
be necessary to identify the exact composition and nature of molecular orbitals
due to the location-dependent tip effect.
The A*STAR-affiliated researchers
contributing to this research are from the Institute of Materials Research and
Engineering
References
- Soe, W.-H., Wong, H. S., Manzano, C., Grisolia,
M., Hliwa, M., Feng, X., Müllen, K. & Joachim, C. Mapping the excited
states of single hexa-peri-benzocoronene oligomers. ACS
Nano 6, 3230–3235 (2012). | article
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