Science News
from research organizations

Boundary between electronics and biology is blurring: First proof of ferroelectricity in simplest amino acid

Date:
April 19, 2012
Source:
DOE/Oak Ridge National Laboratory
Summary:
The boundary between electronics and biology is blurring with the first detection of ferroelectric properties in an amino acid called glycine.
Share:
         
Total shares:  
FULL STORY

ORNL researchers detected for the first time ferroelectric domains (seen as red stripes) in the simplest known amino acid – glycine.
Credit: Image courtesy of DOE/Oak Ridge National Laboratory

The boundary between electronics and biology is blurring with the first detection by researchers at Department of Energy's Oak Ridge National Laboratory of ferroelectric properties in an amino acid called glycine.

A multi-institutional research team led by Andrei Kholkin of the University of Aveiro, Portugal, used a combination of experiments and modeling to identify and explain the presence of ferroelectricity, a property where materials switch their polarization when an electric field is applied, in the simplest known amino acid -- glycine.

"The discovery of ferroelectricity opens new pathways to novel classes of bioelectronic logic and memory devices, where polarization switching is used to record and retrieve information in the form of ferroelectric domains," said coauthor and senior scientist at ORNL's Center for Nanophase Materials Sciences (CNMS) Sergei Kalinin.

Although certain biological molecules like glycine are known to be piezoelectric, a phenomenon in which materials respond to pressure by producing electricity, ferroelectricity is relatively rare in the realm of biology. Thus, scientists are still unclear about the potential applications of ferroelectric biomaterials.

"This research helps paves the way toward building memory devices made of molecules that already exist in our bodies," Kholkin said.

For example, making use of the ability to switch polarization through tiny electric fields may help build nanorobots that can swim through human blood. Kalinin cautions that such nanotechnology is still a long way in the future.

"Clearly there is a very long road from studying electromechanical coupling on the molecular level to making a nanomotor that can flow through blood," Kalinin said. "But unless you have a way to make this motor and study it, there will be no second and third steps. Our method can offer an option for quantitative and reproducible study of this electromechanical conversion."

The study, published in Advanced Functional Materials, builds on previous research at ORNL's CNMS, where Kalinin and others are developing new tools such as the piezoresponse force microscopy used in the experimental study of glycine.

"It turns out that piezoresponse force microsopy is perfectly suited to observe the fine details in biological systems at the nanoscale," Kalinin said. "With this type of microscopy, you gain the capability to study electromechanical motion on the level of a single molecule or small number of molecular assemblies. This scale is exactly where interesting things can happen."

Kholkin's lab grew the crystalline samples of glycine that were studied by his team and by the ORNL microscopy group. In addition to the experimental measurements, the team's theorists verified the ferroelectricity with molecular dynamics simulations that explained the mechanisms behind the observed behavior.


Story Source:

The above story is based on materials provided by DOE/Oak Ridge National Laboratory. Note: Materials may be edited for content and length.


Journal Reference:

  1. Alejandro Heredia, Vincent Meunier, Igor K. Bdikin, José Gracio, Nina Balke, Stephen Jesse, Alexander Tselev, Pratul K. Agarwal, Bobby G. Sumpter, Sergei V. Kalinin, Andrei L. Kholkin. Nanoscale Ferroelectricity in Crystalline γ-Glycine. Advanced Functional Materials, 2012; DOI: 10.1002/adfm.201103011

Cite This Page:

DOE/Oak Ridge National Laboratory. "Boundary between electronics and biology is blurring: First proof of ferroelectricity in simplest amino acid." ScienceDaily. ScienceDaily, 19 April 2012. <www.sciencedaily.com/releases/2012/04/120419121531.htm>.
DOE/Oak Ridge National Laboratory. (2012, April 19). Boundary between electronics and biology is blurring: First proof of ferroelectricity in simplest amino acid. ScienceDaily. Retrieved May 5, 2015 from www.sciencedaily.com/releases/2012/04/120419121531.htm
DOE/Oak Ridge National Laboratory. "Boundary between electronics and biology is blurring: First proof of ferroelectricity in simplest amino acid." ScienceDaily. www.sciencedaily.com/releases/2012/04/120419121531.htm (accessed May 5, 2015).

Share This Page:


Recommended Content
 


Plants & Animals News
May 5, 2015

Latest Headlines
updated 12:56 pm ET