New! Sign up for our free email newsletter.
Science News
from research organizations

Silver nanowires demonstrate unexpected self-healing mechanism: Potential for flexible electronics

Date:
January 23, 2015
Source:
Northwestern University
Summary:
Researchers found that silver nanowires can withstand strong cyclic loads, which is a key attribute needed for flexible electronics.
Share:
FULL STORY

With its high electrical conductivity and optical transparency, indium tin oxide is one of the most widely used materials for touchscreens, plasma displays, and flexible electronics. But its rapidly escalating price has forced the electronics industry to search for other alternatives.

One potential and more cost-effective alternative is a film made with silver nanowires--wires so extremely thin that they are one-dimensional--embedded in flexible polymers. Like indium tin oxide, this material is transparent and conductive. But development has stalled because scientists lack a fundamental understanding of its mechanical properties.

Now Horacio Espinosa, the James N. and Nancy J. Farley Professor in Manufacturing and Entrepreneurship at Northwestern University's McCormick School of Engineering, has led research that expands the understanding of silver nanowires' behavior in electronics.

Espinosa and his team investigated the material's cyclic loading, which is an important part of fatigue analysis because it shows how the material reacts to fluctuating loads of stress.

"Cyclic loading is an important material behavior that must be investigated for realizing the potential applications of using silver nanowires in electronics," Espinosa said. "Knowledge of such behavior allows designers to understand how these conductive films fail and how to improve their durability."

By varying the tension on silver nanowires thinner than 120 nanometers and monitoring their deformation with electron microscopy, the research team characterized the cyclic mechanical behavior. They found that permanent deformation was partially recoverable in the studied nanowires, meaning that some of the material's defects actually self-healed and disappeared upon cyclic loading. These results indicate that silver nanowires could potentially withstand strong cyclic loads for long periods of time, which is a key attribute needed for flexible electronics.

"These silver nanowires show mechanical properties that are quite unexpected," Espinosa said. "We had to develop new experimental techniques to be able to measure this novel material property."

The findings were recently featured on the cover of the journal Nano Letters. Other Northwestern coauthors on the paper are Rodrigo Bernal, a recently graduated PhD student in Espinosa's lab, and Jiaxing Huang, associate professor of materials science and engineering in McCormick.

"The next step is to understand how this recovery influences the behavior of these materials when they are flexed millions of times," said Bernal, first author of the paper.


Story Source:

Materials provided by Northwestern University. Note: Content may be edited for style and length.


Journal Reference:

  1. Rodrigo A. Bernal, Amin Aghaei, Sangjun Lee, Seunghwa Ryu, Kwonnam Sohn, Jiaxing Huang, Wei Cai, Horacio Espinosa. Intrinsic Bauschinger Effect and Recoverable Plasticity in Pentatwinned Silver Nanowires Tested in Tension. Nano Letters, 2015; 15 (1): 139 DOI: 10.1021/nl503237t

Cite This Page:

Northwestern University. "Silver nanowires demonstrate unexpected self-healing mechanism: Potential for flexible electronics." ScienceDaily. ScienceDaily, 23 January 2015. <www.sciencedaily.com/releases/2015/01/150123110756.htm>.
Northwestern University. (2015, January 23). Silver nanowires demonstrate unexpected self-healing mechanism: Potential for flexible electronics. ScienceDaily. Retrieved October 10, 2024 from www.sciencedaily.com/releases/2015/01/150123110756.htm
Northwestern University. "Silver nanowires demonstrate unexpected self-healing mechanism: Potential for flexible electronics." ScienceDaily. www.sciencedaily.com/releases/2015/01/150123110756.htm (accessed October 10, 2024).

Explore More

from ScienceDaily

RELATED STORIES