Asylum Research manufactures advanced Atomic Force/Scanning Probe Microscopy instruments and accessories

Nanograde - Large stock of customized nanoparticles

Park Systems - Manufacturer of a complete range of AFM solutions

Defects at Grain Boundary in Ultrananocrystalline Diamond Hold Responsibility for Fundamental Mechanism of Energy Dissipation

Posted in | Nanoanalysis | Nanomaterials

Email / Share

Back One

Popular
Latest
Random

Researchers Produces New Type of Lighting Component using Graphene

LANL's Top 10 Science Stories in 2009

OSRAM, Philips and AIXTRON Project Partners in BMBF's OLED Initiative

New Composite Material that Could Revolutionise Car Design and Manufacturing

Recipe for Making Conductive Textile

Scientists Observe Electrons in Semiconductor on the Brink of Metal-Insulator Transition for First Time

Atomistic Simulation Studies of Cement Components

Collaboration at CNSE's Albany NanoTech Complex to Accelerate Mask, Source, and Manufacturing Solutions

Community College Students Begin Hands-On Learning With State-of-the-Art Nanotechnology Equipment and Curriculum

New Perspective for Understanding Mechanisms of Catalytic Conversion

Andor Technology and JPK Instruments Offer EMCCD-NanoWizard Compatibility

New Behaviours Could Lead to Faster Optical Information Processing and Cooler Computers

New Approach in the Design of Miniature Insectlike Microids

Avisio Subsidiary Diagnostic Nano Technology Corp Begins Testing Technology on Detection of H1N1 Virus

World's Most Cost-Effective Water Purifier Improves Affordability of Safe Drinking Water for Millions of Indian Families

Tab options

Researchers in the Nanofabrication and Devices group at the Argonne National Laboratory, in collaboration with the University of Pennsylvania, Advanced Diamond Technologies Inc., and Innovative Micro Technology, have discovered that defects at the grain boundary in ultrananocrystalline diamond (UNCD) hold primary responsibility for the fundamental mechanism of energy dissipation.

SEM micrograph of fabricated UNCD microresonator
SEM micrograph of fabricated UNCD microresonator

Because of a high Young's modulus and high sound propagation velocity, UNCD materials hold potential for fabricating high-frequency microelectromechanical (MEMS) resonators.

However, their mechanical dissipation at high frequency, which is important for developing high-frequency resonator applications, is not well understood. Dissipation in UNCD cantilevers was determined by using ring-down measurement under ultrahigh-vacuum conditions, and the quality factor measured in the range of 5000-16000 at kHz resonance frequencies.

These studies reveal that dissipation in UNCD films is mainly due to the presence of defects such as nondiamond-carbon bonding at grain boundaries.

More information: V. P. Adiga, A. V. Sumant, S. Suresh, C, Gudeman, O. Auciello, J. A. Carlisle, R. W. Carpick, "Mechanical stiffness and dissipation in ultrananocrystalline diamond microresonators," Phys. Rev. B, 79, 245403 (2009)

Posted August 12th, 2009