Nanotechnology has the potential to revolutionize the human condition through fundamental contributions to science and technology. The chances of realizing the full potential of nanotechnology have been buttressed by recent demonstrations of rational control and manipulation of matter at the atomic level. Yet, in spite of the remarkable feats achieved in its nascent years, nanotechnology has formidable challenges to overcome in the areas of manufacturing methods, system design, and basic understanding. These challenges have to be overcome before the promise of this new paradigm becomes a reality. The goal of this proposal is to establish a paradigm for real-time use of models in Atomic Force Microscopy (AFM). The concept of using models in real-time has significant potential that has not received the deserved attention by atomic force microscopists as the related tools are primarily employed by engineers. Such a perspective facilitates interpretation of data since it provides a precise means of delineating the effects of the inherent dynamics of the system from the properties of the sample being probed. Thus it provides an effective means of interpreting sample properties. In addition to the proposal goal of laying the foundations of a new paradigm, specific aims of the proposal will result in a new ultrafast investigation tool for AFM, termed the Transient Force Detector (TFD). The prototype will yield hundred thousand features per second detection rates without compromising sample size and resolution. A particular advantage of the TFD is that the resolution of the detection process, dependent on the quality factor of the cantilever probe, is decoupled from the speed of the detection process. Issues of the loss of the probe signal and high resolution imaging based on the likelihood that the probe is detecting the sample will be addressed. Use of models in realtime is very well suited to explore model based imaging where a more detailed information is desired when compared to detection. A finer characterization of the sample will result only if cantilever-sample interaction models amenable for real-time use are available. Based on averaging theory, a methodology is proposed to extract sample characteristics that include topography, local stiffness and local damping at the nanoscale. This includes a parallel operation where the sample characteristics will be gleaned by real-time models built on the results of the averaging analysis of the tip-sample dynamics. Observer theory based active modification of the cantilever probe is presented. This systems viewpoint opens up new vistas for tailoring bandwidth, resolution and forces on the tip and sample. This enhanced flexibility is absent from the present set of tools on modifying the cantilever dynamics. The innovative methods to be developed in the proposed investigation will be complemented by the existing and future experimental facilities. Preliminary proof of concept results indicate the vast potential of the model based imaging paradigm presented. Broader Impacts: Micro-cantilevers are being used in diverse areas with increasing impact and has in- fluenced science in a fundamental manner. The methods proposed are enabling technologies and will open doors for investigating basic science issues by providing ultra-high bandwidth and resolution. The innovative contributions of the proposals will directly impact most aspects of scanning probe microscopy, as the proposed methods apply to most of the existing setups. For example, it will directly impact the extremely high density data storage (3 Tb/in2) and read out technologies as well as the array technologies employed by the bio industry. The experimental aspects of the proposed research will be accomplished in collaboration with Asylum Research, and Bioforce Nanosciences Inc. both leading biology related scanning probe microscope (SPM) company. This collaboration is expected to foster transfer of the theory and technology developed in this program between the academic institution of the PI and the SPM industry. The PI has successfully disseminated the system and control theory viewpoints to the physics community that is heavily involved in scanning probe microscopy. Under this proposal goals the PI will continue to push the synergistic transfer of knowhow between the two communities by exchanging student visits and presenting specialized workshops. A web based remote operation of SPMs is being explored by the PI in collaboration with Asylum Research that can be used for remote operation that will aid this effort.

Project Start
Project End
Budget Start
2006-05-01
Budget End
2008-06-30
Support Year
Fiscal Year
2006
Total Cost
$209,961
Indirect Cost
Name
Iowa State University
Department
Type
DUNS #
City
Ames
State
IA
Country
United States
Zip Code
50011