| United
States Patent |
7,367,186 |
| Clements
|
May 6, 2008
|
Wireless
technique for microactivation
Abstract
The present invention is a method and apparatus for achieving
high work
output per unit volume in micro-robotic actuators, and in particular
TiNi
actuators. Such actuators are attractive as a means of powering
nano-robotic movement, and are being developed for manipulation of
structures at near the molecular scale. In these very small devices
(one
micron scale), one means of delivery of energy is by electron beams.
Movement of mechanical structures a few microns in extent has been
demonstrated in a scanning electron microscope. Results of these and
subsequent experiments will be described, with a description of
potential
structures for fabricating moving a microscopic x-y stage.
| Inventors:
|
Clements;
Ken (Los Gatos, CA) |
| Assignee: |
Technology Innovations, Inc.
(Pittsford, NY)
|
| Appl. No.:
|
10/449,351 |
| Filed:
|
May
30, 2003 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
|
| |
10058887 |
Jan., 2002 |
6588208 |
|
|
| |
60264741 |
Jan., 2001 |
|
|
|
| |
| Current
U.S. Class: |
60/527
; 60/528 |
| Current
International Class: |
F01B
29/10 (20060101) |
| Field
of Search: |
60/527,528
|
References Cited [Referenced
By]
U.S. Patent Documents
Foreign Patent Documents
|
|
|
|
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|
WO 00/34536 |
|
Jun., 2000 |
|
WO |
|
Primary Examiner: Nguyen; Hoang
Attorney, Agent or Firm: Basch;
Duane C.
Basch & Nickerson LLP
Parent Case Text
This application is a continuation of U.S. patent application Ser. No.
10/058,887 by K. Clements, now U.S. Pat. No. 6,588,208. filed Jan. 28,
2002 for a Wireless Technique for Microactivation," which claims
priority
from U.S. Provisional Application for patent, Ser. No. 60/264,741,
filed
Jan. 29, 2001, the contents of which are hereby incorporated by
reference
in their entirety.
Claims
What is claimed is:
1. A method for driving a shape memory alloy actuator, including the
steps of: pre-straining a shape memory alloy in its low-temperature
state to produce a shape memory
actuator; subsequently, heating the shape memory alloy actuator above
its phase transformation temperature using a focused beam so as to
cause a first portion of the shape memory alloy actuator to move
relative to a second portion; and observing
movement of the actuator using the focused beam.
2. The method of claim 1, further including a software feedback loop,
wherein said feedback loop provides wireless control of the shape
memory alloy actuator.
3. The method of claim 1, wherein the focused beam is a photon beam.
4. The method of claim 1, wherein the focused beam is a phonon beam.
Description
This invention relates generally to production and operation of
microactuators by focused beam energy, and more
particularly to a wireless technique for both control and energy, as
well as the return path for observation and data.
The following related publications are also hereby incorporated by
reference for their teachings:
K. Eric Drexler, Engines of Creation: the coming era of nanotechnology,
Anchor Doubleday, 1986;
K. Eric Drexler, Nanosystems, Molecular Machinery, Manufacturing, and
Computation, John Wiley & Sons, Inc., 1992;
James R. von Ehr, Zyvex "the first nanotechnology development company",
http://www.zyvex.com;
M F Yu, M. J. Dyer, G. D. Skidmore, H. W. Rohrs, X K Lu, K. D. Ausman,
J. R. Von Ehr, R. S. Ruoff, 3 Dimensional Manipulation of Carbon
Nanotubes under a Scanning Electron Microscope, Sixth Foresight
Conference 1998;
A. D. Johnson, "Vacuum-Deposited TiNi Shape memory Film:
Characterization and Applications in Micro-Devices," J. Micromech.
Microeng. 1(1991) 34-41;
P. Krulevitch, A. P. Lee, P. B. Ramsey, J. C. Trevino, J. Hamilton, M.
A. Northrup, "Thin film Shape Memory Alloy Microactuators, J. MEMS,
vol. 5, No. 4, December 1996 (showing that SMA has the highest work
output per unit volume of any actuating
technology); and
Deepak Srivastava, NASA Ames research Center, Moffeft Field, 650 604
3468 deepak@nasa.gov; private communication to Vikas Galhotra at TiNi
Alloy Company.
BACKGROUND AND SUMMARY OF THE INVENTION
In 1982 K. Eric Drexler introduced the idea of assemblers of molecular
size in his book "Engines of Creation" (cited above). Nanotechnology is
the subject of at least one international conference, and one
commercial venture has been organized
and funded to invest research and planning in this technology. Although
commercial realization of nanotechnology may be years away, there is
strong indication that research following the human genome project, and
particularly the study of protein
structure and function, will require tools to manipulate components of
the cell. Development of these tools is a demanding, exciting, and
challenging research subject.
Miniaturization of mechanical devices is evolving toward nanometer
scale, requiring handling and assembly of objects as small as a few
nanometers. Manipulation of samples and specimens smaller than a few
microns in size demands a technology
that, at present, does not exist. Assemblers are needed that can grip
collections of molecules, releasing them from their present location,
lifting, rotating, and forcefully placing them in a new environment.
Existing micropositioners do not provide the requisite flexibility of
motion for assembly tasks that are contemplated. Forceful shape memory
alloy actuators can be scaled to micron size. These devices are
thermally powered and so require a
source of heat energy: this heat may be supplied by conduction, joule
heating, infrared light, or other means. The present invention
contemplates the use of a scanning electron microscope beam to provide
heat energy to energize thermal actuators. Prototype actuators are
fabricated by sputter deposition of titanium-nickel thin film,
photolithographic patterning, and chemical milling. A scanning electron
beam is positioned to produce local heating, and to observe the
resulting motion.
Atomic force microscopy can be used to move individual atoms but not to
grip larger objects with enough force to hold against local forces. In
recent investigations of the properties of carbon nanotubes,
piezoelectric stepper motors have been
used to manipulate structures orders of magnitude smaller than the
drivers (see MF Yu et al. in "3 Dimensional Manipulation of Carbon
Nanotubes under a Scanning Electron Microscope"). Manipulation of
objects this small would be improved if the
end-effectors were not much larger than the objects they control. In
analogy to the shoulder-wrist-finger arrangement of the human hand,
gross positioning should be managed by actuators of macroscopic size,
and fine control by end-effectors of much
smaller size.
The force of actuation should be produced as close as possible to the
point of application. This implies that manipulation of sub-micron size
objects requires micron-size actuators. Conventional actuators
(electromagnetic, piezoelectric) do not
scale well to micron size. A promising form of actuation is
heat-actuated devices, particularly shape memory actuators.
Photolithography provides means of fabricating devices of sub-micron
size. Miniature shape memory alloy (SMA) actuators rely on
joule heating to cause the phase change. In the sub-micron range it is
difficult to make electrical connection, especially on devices that
move. To solve this problem, the present invention focuses on the
actuation of sub-micron scale shape memory
alloy devices by electron-beam excitation.
The present invention is directed to the operation of microactuators by
focused beam energy. Whereas microactuators now require wires or tubes
attached to get the energy and control signals down to them, this
invention discloses a wireless
technique for both control and energy, as well as the return path for
observation and data.
Current devices are fabricated as small as a few hundred microns using
conventional microlithography. Shrinking this technology to sub-micron
dimensions has raised at least two questions: (i) Will the shape memory
property be preserved when the
dimensions are as small or smaller than the crystal domains? And (ii)
How can such small objects (sub-micron) be selectively heated to
produce actuation? The present invention, based upon research conducted
to answer such questions, provides preliminary proof-of-concept.
In accordance with the present invention, there is provided a method
for driving a shape memory alloy actuator, including the steps of:
pre-straining a shape memory alloy in its low-temperature state; and
subsequently, heating the shape memory
alloy above its phase transformation temperature using a focused beam.
One aspect of the invention is based on the discovery of techniques for
achieving high work output per unit volume in micro-robotic actuators,
and in particular TiNi and similar actuators. Such actuators are
attractive as a means of powering
nano-robotic movement, and are sitable for manipulation of structures
at or near the molecular scale. In these very small devices (one micron
scale), one means of delivery of energy is by electron beams. Movement
of mechanical structures a few microns
in extent has been demonstrated in a scanning electron microscope.
Results of these and subsequent experiments will be described, with a
description of potential structures for fabricating moving a
microscopic x-y stage.
BRIEF DESCRIPTION OF THE
DRAWINGS
FIG. 1 is a graph of resistivity versus temperature for an exemplary
TiNi film sputter-deposited on silicon oxide in accordance with an
aspect of the present invention;
FIG. 2 is a scanning electron beam image of TiNi film with
fenestrations;
FIG. 3 is a heated sample holder for a scanning electron microscope in
accordance with an aspect of the present invention;
FIGS. 4a-4c are a sequence of images from the SEM showing the results
of heating the TiNi specimen by SEM electron beam; and
FIGS. 5a and 5b are illustrative schematics of a single-direction
platform moved by microactuators in accordance with an aspect of the
present invention.
The present invention will be described in connection with a preferred
embodiment, however, it will be understood that there is no intent to
limit the invention to the embodiment described. On the contrary, the
intent is to cover all
alternatives, modifications, and equivalents as may be included within
the spirit and scope of the invention as defined by the appended
claims.
DESCRIPTION OF THE PREFERRED EMBODIMENT
For a general understanding of the present invention, reference is made
to the drawings. In the drawings, like reference numerals have been
used throughout to designate identical elements.
As depicted by information in the associated figures, the present
invention is directed to the operation of microactuators by focused
beam energy. As depicted in the graph of FIG. 1, memory property may be
preserved when the dimensions of a
device are as small or smaller than the crystal domains. For example, a
film approximately 100 nanometers (nm) (about 200 atomic layers) thick
was shown to undergo a phase transformation as indicated by a change in
resistivity. The change in slope and
hysteresis loop are typical for TiNi shape memory alloy (SMA).
As noted herein, a scanning electron microscope electron beam (e-beam)
may be used to provide the heat energy, and beam steering can bring a
spot of energy a fraction of a micron in diameter to bear on a sample.
Therefore, the questions of how
much power must be delivered to the sample, and whether the beam can
provide this much energy in a short enough time to effect a shape
change were addressed.
The estimated energy required to actuate a TiNi specimen
4.times.10.times.100 microns by heating it from the room temperature to
the transition point is about 1.3.times.10.sup.-5 joules (DT=.about.80
C, DH=.about.25 J/gm, Cp=.about.0.3 J/gm
.degree. C., density=6.4 gm/cm.sup.3). The power available from the
electron beam is 2.times.10.sup.-3 watt (for accelerating voltage
.about.20 KV and beam current .about.10-7 A) and the estimated heating
time is .about.6.times.10.sup.-3 sec.
Demonstration of shape recovery requires that the specimen be
pre-strained (stretched, compressed, or bent) while it is in its
low-temperature state and then heated above the phase transformation
temperature. The sample used was a fragment of
TiNi film 4 micrometers thick deposited on silicon oxide, and patterned
with fenestrations about 40 microns in diameter, and removed from the
substrate. This film was further etched to diminish the width and
thickness of the web elements. The resulting
Web was torn apart, producing small protrusions about 1-2 micron wide
and 20 microns long. Referring to FIG. 2, one such structure is
depicted in the micrograph. Some of these were bent during tearing,
others were deformed manually using a
micromanipulator.
Once the structures were isolated, the specimen was placed on a heated
pedestal in an ISI-SS60 scanning electron microscope. The pedestal was
equipped with a heater and thermocouple so that the base temperature of
the structure could be
controlled and measured. An exemplary fixture is depicted in FIG. 3
against a size reference. Fluke instruments were used to record
temperature and current through the heater, and an IRF 640 field-effect
transistor, with a variable gate voltage, was
used to control the current through the heater to vary the temperature
of the substrate.
Subsequently, the chamber was evacuated and the e-beam was started. A
picture was obtained at 1.5 kx magnification. The sample holder was
heated with resistance heater to a temperature above ambient of
approximately 40.degree. C. and
approximately 10.degree. C. below the transition temperature around
45-50.degree. C. of the TiNi. This was to enable the electron beam to
bring the temperature through a relatively small temperature change to
effect the phase transformation. The beam
was centered approximately on the bent portion of the microbeam as
indicated by reference arrow 10. It should be further appreciated that
the amount of pre-heating energy applied influences the amount of power
that must be applied by the focused
beam--the lower the pre-heat temperature of the shape memory alloy, the
more energy that must be applied by the beam.
The SEM beam aperture was opened to impart the maximum current to the
specimen, using spot mode, and current in the e-beam was increased.
Typical current used was in the range of 70 to 100 nano-amperes
measured with a Kiethley picoammeter
connected between the sample and ground potential. This current was
applied to the sample for a time between 2 and 10 seconds, although
other exposure times may be suitable. After exposure, the beam current
was reduced and further pictures taken.
The resultant movement of the structure are shown in FIGS. 4a through
4c. In particular, image FIG. 4a shows the sample previous to heating.
Images 4b and 4c, in turn, show the progressive actuation as successive
parts of the device were heated
by the electron beam. Approximately thirty degrees of recovery was
achieved, although other levels may be possible depending upon the
structure characteristics. Accordingly, the lever achieved in the
experimental design is about 2 microns in diameter
and 20 microns long.
As a result of the initial experiments, the micro-cantilever moving
about thirty degrees from its original position was not due to thermal
expansion as it did not reverse when the temperature was reduced. Thus,
actuation of a micro-scale device
by scanning electron beam was demonstrated, showing that the e-beam can
provide enough energy to cause the phase transformation (and resultant
movement) under controlled conditions.
Using such information, the present invention is directed toward a
number of alternative embodiments. One such embodiment, depicted in
FIGS. 5a and 5b, contemplates construction of a platform 18 and
providing molecular and nano-level x-y motion
using pairs of opposed bending cantilevers 20, so that partial
actuation of one cantilever pushes the platform in the direction of the
arrow while pre-straining the opposing cantilever. Similarly, it is
believed that larger-scale, translational motion
can be achieved with multiple actuators operating in sequence against a
ratcheting or similar advancement mechanism.
In the electron microscope embodiment described herein, it is further
contemplated as part of the invention, that the normal beam is used for
both causing and observing movement of the memory alloy segment or
structure. Moreover, a software or
similar feedback loop may be implemented, perhaps providing wireless
control of microrobotic systems. Analogous actions can be done in the
optical and ultrasonic embodiments described below.
In an alternative to the e-beam embodiment described above, it is also
contemplated that aspects of the present invention may be implemented
using laser energy in an optical microscope. It will be appreciated by
those skilled in the art that the
concept is the same in both cases; a beam of energy focused on a shaped
memory alloy segment will produce local heating of the segment, giving
rise to movement.
In accordance with the embodiments described herein, SMA microactuators
may be produced to provide the "muscles" of tiny robots that are
fabricated by MEMS technology on silicon wafers. It will be further
appreciated that such structures may be
employed for fabricating other nanotechnology devices and elements, and
particularly for moving a microscopic x-y stage. However, this
invention is also applicable to nanotechnology where the nanoactuators
are large molecules that are undergoing shape
transformations as a result of interactions with focused beam energy
such as photons, particle beams (such as electrons), or phonons
(ultrasound).
In recapitulation, the present invention is a method and apparatus for
the production and operation of microactuators by focused beam energy,
and more particularly to a wireless technique for both control and
energy, as well as the return path
for observation and data.
It is, therefore, apparent that there has been provided, in accordance
with the present invention, a method and apparatus for the creation and
application of microactuators. While this invention has been described
in conjunction with preferred
embodiments thereof, it is evident that many alternatives,
modifications, and variations will be apparent to those skilled in the
art. Accordingly, it is intended to embrace all such alternatives,
modifications and variations that fall within the spirit
and broad scope of the appended claims.