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Lecture-9 SIMS NDT with all detail in method.ppt
1. Lecture-9 SIMS & NDT
• SIMS
Basic Principles
Instrumentation
Mass Resolution
Modes of Analysis
Applications
• Non-Destructive Analysis (NDA)
or Non-Destructive Testing (NDT)
2. Instrumentation
SIMS CAMECA 6F
Ion Sources
• Ion sources with electron impact ionization - Duoplasmatron: Ar+, O2
+, O-
• Ion sources with surface ionization - Cs+ ion sources
• Ion sources with field emission - Ga+ liquid metal ion sources
Mass Analyzers
• Magnetic sector analyzer
• Quadrupole mass analyzer
• Time of flight analyzer
Ion Detectors
• Faraday cup
• Dynode electron multiplier
Ip
Is Ion sources
Ion detectors
Mass Analyzers
Mass analyzers
Vacuum < 10−6 torr
http://www.youtube.com/watch?v=IO-KCjxznLs to~1:50
Bombardment of a sample surface with a primary ion beam followed by mass spectrometry
of the emitted secondary ions constitutes secondary ion mass spectrometry (SIMS).
3. Cameca SIMS
Accelerating voltage
Secondary ions have low kinetic
energies from zero to a few
hundred eV.
L1, L2 and L3 - electromagnetic lens
http://www.eaglabs.com/mc/sims-instrumentation.html
4. Energy Analyzer and Mass Spectrometer
ESA bends lower energy ions more strongly than higher energy ions. The sputtering
process produces a range of ion energies. An energy slit can be set to intercept the high
energy ions. Sweeping the magnetic field in MA provides the separation of ions
according to mass-to-charge ratios in time sequence.
Mass Analyzer (MA)
Magnet Sector
Electrostatic
Sector
E
r - radius of curvature of an ion
http://www.youtube.com/watch?v=lxAfw1rftIA at~1:00-4:12
Energy
Focal plane
Degree (r) of deflection of
ions by the magnetic filed
depends on m/q ratio.
V - ion acceleration voltage
https://www.youtube.com/watch?v=EzvQzImBuq8 to~2:06
https://www.youtube.com/watch?v=NuIH9-6Fm6U at~3:40-5:16
5. Basic Equations of Mass Spectrometry
2
1
2
mv zV
2
/
F mv R
F Bzv
2
/
mv R Bzv
2 2
/ / 2
m z B R V
Ion’s kinetic E function of
accelerating voltage (V) and
charge (z).
Centrifugal force
Applied magnetic field
Lorentz force
Balance as ion goes
through flight tube
Fundamental equation of mass spectrometry
Combine equations to obtain:
Change ‘mass-to-charge’ (m/z) ratio by
changing V or changing B.
NOTE: if B, V, z constant, then:
r m
m/z = m/e
for singly charged ions
r - radius of circular ion path
r
r
r
7. Ion Detectors
Faraday Cup
Secondary electron Multiplier
20 dynodes Current gain 107
A Faraday cup measures the
ion current hitting a metal
cup, and is sometimes used
for high current secondary ion
signals. With an electron
multiplier an impact of a
single ion starts off an
electron cascade, resulting in
a pulse of 108 electrons
which is recorded directly.
Usually it is combined with a
fluorescent screen, and
signals are recorded either
with a CCD-camera or with a
fluorescence detector.
http://www.eaglabs.com/mc/sims-secondary-ion-detectors.html#next
https://www.youtube.com/watch?v=NuIH9-6Fm6U at~5:18-6:50 and to~9:25
10. Time of Flight (TOF) SIMS - Reflectron
(TOF) SIMS enables the analysis of an
unlimited mass range with high sensitivity and
quasi-simultaneous detection of all secondary
ions collected by the mass spectrometer.
TOF SIMS is based on the fact that ions with
the same energy but different masses travel
with different velocities. Basically, ions formed
by a short ionization event are accelerated by
an electrostatic field to a common energy and
travel over a drift path to the detector. The
lighter ones arrive before the heavier ones and
a mass spectrum is recorded. Measuring the
flight time for each ion allows the
determination of its mass.
Schematic of time of flight (TOF)
spectrometer - reflectron
http://www.youtube.com/watch?v=ZoAUxsEBUnk TOF-SIMS
http://www.youtube.com/watch?v=KAWu6SmvHjc
11. Time of Flight (TOF) Spectrometer
TOF operates in a pulse mode.
pulse width
In order to provide higher resolution the pulse
should be as narrow as 1-10 ns. The pulse
repetition frequency is usually in a kHz range.
During a short pulse of E, ions are
accelerated and acquire a constant
kinetic energy:
kinetic energy = mv2/2
but have different m/q and Vs.
Thus they arrive to the detector in
time sequence after travel the same
distance. Time required to travel
distance l from the ion origin to the
detector is:
The light ions with higher Vs arrive
to the detector first.
Schematic of TOF spectrometer with a spectrum
12.
13. SIMS can do trace element analysis
Detection limit
is affected by
WDS ~100ppm
EDS ~1000ppm
18. Dynamic SIMS involves the use of a much higher energy primary beam (larger amp
beam current). It is used to generate sample depth profiles. The higher ion flux eats
away at the surface of the sample, burying the beam steadily deeper into the sample
and generating secondary ions that characterize the composition at varying depths. The
beam typically consists of O2
+ or Cs+ ions and has a diameter of less than 10 μm. The
experiment time is typically less than a second. Ion yield changes with time as primary
particles build up on the material effecting the ejection and path of secondary ions.
Dynamic Secondary Ion Mass Spectrometry
21. Crater Effect
(a)
(b)
(a) Ions sputtered from a selected central
area (using a physical aperture or electronic
gating) of the crater are passed into the mass
spectrometer.
(b) The beam is usually swept over a large
area of the sample and signal detected from
the central portion of the sweep. This avoids
crater edge effects.
The analyzed area is usually required to
be at least a factor of 3 3 smaller than
the scanned area.
27. Mapping Chemical Elements
The example (microbeam) images show a pyrite (FeS2) grain from a sample of
gold ore with gold located in the rims of the pyrite grains. The image numerical
scales and associated colors represent different ranges of secondary ion
intensities per pixel.
Some instruments simultaneously produce high mass resolution and high
lateral resolution. However, the SIMS analyst must trade high sensitivity for
high lateral resolution because focusing the primary beam to smaller
diameters also reduces beam intensity. High lateral resolution is required
for mapping chemical elements.
34 S
197 AU
28. SIMS can be used to determine the composition of organic and
inorganic solids at the outer 5 nm of a sample.
To determine the composition of the sample at varying spatial and
depth resolutions depending on the method used. This can generate
spatial or depth profiles of elemental or molecular concentrations.
These profiles can be used to generate element specific images of
the sample that display the varying concentrations over the area of
the sample.
To detect impurities or trace elements, especially in semi-
conductors and thin filaments.
Secondary ion images have resolution on the order of 0.5 to 5 μm.
Detection limits for trace elements range between 1012 to 1016
atoms/cc.
Spatial resolution is determined by primary ion beam widths, which
can be as small as 100 nm.
Summary
SIMS is the most sensitive elemental and isotopic surface
microanalysis technique (bulk concentrations of impurities
of around 1 part-per-billion). However, very expensive.
http://www.youtube.com/watch?v=QTjZutbLRu0 at~1:38-2:14 advantages and disadvantages of SIMS
29. Review Questions for SIMS
• What are matrix effects?
• What is the difference between ion yield
and sputtering yield?
• When are oxygen and cesium ions used as
primary ions?
• What is mass resolution?
• How can depth resolution be improved?
• Applications of SIMS
• Advantages and disadvantages of SIMS
30. Non-destructive Analysis (NDA)
Non-destructive Testing (NDT)
https://www.nde-ed.org/index_flash.php
Introduction to NDT
Overview of Six Most Common NDT Methods
Selected Applications
https://www.youtube.com/watch?v=tlE3eK0g6vU NDT very good
31. The use of noninvasive
techniques to determine
the integrity of a material,
component or structure
or
quantitatively measure
some characteristic of
an object.
i.e. Inspect or measure without doing harm.
Definition of NDT
32. What are Some Uses
of NDT Methods?
• Flaw Detection and Evaluation
• Leak Detection
• Location Determination
• Dimensional Measurements
• Structure and Microstructure Characterization
• Estimation of Mechanical and Physical Properties
• Material Sorting and Chemical Composition
Determination
Fluorescent penetrant indication
33. Why Nondestructive?
• Test piece too precious to be destroyed
• Test piece to be reused after inspection
• Test piece is in service
• For quality control purpose
• Something you simply cannot do harm
to, e.g. fetus in mother’s uterus
34. When are NDE Methods Used?
–To assist in product development
–To screen or sort incoming materials
–To monitor, improve or control
manufacturing processes
–To verify proper processing such as
heat treating
–To verify proper assembly
–To inspect for in-service damage
There are NDE applications at almost any stage
in the production or life cycle of a component.
35. Six Most Common NDT Methods
• Visual
• Liquid Penetrant
• Magnetic
• Ultrasonic
• Eddy Current
• Radiography
Detection of surface flaws
Detection of internal flaws
36. Most basic and common
inspection method.
Tools include
fiberscopes,
borescopes, magnifying
glasses and mirrors.
Robotic crawlers permit
observation in hazardous or
tight areas, such as air
ducts, reactors, pipelines.
Portable video inspection
unit with zoom allows
inspection of large tanks
and vessels, railroad tank
cars, sewer lines.
1. Visual Inspection
37. https://www.youtube.com/watch?v=tlE3eK0g6vU at~2:48-3:33 https://www.youtube.com/watch?v=bHTRmTQDZzg
• A liquid with high surface wetting characteristics
is applied to the surface of the part and allowed
time to seep into surface breaking defects.
• The excess liquid is removed from the surface
of the part.
• A developer (powder) is applied to pull the
trapped penetrant out the defect and spread it
on the surface where it can be seen.
• Visual inspection is the final step in the
process. The penetrant used is often loaded
with a fluorescent dye and the inspection is
done under UV light to increase test
sensitivity.
Liquid Penetrant Inspection
High surface wetting
Low surface wetting
https://www.youtube.com/watch?v=xEK-c1pkTUI to~2:26
38. • A NDT method used for defect detection. Fast and relatively
easy to apply and part surface preparation is not as critical as
for some other NDT methods. – MPI one of the most widely
utilized nondestructive testing methods.
• MPI uses magnetic fields and small magnetic particles, such
as iron filings to detect flaws in components. The only
requirement from an inspectability standpoint is that the
component being inspected must be made of a
ferromagnetic material such as iron, nickel, cobalt, or
some of their alloys. Ferromagnetic materials are materials
that can be magnetized to a level that will allow the inspection
to be effective.
• The method is used to inspect a variety of product forms such
as castings, forgings, and weldments. Many different
industries use MPI for determining a component's fitness-
for-use. Some examples of industries that use magnetic
particle inspection are the structural steel, automotive,
petrochemical, power generation, and aerospace industries.
Underwater inspection is another area where magnetic particle
inspection may be used to test such things as offshore
structures and underwater pipelines.
Magnetic Particle Inspection (MPI)
https://www.youtube.com/watch?v=tlE3eK0g6vU at~1:10-2:48 MPI
https://www.nde-ed.org/EducationResources/CommunityCollege/MagParticle/cc_mpi_index.php
39. Magnetic Particle Inspection
The part is magnetized. Finely milled iron particles coated with a
dye pigment are then applied to the specimen. These particles
are attracted to magnetic flux leakage fields and will cluster to
form an indication directly over the discontinuity. This indication
can be visually detected under proper lighting conditions.
Flux leakage
The magnetic particles form a
ridge many times wider than
the crack itself, thus making the
otherwise invisible crack visible.
Cracks just below the surface
can also be revealed.
Relative direction between the
magnetic field and the defect
line is important.
https://www.youtube.com/watch?v=qpgcD5k1494 to~3:03
https://www.youtube.com/watch?v=dQoB7jpxSe8 MPI testing procedure
40. Magnetic particles
• Pulverized iron oxide (Fe3O4) or
carbonyl iron powder can be used
• Colored or even fluorescent
magnetic powder can be used to
increase visibility
• Powder can either be used dry or
suspended in liquid
41. Examples of visible dry magnetic particle indications
Indication of a crack in a saw blade Indication of cracks in a weldment
Before and after inspection pictures of
cracks emanating from a hole
Indication of cracks running between
attachment holes in a hinge
42. Examples of Fluorescent Wet Magnetic
Particle Indications
Magnetic particle wet fluorescent
indication of a cracks in a drive shaft
Magnetic
particle wet
fluorescent
indication of
a crack in a
bearing
Magnetic particle wet fluorescent
indication of a cracks at a
fastener hole
43. One of the most dependable and sensitive
methods for surface defects
fast, simple and inexpensive
direct, visible indication on surface
unaffected by possible deposits, e.g. oil,
grease or other metals chips, in the cracks
can be used on painted objects
results readily documented with photo or tape
impression
Advantages of MPI
44. Limitations of MPI
Only good for ferromagnetic materials
sub-surface defects will not always be
indicated
relative direction between the magnetic field
and the defect line is important
objects must be demagnetized before and
after the examination
the current magnetization may cause burn
scars on the item examined
45. The most commonly used
ultrasonic testing technique is
pulse echo, whereby sound is
introduced into a test object
and reflections (echoes) from
internal imperfections or the
part's geometrical surfaces are
returned to a receiver. The
time interval between the
transmission and reception of
pulses give clues to the
internal structure of the
material.
Ultrasonic Inspection
(Pulse-Echo)
In ultrasonic testing, high-frequency
sound waves are transmitted into a
material to detect imperfections or to
locate changes in material properties.
https://www.youtube.com/watch?v=tlE3eK0g6vU at~6:45-8:00 or to 11:35
https://www.youtube.com/watch?v=gqJN8tyosDw to~0:42
46. High frequency sound waves are introduced into a material and
they are reflected back from surfaces or flaws.
Reflected sound energy is displayed versus time, and inspector
can visualize a cross section of the specimen showing the depth
of features that reflect sound.
f
Oscilloscope, or flaw detector screen
Ultrasonic Inspection (Pulse-Echo)
https://www.youtube.com/watch?v=UM6XKvXWVFA at~1:18-3:08
http://www.doitpoms.ac.uk/tlplib/piezoelectrics/applications.php
Principle of ultrasonic testing
LEFT: A probe sends a sound wave
into a test material. There are two
indications, one from the initial
pulse of the probe, and the second
due to the back wall echo.
RIGHT: A defect creates a third
indication and simultaneously
reduces the amplitude of the back
wall indication. The depth of the
defect is determined by the
ratio D/Ep
Ultrasonic Probe
Ultrasonic probe is made of piezoelectric
transducers.
47. How It Works?
At a construction site, a technician
tests a pipeline weld for defects
using an ultrasonic instrument.
The scanner, which consists of a
frame with magnetic wheels,
holds the probe in contact with
the pipe by a spring. The wet area
is the ultrasonic couplant
(medium, such as water and oil)
that allows the sound to pass into
the pipe wall.
Non-destructive testing of a swing
shaft showing spline cracking.
Spline cracking
Backwall
Spline – any of a series of projections on a
shaft that fit into slots on a corresponding
shaft, enabling both to rotate together.
Lower end Upper end
https://www.youtube.com/watch?v=UM6XKvXWVFA
at~3:08-4:10
48. Gray scale image produced using
the sound reflected from the front
surface of the coin
Gray scale image produced using the
sound reflected from the back surface
of the coin (inspected from “heads” side)
High resolution scan can produce very detailed images. Both images
were produced using a pulse-echo techniques with the transducer
scanned over the head side in an immersion scanning system.
Images obtained by C-Scan
49. Applications of Ultrasonic Inspection
Ultrasonic inspection is often performed on steel and other metals and
alloys, though it can also be used on concrete, wood and composites,
albeit with less resolution. It is used in many industries including steel
and aluminium construction, metallurgy, manufacturing, aerospace,
automotive and other transportation sectors.
Limitations of Ultrasonic Inspection
1. Manual operation requires careful attention by experienced
technicians.
2. Extensive technical knowledge is required for the development of
inspection procedures.
3. Parts that are rough, irregular in shape, very small or thin, or not
homogeneous are difficult to inspect.
4. Surface must be prepared by cleaning and removing loose scale,
paint, etc.
5. Couplants are needed to provide effective transfer of ultrasonic wave
energy between transducers and parts being inspected unless a non-
contact technique is used.
6. Inspected items must be water resistant, when using water based
couplants that do not contain rust inhibitors.
50. • Eddy current testing can be used on all electrically
conducting materials with a reasonably smooth surface.
• The test equipment consists of a generator (AC power
supply), a test coil and recording equipment, e.g. a
galvanometer or an oscilloscope
• Used for crack detection, material thickness measurement
(corrosion detection), sorting materials, coating thickness
measurement, metal detection, etc.
Eddy Current Testing (ECT)
Electrical currents are generated in a conductive material by an
induced alternating magnetic field. The electrical currents are
called eddy currents because they flow in circles at and just
below the surface of the material. Interruptions in the flow of
eddy currents, caused by imperfections, dimensional changes, or
changes in the material's conductive and permeability properties,
can be detected with the proper equipment.
https://www.youtube.com/watch?v=tlE3eK0g6vU at~11:36-12:38
52. •Crack Detection
•Material Thickness
Measurements
•Coating Thickness
Measurements
•Conductivity Measurements for
Material Identification
•Heat Damage Detection
•Case Depth Determination
•Heat Treatment Monitoring
Applications of ECT
Here a small surface probe is scanned
over the part surface in an attempt to
detect a crack.
https://www.youtube.com/watch?v=9A5fQtOwnzw
53. • Sensitive to small cracks and other defects
• Detects surface and near surface defects
• Inspection gives immediate results
• Equipment is very portable
• Method can be used for much more than flaw detection
• Minimum part preparation is required
• Test probe does not need to contact the part
• Inspects complex shapes and sizes of conductive materials
Advantages of ECT
54. • Only conductive materials can be inspected
• Surface must be accessible to the probe
• Skill and training required is more extensive than other
techniques
• Surface finish and roughness may interfere
• Reference standards needed for setup
• Depth of penetration is limited
• Flaws such as delaminations that lie parallel to the probe coil
winding and probe scan direction are undetectable
Limitations of ECT
55. Radiography
Radiography involves the use of penetrating
gamma- or X-radiation to examine material's
and product's defects and internal features. An
X-ray machine or radioactive isotope is used
as a source of radiation. Radiation is directed
through a part and onto film or other media.
The resulting shadowgraph shows the internal
features and soundness of the part. Material
thickness and density changes are indicated
as lighter or darker areas on the film.
High Electrical Potential
Electrons
-
+
X-ray Generator or
Radioactive Source
Creates Radiation
Exposure Recording Device
Radiation
Penetrate
the Sample
https://www.youtube.com/watch?v=VscasN8jgfo Introduction to radiography
56. Film Radiography
Top view of developed film
X-ray film
The part is placed between the
radiation source and a piece of
film. The part will stop some of the
radiation. Thicker and more dense
area will stop more of the radiation.
= more exposure
= less exposure
• The film darkness (density) will
vary with the amount of radiation
reaching the film through the
test object.
• Defects, such as voids, cracks,
inclusions, etc., can be detected.
https://www.youtube.com/watch?v=tlE3eK0g6vU at~3:35-6:45
57. Applications of Radiography
• Can be used in any situation when one wishes to view the
interior of an object
• To check for internal faults and construction defects, e.g.
faulty welding
• To ‘see’ through what is inside an object
• To perform measurements of size, e.g. thickness
measurements of pipes
Limitations of Radiography
• There is an upper limit of thickness through which the
radiation can penetrate, e.g. -ray from Co-60 can
penetrate up to 150mm of steel
• The operator must have access to both sides of an object
• Highly skilled operator is required because of the potential
health hazard of the energetic radiations
• Relative expensive equipment
59. Burn through (icicles) results when too much heat causes
excessive weld metal to penetrate the weld zone. Lumps of
metal sag through the weld creating a thick globular condition
on the back of the weld. On a radiograph, burn through
appears as dark spots surrounded by light globular areas.
Examples of radiograph
60. For More Information on NDT
The Collaboration for
NDT Education
www.ndt-ed.org
The American Society
for Nondestructive
Testing
www.asnt.org
61. Review Questions for NDT
• Applications of NDT
• What are six most common NDT methods?
• Can liquid penetrant inspection be used to detect
internal flaws? Why?
• Why relative direction between the magnetic field
and the defect line is important in magnetic
particle inspection?
• Why are couplants needed for ultrasonic
inspection (UI)? Limitations of UI?
• Advantages and disadvantages of eddy current
testing.
• What is rediography? Limitations of radiography.