Week 2- Spectroscopy - Structure of Atoms PDF

Summary

This document covers the topic of Spectroscopy and the Structure of Atoms, with information on fundamental concepts and applications of Forensic Science. It includes learning objectives, case studies, and detailed explanations about elements, compounds, atomic structure, spectroscopy techniques and their applications. The document appears to be a presentation or lecture notes based on the content.

Full Transcript

FORENSIC SCIENCE

SPECTROSCOPY
AND THE
STRUCTURE OF
ATOMS
Learning Objectives

explain the concept of chemical elements

from an understanding of atomic structure explain how
emission and absorption spectroscopy work

flame tests, AAS, SEM-EDX, NAA
Cases

September 2001: 1963: how 1821: Death of
part of the body of a many people Napoleon
boy found in the shot JFK?
Thames
 is a substance that cannot

- be transformed into another
substance

Elements and
Compounds
& consists of multiple
elements combined tyt
Elements are the basic
materials: 93 natural,
more artificial
H, O, C, Fe, Zn, U,
Ir, Sm, Gd, Kr, Tl….
Gunturtiny elements

ELEMENTS CAN
NEITHER BE
CREATED NOR
DESTROYED

Robert Boyle
1627-1691
 Paper made of burn
Carbon dioxide CO2
Cellulose = C, H, O Water H2O
paper
elements can neither

CO2
&
Still
created nordevea
in
Human Body H2O they just appear
N oxides different compounds
C, H, O, N, P,
S, Ca, Na, K, Fe….
burn P oxides
body S oxides
Au or Hg in teeth Ca oxides or hydroxides
(fillings in teeth ……..
Au
Hg oxides
Elements
The elements may be organised according to chemistry:
~
chemicties
a
The Periodic Table (Mendeleev, Chemist, Russia)

Or musically
(Tom Lehrer, Mathematician, Harvard)
http://www.privatehand.com/flash/elements.html
Analysis
Which elements are present, and how much?

ex. suspected lead or mercury poisoning
Are these metals present in the body?
regardless of their chemical form
Toxicology

ex. FUN analysis
how much of these elements were
present in the Piltdown bones?
Time of Death
 What is it made of?
How can we identify the elements present in an object?

Bulk composition (what is most it of it made of?)
e.g. bullets – lead

Trace impurities (what is a very small part of it made of?)
e.g. bullets - silver and antimony
if multiple elements are
present,
I results you get for one might
Chemical tests – large amounts mask
results that

- destructive no from another
- subject to interference
- fast
- easy to do
- simple equipment
-
not sensitive
 Trace impurities: How small is small?
S.I. prefixes
1 Megagram 1 Mg = 1,000,000 g is called a tonne

biggest
than
1 Kilogram (1 Kg) = 1,000 g

19 1 gram (1 g)
1 milligram (1 mg) = 0.001 gram (1/1000th) [se)
smaller
than
1 microgram (1 g) = 0.000001 gram (1/1000,000th) I can't see)
19
1 nanogram (1 ng) = 0.000000001 gram (1/billionth)

~ 1 picogram (1 pg) = 0.000000000001 gram (1/trillionth)

Even a picogram contains about
100,000,000,000 atoms
How small is small?
trace elements are often measured
in ppm = part per million 1 in 1,000,000

5 people in all of Singapore

or even in ppb = parts per billion 1 in 1,000,000,000

7 people in the whole world
The Spectrum

White light consists of all colours. These can be
separated by passing light through a prism.
~ light from
I sun is split into
The same effect results in rainbows. its constituent colours
White light is split when Early investigators such
passing through a prism as Newton, used sunlight
Spectroscopy
Early 19th Century: black bands observed in the
solar spectrum: ~ sunlight
Fraunhofer lines - found to be due to hydrogen black
consists
caused
Other lines led to the discovery of helium bylines part of
are

light from
absorbed
sun being
by H

Norman
Lockyer
&
proposed - existence
I helium
 the whole spectrum
Different spectroscopic techniques use different frequencies of light.
The different frequencies of light interact differently with the molecules.

shortwavelength,
high free
:

longwarelea
nt (inverse uls)
Structure of the Atom

Tiny, dense, positively charged core
called a nucleus in which nearly all the
mass is concentrated, around which
the light, negative constituents, called
electrons circulate at some distance:
“planetary model” (not e best model)

Ernest Rutherford
1871-1937
Atomic structure
Why don’t atoms destroy themselves due to electrostatic attraction?

Niels Bohr – electrons
are restricted to
specific energy levels
so
they can't drop down

to e nucleus as there
aren't any energy his ready
for them
Atomic structure

Electrons release
AE

energy when they
drop to a lower level

Ground state
Excited State
Energy is released as electromagnetic
le- in
higher radiation
11
energy
The frequency of the electromagnetic
radiation emitted or absorbed is proportional
to E (the energy drop)

de Broglie eqn: E = h
&
freq
Allowed Energy Levels the rungs of a ladder
are allowed levels

in an atom
,
luls are
energy released energy
not equally
that matches gap to
spaced like
next rung on this
ladder

Energy emitted
Atomic structure
add every

Electrons jump to a
higher level when
they absorb energy

Ground State Excited
State
Energy is absorbed as electromagnetic radiation

The frequency of the electromagnetic radiation
emitted or absorbed is proportional to E (the
energy drop) ~
i fregt of electromagnetic

radiate must be
right
de Broglie eqn: E = h fregt to match AE
Allowed Energy Levels the rungs of a ladder
are allowed levels

add energy
that matches gap
to next rung

Energy absorbed
& in i form of
electromagnetic
radiate
Energy Levels
Black lives e
in spectrum
19th century
are
in
early
due to electromagnetic energy
being a ri/he
absorbed by
or other atoms

atoms have
for ove
Multiple energy levels - multiple lines in the spectra afor
The pattern is characteristic for each element
 absorb electromagnetic radiati e
specific
only of atoms of e

~
match i AE
that
free
elements present
Absorption Spectroscopy

er promoted to add
E higher
1
energy

absorb
electromagnetic
radiata

Ground State Excited State
E and therefore
frequency characteristic
of the element
can determine presence of
element from spectrum
 Emission Spectroscopy

>

energy given out fregt of
>
radiate given
out matches AE yeth L

lvls
supplied energy energy
Excited given
State
out
E aselectromagnetic

E and therefore Ground State
frequency characteristic if we art
measure of radiati
of the element absorbed/ emitted we can

of element
, in
I couc
measure
assume am
e sample as we can
,
absorbed/ emitted will be proportional to
e 2) of I element
 emission spectrum

Using a prism, the spectrum of the element
can be obtained

used
in this
experiment electricity
,
is

to excite H to their excited state,

they drop back to
then their ground
states & give off light
& I beam of
& to
light is passed through
slits

e prism. I
prism breaks I light
into its components & diff bands
of lighe diff colors (signifying
diff fregt) are observed I gas
bands

no emiss ? diff wavelength/ free =
bed it that I emits
does not match
AE in H afor
Flame tests for metals lemiss)

If a metal salt is introduced into a flame, a
characteristic colour is produced
Cheat)
energy of the flame
excites electrons in
the sodium atoms & fo
higher
sodium energy l
(orange) emit orange light as
they drop back to
the ground state

At matches I
freg of
orange light : flame
turns orange
Barium Calcium Lithium Copper Potassium
(green) (red) (red) (green) (lilac)
Flame tests for metals

qualitative quantitative
Y now which
Flame photometer Cemiss1)
element is
present (light of particular fregt of interest
a

is separated & I
intensity of that

light is measured to measure.
cous
 replace flame photometer
~
Atomic Absorption Spectrometer (quantitative)
labsorpt)
not
flame
detector loss of intensity is related to
amount of the atom of interest
other
hollow monochromator
in the flame because the atoms
cathode
lamp & sample becomes
in the flame absorb e diff frog &
not e
are
provided bye lamp
atomised
Advantages:
fast
specific
gas sensitive
acetylene/ oxygen display or small sample size
or computer
acetylene/ NO
Disadvantages:
destructive dissolve in acid
~

sample dissolved light from the element by element
in acid Chas to be in
solute form to
pass
lamp at frequency
flume) for the element
in

of interest
 samplea beam of e
bombarding
-
EDX: Energy Dispersive X-ray Fluorescence
lemiss)
non destructive analysis looking at the core electrons
Use an electron beam to eject core electrons

fire electron
beam

& core electron electromagnetic
radiat is?
knocked out emitted HE
,
will be quite
big fregt
will
,

bequitehia b
when a higher energy electron X-ray
ejecting a core electron
drops to fill the vacancy, a
creates a vacancy
characteristic X-ray is
emitted
 EDX diff elements correspond to diff X-ray freat
Intensity

S
correlated
to 17 of
elements
present

energy of emitted X-Ray
/frog-
Microscopy
technique
microscope
basedonbombardin
are
↑ ofe
Scanning
Electron ~ fr
Microscope imaging
(SEM)
Luses a beam of
electrons instead of
light

a particle of gunshot residue
diameter about 5 m
called
combine SEM & EDX to give a technique
SEM-EDX
SEM-EDX Lemissa)

in a SEM, there is an electron gun that fires a beam of electron at the object of
interest and hit the object and bounce and are detected. The signals from the
detector are used to generate the image

Besides the electrons hitting and bouncing off the sample, they can also hit
the atom and cause a core electron to be ejected and a higher energy level
electron will drop down to fill the vacancy. The drop is from a higher energy
level to a much lower energy level and the radiation given out is high energy
and corresponds to X-rays which are characteristic of the element
 uses atomic nucleus rather
- than electrons
Neutron Activation Analysis lemiss )
=

git

neutron
absorbed
by
nucleus
giving

non-destructive Lexcited State) &
forms of electromagnetic radiate
trei
-
ve; but needs a nuclear reactor Characteristic energy
sample may be radioactive afterwards
Neutron Activation Analysis
Gamma-ray
spectrum from 0 to
800 keV showing
medium- and long-
lived elements
measured in a
sample of pottery
irradiated for 24
hours, decayed for
smaller peaks
in
-

much
elements 9 days, and
present
smalle quantities vice versa counted for 30
minutes

Qualitative and quantitative multi-element analysis
70% of elements can be studied
Who Killed Napoleon?
Napoleon’s Career:
Artillery officer, General,
Dictator of France,
Emperor of (most of) Europe
Defeated, Waterloo, 1815
Exiled to St Helena; 1821 dies
Who Killed Napoleon?

1952 Analysis of hair samples (neutron activation
analysis) shows arsenic

the British?

the French?
Who Killed Napoleon?

1980 Dr David Jones (Newcastle): what colour was
Napoleon’s wallpaper?
↓ ~
non-destructive

SEM-EDX shows presence of arsenic
in his wallpaper
copper arsenite
or Scheele’s Green green
in
I
wallpaper
certain species would
of metabolised
~

mold
argenic

CuAsO3H AsH3 (gas)
forming dre to
St Helena's subtropical
warm humid climate
Who Killed Napoleon?

autopsy?

eye-witnesses?

His doctors – using mercury chloride
& toxic
drug i Drs
prescribed to him
Kennedy Assassination 22nd Nov. 1963

Lee Harvey
Oswald (Shooter)

Oswald fired three times (One complete miss)

If there was a second gunman, how
many types of bullet would there be?
 theyfly throne air ,theybecome extremea
~ Then
fragments
Analysis of Bullets - not pure lead!
into

now to tell which
fragment belongs
Neutron activation analysis to which bullet ?
-

analysis of trace elements of
bullets
bullet fragment silver (Ag)/ppm antimony (Sb)/ppm

bullet will
Q1 8.8 833 each
have its unique
Q9 9.8 797 amount of these
elements
Q2 8.1 602 e
indicating
Q4,5 7.9 621 presence f 2

bullets
Q14 8.2 642

Bullets of this type had Ag 5 to 15 ppm; Sb 20 to 1200 ppm

Most likely to be a single gunman
 Adam
2001: part of a body of a boy found in the Thames

forsoo limbsa head
missing
cuts made with very sharp knife
blood drained
- ethnic :
African

still
wearing a
pair of orange shorts

shorts from China, sold in West Germany
stomach contained food, pollen (N.European), clay,
calabar bean, gold particles
&
toxic plant native to West these 3 are associated in West African
Africa black magic ,
he is murdered as part of
he was
West African black magic ceremony ,

a human sacrifice
You Are What You Eat
Bone consists of calcium phosphate in a protein matrix.
Calcium is derived from the diet. Other metals may also be
incorporated if they are present in the diet. you grow up where may be
present
in e
chemisty of your bones
in more
who live
(particularly true for people
where
they
Relative abundance of trace elements in bone can indicate
traditional societies
eat what is grown locally &

geographical origin: strontium, copper, lead. not
were
as true
we eat
for advance societies
what is imported
from all sorts of places around
e world

strontium
copper
lead
he was abducted

Small soil & samples
in
Nigeria &
people taking
area bore
of Nigeria trafficked to
I
to match trace element west Germany
profile ofI soil to that If & transported to

bones London where
his
he was used as

a human sacrifice
 Elemental Analysis

Spectroscopic methods:
emission (flame photometry)
absorption (AAS)

EDX: X-Ray
combine with SEM

NAA