CHM 1020C Lecture 3
If the number of electrons is less than the number of protons, the atom is a
CATION
it is a perfect technique for working with dirty mixtures of samples which are often the only kind available at a crime scene.
Mass spectrometery
had deduced that the energy of the photons comprising EM (electromagnetic) radiation is a function of its frequency (E = hν), this Planck's equation.
Max Planck
stated that the structure of an atom had specific energy levels in which the electrons were located around the nucleus
Neils Bohr
Are large and heavy like protons except they have no electrical charge
Neutrons
Provide the "extra Glue" that hold the nucleus together
Neutrons
an extra attractive force that belongs in nucleus that works only between protons and neutrons ; without this force the nucleus would disintegrate
Strong nuclear force
Oxygen also exists as O3 = ozone. This is called an
allotropic forms
Bohr also assumed that the electron can change from one
allowed orbit to another
So through Bohr's equation we can relate the energy to the structure of the
atom
Since the number of protons for a specific element is always the same and given by the atomic number, calculating the number of neutrons in an atom is easy; just subtract the number of protons from the
atomic mass number
Each element has a unique
atomic number
makes statements regarding chemical changes much easier
chemical symbols
Hydrogen isotope with one proton and one neutron
deuterium
Different elements have BLANK so that is why different elements emit or absorb different amounts (wavelengths) of light.
different energy levels
an increase in frequency increases the
energy of the photons created.
Those clouds are located specific distances from the
nucleus
an increase in intensity just increases the
number of photons created
electrons live in shells that are wrapped around the nucleus called
orbitals
Only electrons in the blank orbitals participate in chemical reactions these are called valence electrons
outer
The atom is composed of three types of
particles
as each electron moves from a higher energy level (orbit) to a lower one, a different color is emitted. The numbers shown above the colors are the wavelengths that correspond to the color.
the Bohr model
The protons and neutrons are located in center of an atom called
the nucleus
If two protons are in the nucleus they will fly apart because they have
the same charge
The relationship between wavelength and frequency is related through
the speed of light c=λν
Through Planck's equation we can relate the frequency of light to the
energy
The unit used most often to describe frequency is Blank which means "per second" or /s.
(Hertz) Hz
Wavelengths found in the electromagnetic spectrum (range of light) can be measured in units a small as
10^-11 meters (gamma waves)
Wavelengths found in the electromagnetic spectrum (range of light) can be measured in units as large as
10^3 Meters (radio waves)
If the number of electrons is greater than the number of protons, the atom is an
ANION
The number of neutrons plus the number of protons is called the
ATOMIC MASS NUMBER
The number of protons in an atom is called the
ATOMIC NUMBER of the element
Are the fundamental units of matter
Atoms
1. Electrons assume only certain orbits around the nucleus. These orbits are stable and called "stationary" orbits.
Bohr Model Principle 1
2. Each orbit has an energy associated with it. For example the orbit closest to the nucleus has an energy E1, the next closest E2 and so on.
Bohr Model Principle 2
3. Light is emitted when an electron jumps from a higher orbit to a lower orbit and absorbed when it jumps from a lower to higher orbit.
Bohr Model Principle 3
4. The energy and frequency of light emitted or absorbed is given by the difference between the two orbit energies, e.g.
Bohr Model Principle 4
1.The electrons were emitted immediately. 2. Increasing the intensity of the light increased the number of photoelectrons, but not their maximum kinetic energy. 3. When Na is the metal red light will not cause the ejection of electrons, no matter what the intensity. 4. Weak violet light will eject only a few electrons, but their maximum kinetic energies are greater than those for intense light of longer wavelengths.
Characteristics of Photoelectric effect
are formed by the combination of atoms
Compounds
Compounds that share electrons are
Covalent Bonds
In the 5th century B.C. a philosopher hypothesized that all matter (plus space and time) is composed of tiny indestructible units, called atoms named
Democritus
can be used to "label" compounds that have hydrogen atoms so that the spectroscope can see their location better. Because of the additional mass of the extra neutron in the nucleus, this makes the atom easier to "see".
Deuterium
Atoms are overall neutral meaning the positive charge of a proton need to be cancelled by the negative charge of a
Electron
The number of BLANK in each orbital are very important because they effect the properties of the element and how it will behave in the world i.e. lithium is a metal because it has one electron in its outer orbital
Electrons
are tiny, very light particles with a negative charge
Electrons
In the case of light, BLANK refers to the number of times a wavelength is repeated per second
Frequency
is the number of occurrences of a repeating event per unit time.
Frequency (ν)
Monatomic Elements called noble gases used to be called inert gases
Helium, Neon, Argon, Krypton, Xenon, and Radon
the only atom that does not need a neutron in its nucleus because it has one proton and one electron
Hydrogen
is similar to UV/VIS spectroscopy in that it uses light to determine the structural components in a substance, but unlike UV/VIS spectroscopy, the wavelength of Infrared light is not sufficiently energetic to cause an emission.
Infrared spectroscopy
it is the number of waves or photons of light reaching your detector; a brighter object is more intense but not necessarily more energetic.
Intensity
The variation in the number of Neutrons in an atom are called
Isotopes
use a stream of electrons to convert molecules or atoms into positive ions so that they can be attracted using a magnet.
Mass spectrometers
an energy particle (electromagnet radiation) called a
PHOTON
NO TWO ELEMENTS HAVE THE SAME NUMBER OF
PROTONS IN THEIR ATOMS.
We can use the light that passes through the sample and is not absorbed to not only confirm the presence of our molecule in a sample but also quantify how much of the compound is present based on the response.
Photoelectric effect
Hydrogen isotope with one proton and no neutrons
Protium
Are much larger and heavier then electrons. These particles have a positive charge
Protons
The atomic number of an atom is always the same as the number of BLANK in its nucleus
Protons
The number of blank identifies the element
Protons
What makes up electromagnetic sprectrum
Radio waves, microwaves, infrared light, visible light, ultraviolet light, X-rays, and gamma rays
is defined as the distance between the crests or troughs of a wave motion.
The wavelength (λ) of light
It's been determined experimentally that when light shines on a metal surface, the surface emits electrons. This is called the photoelectric effect.
This is called the photoelectric effect.
Hydrogen isotope with one proton and two neutrons
Tritium
is also used for determining the concentration of illegal substances in mixtures
UV/VIS spectroscopy
are involved in the formation of chemical bonds between atoms
Valence electrons
The light we see color in
Visible Light
does lead to the rearrangement of atoms
a chemical reaction
If the electron gains energy this is called an
absorbance
Spectrometers like the one above can be set to read in two different units
absorbance (A) or percent transmission (%T).
Energy must be BLANK for an electron to move to a higher state (one with a higher n value)
absorbed
In both cases an energy particle called a PHOTON is absorbed or emitted and thus light is
absorbed or emitted
Energy is BLANK when the electron moves to an orbit of lower energy (one with a lower n value)
emitted
the second orbital can have only
eight electrons
range of light
electromagnetic spectrum
it is very important in determining the charge of the atom and how reactive the atom will be with the world around it.
electron
The number of electrons in each orbital is called the
electron configuration
emission spectrum is determined by
electronic structure
The wavelengths and frequencies of the light emitted by an atom (its emission spectrum) is determined by its
electronic structure.
Have almost no mass an orbit the nucleus at incredible speeds
electrons
are found in clouds that surround the nucleus of an atom
electrons
are located in energy levels surrounding the nucleus.
electrons
The overall shape of the shells depends on the number of
electrons in the atom
The higher the atomic number, the more shells and electrons an atom will have. The overall shell shape becomes more complex as the number of
electrons increases
The wavelengths and frequencies of the light emitted by an atom
emission spectrum
if it lost energy this is called an
emittance
In forensic investigations, the most common use of UV/VIS spectroscopy is the determination of i.e. if you have a chip of paint from an accident scene that you need to match to a suspect's car, you can use UV/VIS spectroscopy to determine the wavelength of maximum absorbance and that will give you the specific color of the paint chip for comparison.
exact colors.
When an electron Blank from a higher orbit to a lower one the energy difference is a defined amount and results in emitted electromagnetic radiation of a defined energy (ΔE)
falls
The overall change in energy associated with "orbit jumping" is the difference in energy levels between the
final and initial orbits:
The full electromagnetic spectrum is generally shown with both measurements given
frequency and wavelength
Whenever an electron moves from one of these energy levels to another it must either
gain or lose energy
Mass Spectrometry or IR spectroscopy, are used to confirm the identification of the
illegal substance.
But if the number of electrons is greater or less than the number of protons, then you have what is called an
ion
Compounds that are held together by difference in charge are
ionic bonds
Electrons are the glue that hold together
molecules
For the wavelengths of visible light (the light we see in color) the most common units used
nanometers and Angstroms
In an atom where the number of electrons is exactly the same as the number of protons, the atom is said to be
neutral
is an uncharged particle that is also found in the nucleus of atoms
neutron
Neutrons are found in all atoms that have one more than one
proton
The number of blank and blank must be the same; this is true for all atoms
protons and electrons
Atoms are made up of three subatomic particles
protons, neutrons, and electrons
Planck's equation implies the higher the frequency of a radiation, the more energetic are its
quanta
radiant energy is emitted in small bursts, known as
quanta
Because electrons move so BLANK it is impossible to know the exact location of the electron around the nucleus
quickly
One of the main ways forensic scientists and chemists analyze the data they collect is by using a piece of equipment called a
spectrometer
Isotopes are important because we can often use them in
spectroscopy
The most inner orbital can only have
two electrons
each element has its own
unique symbol
photon's energy depends on the
wavelength (or frequency) only
In the case of light, frequency refers to the number of times a
wavelength is repeated per second.