Adobe Systems
Zápatí prezentace
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Adobe Systems
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Matter and Energy
ØEverything is made up of basic particles of matter and fields of energy / force, which also means
that the fundamental structural elements of the organic and inorganic world are identical.
ØLiving matter differs from non-living matter mainly by its much higher level of organisation.

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Elementary Particles of Matter
(i.e. having - probably - no internal structure)
Ø„force“ particles – integer spin – bosons
ØVector bosons – spin 1
ØFoton
ØGluons
ØW, Z (week bosons)
ØGraviton
ØScalar boson – spin 0
ØHiggs boson
Ø„matter“ particles – noninteger (odd) spin - fermions
ØThe elementary particles of matter are leptons and quarks
ØLeptons – electrons, muons, neutrinos and their anti-particles – light particles without internal
structure
ØQuarks (u, c, t, d, s, b) – heavier particles without internal structure
Ø
ØComposite particles
ØHadrons – heavy particles formed of quarks - baryons (fermions - proton (u, u, d), neutron (d, d,
u)) mezons (bosons (quark-antiqvark))
Ø

[USEMAP]
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The Four Fundamental Energy / Force Fields
gravitational
electromagnetic
strong
weak
Strong : weak : electromagnetic : gravitational force - 1 : 10-5 : 10-2 : 10-39 at interaction
distance of about 10-24 m; 10-7 : ~0 : 10-9 : 10-46 at a distance of  about 10-18 m (1/1000 of atom
nucleus dimension). In the distance equal to nucleus dimension goes to zero also strong
interaction.

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Photons
ØPhotons - energy quanta of electromagnetic field, zero mass
ØEnergy of (one) photon: E = hf = hc/l
h is the Planck constant (6.62·10-34 J·s),
f  is the frequency,
c is speed of light in vacuum,
l is the wavelength.

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Particles and Field Energy Quanta
Particles of matter and field energy quanta are capable of mutual transformation (e.g., an electron
and positron transform to two gamma photons in the so-called annihilation – this is used in PET
imaging).

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Electron diffraction pattern
Quantum Mechanics
The behaviors of ensembles of a given type of particle obey equations which are similar to wave
equations.
(http://www.matter.org.uk/diffraction/electron/electron_diffraction.htm)
On the left pattern formed on a photographic plate by an ensemble of electrons hitting a crystal
lattice. Notice that it is very similar to the diffraction pattern produced by a light wave passed
through optical grating.

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kag10602_e kag10601_e
Quantum Mechanics
tunnel effect:
kag10602_e kag10601_e

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Quantum Mechanics: Heisenberg uncertainty relations
dr·dp ≥ h/2p
dE·dt ≥ h/2p
The position r and momentum p of a particle cannot be simultaneously measured with independent
precision (if the uncertainty of particle position – dr – is made smaller, the uncertainty of
particle momentum – dp – automatically increases). The same holds for the simultaneous measurement
of energy change dE and the time dt necessary for this change. h is the Planck constant.

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Schrödinger equation
(to admire J)
„one-dimensional“ S. equation
Radial co-ordinates of an electron in a hydrogen atom
Y - wave function
S. equation for the electron in the hydrogen atom
according http://hyperphysics.phy-astr.gsu.edu/hbase/quantum/hydsch.html
Obsah obrázku hodiny Popis byl vytvořen automaticky

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Solution of the Schrödinger Equation
ØThe solution of the Schrödinger equation for the electron in the hydrogen atom leads to the values
of the energies of the orbital electron.
ØThe solution of the Schrödinger equation often leads to numerical coefficients which determine the
possible values of energy. These numerical coefficients are called quantum numbers

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Quantum numbers for Hydrogen
ØPrincipal  n = 1, 2, 3 …. (K, L, M, ….)
ØOrbital for each n   l = 0, 1, 2, …. n – 1 (s, p, d, f …)
ØMagnetic for each l     m = 0, ±1, ±2, …±l
ØSpin magnetic for each m  s = ±1/2
Ø
ØPauli exclusion principle – in one atomic electron shell there cannot be present two or more
electrons with the same set of quantum numbers.

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Ionisation of Atoms
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Example of ionisation: photoelectric effect
h·f = Eb + ½ m··v2
The binding energy of an electron Eb is the energy that would be required to liberate the electron
from its atom – depends mainly on the principal quantum number.
Secondary electron
Primary photon
excitation
ionisation

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Emission Spectra
Dexcitations between discrete energy levels result in emitted photons with only certain discrete
energies, i.e. radiation of certain frequencies/wavelengths.
slits
prism
Hydrogen discharge tube
Visible emission spectrum of hydrogen.
http://chemed.chem.purdue.edu/genchem/topicreview/bp/ch6/bohr.html
modro- = bluish
Learn the Czech names of colours J

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Hydrogen spectrum again
magenta, cyan and red line
according
http://cwx.prenhall.com/bookbind/pubbooks/hillchem3/medialib/media_portfolio/text_images/CH07/FG07_
19.JPG
Excitation of electrons
Emission of light

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Excitation (absorption) Spectra for Atoms
Absorption lines in visible spectrum of sun light.
Wavelengths are given in Angströms (Å) = 0.1 nm
http://cwx.prenhall.com/bookbind/pubbooks/hillchem3/medialib/media_portfolio/07.html
Transitions between discrete energy states of atoms!!

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Excitation (Absorption) Spectrum for Molecules
According: http://www.biochem.usyd.edu.au/~gareth/BCHM2001/pracposters/dyeZ.htm
Absorption spectrum of a dye
Wavelength

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Atom nucleus
Proton (atomic) number – Z
Nucleon (mass) number – A
Neutron number – N     N = A - Z
Atomic mass unit u = 1.66·10-27 kg, i.e. the 1/12 of the carbon C-12 atom mass
Electric charge of the nucleus  Q = Z1.602·10-19 C
If relative mass of electron = 1                                        Þ Relative mass of proton =
1836                           Þ Relative mass of neutron = 1839
fission

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Mass defect of nucleus
= measure of nucleus stability:
 dm = (Zmp + Nmn) - mnuc
Sources:
http://cwx.prenhall.com/bookbind/pubbooks/hillchem3/medialib/media_portfolio/text_images/CH19/FG19_
05.JPG
http://cwx.prenhall.com/bookbind/pubbooks/hillchem3/medialib/media_portfolio/text_images/CH19/FG19_
06.JPG
fission
nucleon number
nuclear synthesis
scale change
E = dm.c2
This formula allows to calculate amount of energy liberated during the synthesis of the nucleus.

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Nuclides
Ønuclide - a nucleus with a given A, Z and energy
ØIsotopes - nuclides with same Z but different A
ØIsobars – nuclides with same A but different Z
ØIsomers – nuclides with same Z and A, but different energy (e.g., Tc99m used in gamma camera
imaging)

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Isotope composition of mercury
% of Hg atoms vs. isotope nucleon number (A)
According to:
http://cwx.prenhall.com/bookbind/pubbooks/hillchem3/medialib/media_portfolio/text_images/CH07/FG07_
08.JPG
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A
Nucleon number

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What else is necessary to know?
ØRadionuclides – nuclides capable of radioactive decay
ØNuclear spin:
Nuclei have a property called spin. If the value of the spin is not zero the nuclei have a magnetic
moment i.e, they behave like small magnets - NMR – nuclear magnetic resonance spectroscopy and
magnetic resonance imaging (MRI) in radiology are based on this property.

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Author:
Vojtěch Mornstein
Content collaboration and language revision:
Carmel J. Caruana
Presentation design:
Lucie Mornsteinová
Last revision:September 2021, soundtrack 2021
Author:
Vojtěch Mornstein
Content collaboration and language revision:
Carmel J. Caruana
Presentation design:
Lucie Mornsteinová
Last revision:December 2018