Instructor: Maurizio Casarin - Address: Chimica UniPD

Page created by Wallace Chandler
 
CONTINUE READING
Instructor: Maurizio Casarin - Address: Chimica UniPD
Instructor:
                                           Maurizio Casarin

                                              Address:
                            Maurizio Casarin: Via Loredan 4, 35131 - Padova
                               Phone number: +39 049 - 827 ext. 5164
                              E-mail address: maurizio.casarin@unipd.it
                   http://www.chimica.unipd.it/maurizio.casarin/pubblica/casarin.htm

Maurizio Casarin               Chimica Generale ed Inorganica (Canale L – Z)
Instructor: Maurizio Casarin - Address: Chimica UniPD
Recommended Book:

  “Chimica Generale” 11th edition
                  by
Petrucci, Herring, Madura, Bissonette
              Piccin Eds
               (47.00 €)
Instructor: Maurizio Casarin - Address: Chimica UniPD
CORSO DI LAUREA MAGISTRALE A CICLO UNICO IN FARMACIA

ORARI I SEMESTRE A.A. 2018-2019 (01/10/2018 - 18/01/2019)

         AULA MENEGHETTI - LARGO MENEGHETTI N° 2
Instructor: Maurizio Casarin - Address: Chimica UniPD
DUE ORE
TRE ORE
Instructor: Maurizio Casarin - Address: Chimica UniPD
I° appello sessione invernale 2018-2019 ore 10:00 aula E. Meneghetti
2.5h
       II° appello sessione invernale 2018-2019 ore 10:00 aula E. Meneghetti
Instructor: Maurizio Casarin - Address: Chimica UniPD
https://didattica.unipd.it/off/2018/ME/corsi_attivi

           Modalità di Esame:
             Scritto (no compitini)
           Orale (iff scritto ≥ 17/30 )
Instructor: Maurizio Casarin - Address: Chimica UniPD
Instructor: Maurizio Casarin - Address: Chimica UniPD
Instructor: Maurizio Casarin - Address: Chimica UniPD
Instructor: Maurizio Casarin - Address: Chimica UniPD
https://ptable.com/
Tc: Perrier, Segre in ‘37 at Italy
                        Fr: Perey in ‘39 at France
                        At: Corson, MacKenzie, Segre in ‘40 at USA
                        Pm: Marinsky, Glendenin, Coryell in ‘45 at USA

Np: obtained by Edwin M. McMillan and P. H. Abelson in 1940 in USA
Pu: obtained by G.T Seaborg, J.W. Kennedy, E. M.
    McMillan and A. C. Wahl in 1940 in USA
https://ptable.com/

On 28 November 2016, the IUPAC approved the name and symbols for four elements: nihonium (Nh),
moscovium (Mc), tennessine (Ts), and oganesson (Og), respectively for element 113, 115, 117, and 118
https://ptable.com/
15 February 1564[2] – 8 January 1642
Experiments are the only means of knowledge at our
disposal. The rest is poetry, imagination.

Max Planck 1894
Facts & Data

Fact: A statement that scientists demonstrate to be true.

 Data: Raw information that scientists gather.
Laws & Hypotheses

 Laws:   A description of events that always happens.
         No assumptions about why.

Hypotheses:   An assumption about why things happen.
              Requires testing. Never proven.
Theory & Experiment

Theory: Like a hypothesis; but based   on more observations.

      Experiment: A controlled test of a hypothesis.
The Scientific Method
Making observations
     Making predictions
           Doing Experiments

     Making observations
     Making predictions
     Doing Experiments
https://www.youtube.com/watch?v=5KcpqLk78YA
“It is a capital mistake to theorize before you
have all the evidence. It biases the judgment."

Sherlock Holmes, in
The Adventures of Sherlock Holmes,
"Scandal in Bohemia" (1892).
«La filosofia è scritta in questo grandissimo libro che continuamente ci
sta aperto innanzi a gli occhi (io dico l'universo), ma non si può
intendere se prima non s'impara a intender la lingua, e conoscer i
caratteri, ne' quali è scritto. Egli è scritto in lingua matematica, e i
caratteri son triangoli, cerchi, ed altre figure geometriche, senza i quali
mezi è impossibile a intenderne umanamente parola; senza questi è un
aggirarsi vanamente per un oscuro laberinto. »

Galileo Galilei, Il Saggiatore, Ed. Accademia dei Lincei, Roma (1623).
Measurement Systems:

Where did the “foot” originate from, and why was it useful?
Carpenters always had it with them!

Early definition of an inch?
The distance occupied by four barley corns!

The cubit is? The distance from the elbow to the end of the
index finger.
Quantitative Units of Measurement
               (SI UNITS)
Measurement       Unit Name    Abbreviation
Mass                Kilogram        kg
Length              Meter           m
Time                Second          s
Temperature         Kelvin          K
Amount              Mol             mol
Electric Current    Ampere          A
Luminous Intensity Candela          cd
SI Prefixes
Prefix   Symbol   Multipliers      Prefix   Symbol   Multipliers

deci      d             10-1       deka       da          101
centi     c             10-2       hecto      h           102
milli     m             10-3       kilo       k           103
micro     m             10-6       mega       M           106
nano      n             10-9       giga       G           109
pico      p             10-12      tera       T           1012
femto     f             10-15      peta       P           1015
atto      a             10-18      exa        E           1018
zepto     z             10-21      zetta      Z           1021
yocto     y             10-24      yotta      Y           1024
SI DERIVED UNITS
SI Derived            Quantity Unit Name           Symbol   Dimension

acceleration         meter per second per second       -      m ✕ s-2

electric charge      coulomb                           C      A   ✕   s
electric field       volt per meter                    -      V ✕ m-1
electric potential   volt                              V      J ✕ C-1
force                newton                            N      Kg ✕ m ✕ s-2
frequency            hertz                             Hz     s-1
momentum             newton second                     -      Kg ✕ m ✕ s-1
power                watt                              W      J ✕ s-1
pressure             pascal                            Pa     N ✕ m-2
radioactivity        becquerel                         Bq     s-1
speed                meter per second                  -      m ✕ s-1
work, energy, heat   joule (newton meter)              J      Kg ✕ m2 ✕ s-2
Special Units and Conversion Factors
    Quantity          Unit        Symbol              Conversion

energy         electron volt       eV        1 eV       = 1.60217733 ✕ 10-19 J
heat           calorie             cal       1 cal      = 4.184 J
length         ångstrom            Å         1Å         = 10-8 cm = 10-10 m
mass           atomic mass unit    u or Da   1 u/1 Da = 1.6605402 ✕ 10-27 kg
pressure       atmosphere          atm       1 atm      = 1.01325 ✕ 105 Pa
pressure       torr                torr      1 torr     = (1/760) atm
temperature    Celsius             °C        °C         = K - 273.15
Special Units and Conversion Factors
Quantity    Unit               Symbol    Conversion

time        minute             min       1 min   = 60 s
time        hour               h         1h      = 60 m = 3600 s
time        day                d         1d      = 24 h = 86400 s
time        year               y         1y      = 365.25 d
volume      liter              L         1L      = 1 dm3 = 10-3 m3
volume      cubic centimeter   cm3, cc   1 cm3   = 1 mL = 10-3 L
Physical Constants
Quantity                          Symbol           Value
acceleration due to gravity (earth)   g       9.80665               m.s-2
Avogadro’s Number                     N       6.0221367 ✕ 1023      mol-1
Bohr radius                           a0      0.529177249 ✕ 10-10   m
Boltzmann’s constant                  kB      1.380658 ✕ 10-23      J.K-1
electronic charge-to-mass ratio       -e/me   1.75881962 ✕ 1011     C.kg-1
elementary charge                      e      1.60217733 ✕ 10-19    C
Faraday constant                      F       9.6485309 ✕ 104       C.mol-1
gravitational constant                G       6.67259 ✕ 10-11       m3.kg-1.s-2
mass of electron                      me      9.1093897 ✕ 10-31     kg
mass of neutron                       mn      1.6749286 ✕ 10-27     kg
mass of a proton                      mp      1.6726231 ✕ 10-27     kg
Physical Constants
  Quantity                   Symbol                    Value
molar volume of ideal gas at NTP   Vm   22.41410 L.mol-1
permittivity of vacuum             ε0   8.854187817 x 10-12 C.N-1.m-2
Planck’s constant                  h    6.6260755 x 10-34 J.s
Rydberg constant                   R∞   2.1798741 x 10-18 J
speed of light in vacuum           c    2.99792458 x 108 m.s-1
universal gas constant             R    8.314510 J.mol-1.K-1
                                        0.08205783 atm.L.mol-1.K-1
Mass and weight

• Mass is the resistance of an object
  to its change in state of motion.

• On earth this is due to gravity, and
  is “constant”. We measure a
  weight.
Density = mass/volume
Density = mass/volume
Uncertainty in Measurements

     meniscus

 Instrument error
   Human error
concave meniscus   convex meniscus
Accuracy vs Precision

Accuracy: how close to “Real”
Precision: how reproducible

                    Good
                    precision
          Terrible
          Accuracy!
Significant Figures (Sig Figs)

 The answer can be no more precise
than the least precise measurement.
Rules to determine Sig Figs:

1.   All non-zero integers ALWAYS count as Sig Figs.

     The numbers 14576 and 1.7895 both have FIVE SigFigs

2.    Exact numbers NEVER limit the number of Sig Figs in a
     calculation and as a result are assumed to have an
     UNLIMITED number of Sig Figs.

     Exact numbers are those that are determined by counting rather
     than measuring; they also arise from definitions of quantities.

     102 people were in the room; it indicates that EXACTLY 102
     people were in the room; not 101 or 105 or 102.334 people. The
     number 102 is an EXACT number and carries with it an unlimited
     number of Sig Figs.
Rules to determine Sig Figs:

3.      Treatment of zeros (note: if you have a problem with Sig
       Figs it will be here). There are three types of zeros:

i)     Leading zeros (zeros that precede all of the non-zero digits [i.e.
       are to the left]) NEVER count as Sig Figs;

ii)    Captive zeros (zeros that fall between non-zero digits) ALWAYS
       count as Sig Figs;

iii)   Trailing zeros (zeros at the right end of a number) are ONLY
       SIGNIFICANT IF THE NUMBER CONTAINS A DECIMAL POINT.
Leading zeros:

Say you have a counter on a turnstile that reads ‘0012’. The zeros
here are NOT significant (think about it...they simply tell you that less
than 1100 people have passed through your turnstile). This number
has TWO Sig Figs.

0.00034; here this number has four leading zeros, none of which are
significant...all they do is fix the decimal point. This number has TWO
Sig Figs.
Captive zeros:

10.005 has three captive zeros ALL of which are significant. This
number therefore has FIVE Sig Figs.

                        Trailing zeros

120 has two significant figures, while 120. has three; the decimal
point indicates that the zero IS significant.

What about 10.000? If you said it has FIVE Sig Figs, you’d be correct!
By the way, if I said that I counted 120 oranges, now that number has
THREE Sig Figs, since it is now an exact number and should be best
represented by writing 120..
Significant Figures (Sig Figs)
   1.23     grams    =    3
   0.000123 grams    =    3
    2.0    grams     =    2

   0.020   grams     =    2

    100    grams     =    1

    100.   grams     =    3
a defined quantity   =   infinity
Rules of use:

1.Multiplication and Division:
           Least significant rules.

2. Addition and Subtraction
           Least # decimal places.

My suggestions:
i) Use all the numbers available for all calculations.
ii) When the calculation is done, then apply rules.

   Use rounding when appropriate.
What are Physical Properties?

Properties that can be seen and measured
without changing the composition of the
substance.
Physical Properties

•   Color
•   Density
•   Melting and Boiling points
•   Heat of fusion and vaporization
•   Solubility
•   Ability to conduct heat or electricity
•   Magnetic Properties
•   Metallic Character
•   Malleability
•   Ductility
•   Viscosity
States of Matter
Solid             Liquid
        melting
States of Matter
Liquid              Solid
         freezing
States of Matter
Liquid      gas
   vaporizing
States of Matter
gas        liquid
  condensing
States of Matter
 solid      gas

    subliming
States of Matter
 solid      gas

   deposition
FeS structure
      FeS

FeS2 (oro degli stolti)
                            FeS2 structure
Solute          Solvent        Solution
    gas O2 in a       gas N2          Air
  Gas CO2 in a     Liquid H2O   Carbonated Water
 liquid H2O in a     Gas Air         Fog
liquid EtOH in a   Liquid H2O        Wine
  Liquid Hg in a     Solid Ag     Dental-filling
Solid NaCl in a    Liquid H2O        Brine
 Solid Ag in a       Solid Au    14 Karat gold
Chemical Change
 Reactants                                      Products
The number and
                                               Must equal those
kind of atoms on
                                               on this side of the
this side of the
                                               equation
equation

  This is the conservation of matter
                   Antoine-Laurent Lavoisier
                     (Paris 1743, ivi 1794)
This is Antoine Lavoisier's
(1743-94) first book. It deals with
the phenomena of disengagement
and fixation of an elastic fluid
during combustion and
fermentation. It represents the
first phase in a series of
experiments which ultimately led
to the rejection of the phlogiston
theory and the discovery of
oxygen. In order to have the book
published, Lavoisier had to
reperform all the experiments
before the Commissioners of the
Royal Academy of Sciences in Paris.
The Traité was his crowning
achievement giving a full
exposition of his and his disciples
achievement in chemistry. It opens
with the famous 'Discours
preliminaire' which outlines his
views on methodology. Indeed the
'Discours' is the most widely read
of Lavoisier's writings today. In the
Traité Lavoisier included a table of
substances simples which is a
precursor to the Periodic Table. It
is quite revealing as to the state of
knowledge about material
elements in his day. The thirteen
copperplate engravings are the
work of Lavoisier's wife who
dedicated her life to assisting and
promoting her husband's work.
You can also read