Title: W No class! Celebrate with a veteran.
1W No class! Celebrate with a veteran.
- R, F I will be out of town. My lab and lecture F
will be taught by Brandon. And yes, it will be
on the exam. - Exam next T Ch 7 and 8
- Review M 1 pm BH 419
2(No Transcript)
3Quantum Numbers Noble Gases
Electron Orbitals
Number of Electrons Element
1s2
2
He
1s2 2s22p6
10
Ne
1s2 2s22p6 3s23p6
18 Ar
1s2 2s22p6 3s23p6 4s23d104p6
36 Kr
1s2 2s22p6 3s23p6 4s23d104p6 5s24d105p6
54 Xe
1s2 2s22p6 3s23p6 4s23d104p6 5s24d105p6
6s24f14 5d106p6 86 Rn
1s2 2s22p6 3s23p6 4s23d104p6 5s24d105p6
6s24f145d106p6 7s25f146d10?
4- There are a few exceptions to the building-up
order prediction for the ground state. - Chromium (Z24) and copper (Z29) have been found
by experiment to have the following ground-state
electron configurations - Cr 1s2 2s2 2p6 3s2 3p6 3d5 4s1
- Cu 1s2 2s2 2p6 3s2 3p6 3d10 4s1
- In each case, the difference is in the 3d and 4s
subshells.
5- There are several terms describing electron
configurations that are important. - The complete electron configuration shows every
subshell explicitly.
6- The noble-gas configuration substitutes the
preceding noble gas for the core configuration
and explicitly shows subshells beyond that. - Br Ar3d104s24p5
7- The pseudo-noble-gas core includes the noble-gas
subshells and the filled inner, (n 1), d
subshell. - For bromine, the pseudo-noble-gas core is
- Ar3d10
8- The valence configuration consists of the
electrons outside the noble-gas or
pseudo-noble-gas core. - Br 4s24p5
9- For main-group (representative) elements, an s or
a p subshell is being filled. - For d-block transition elements, a d subshell is
being filled. - For f-block transition elements, an f subshell is
being filled.
10- Write the complete electron configuration of the
arsenic atom, As, using the building-up principle.
For arsenic, As, Z 33.
1s2
2s2
2p6
3s2
3p6
3d10
4s2
4p3
11- What are the electron configurations for the
valence electrons of arsenic and cadmium?
Arsenic is in period 4, Group VA. Its valence
configuration is
4s24p3.
Cadmium, Z 30, is a transition metal in the
first transition series. Its noble-gas core is
Ar, Z 18. Its valence configuration is
4s23d10.
12When n 2, there are two subshells. The s
subshell has one orbital, which could hold one
electron. The p subshell has three orbitals,
which could hold three electrons.
This would give a total of four elements for the
second period.
13- In 1927, Friedrich Hund discovered, by
experiment, a rule for determining the
lowest-energy configuration of electrons in
orbitals of a subshell. - Hunds rule states that the lowest-energy
arrangement of electrons in a subshell is
obtained by putting electrons into separate
orbitals of the subshell with the same spin
before pairing electrons.
14- For nitrogen, the orbital diagram would be
15- Write an orbital diagram for the ground state of
the nickel atom.
For nickel, Z 28.
16- Which of the following electron configurations or
orbital diagrams are allowed and which are not
allowed by the Pauli exclusion principle? If they
are not allowed, explain why?
- Allowed excited.
- p8 is not allowed.
- Allowed.
- d11 is not allowed.
- Not allowed electrons in one orbital must have
opposite spins.
- 1s22s12p3
- 1s22s12p8
- 1s22s22p63s23p63d8
- 1s22s22p63s23p63d11
-
17- Magnetic Properties of Atoms
- Although an electron behaves like a tiny magnet,
two electrons that are opposite in spin cancel
each other. Only atoms with unpaired electrons
exhibit magnetic susceptibility. - This allows us to classify atoms based on their
behavior in a magnetic field.
18- A paramagnetic substance is one that is weakly
attracted by a magnetic field, usually as the
result of unpaired electrons. - A diamagnetic substance is not attracted by a
magnetic field generally because it has only
paired electrons.
19- You learned how the organization of the periodic
table can be explained by the periodicity of the
ground-state configurations of the elements. Now
we will look at various aspects of the
periodicity of the elements.
20- Mendeleevs periodic table generally organized
elements by increasing atomic mass and with
similar properties in columns. In some places,
there were missing elements whose properties he
predicted. - When gallium, scandium, and germanium were
isolated and characterized, their properties were
almost identical to those predicted by Mendeleev
for eka-aluminum, eka-boron, and eka-silicon,
respectively.
21- Periodic law states that when the elements are
arranged by atomic number, their physical and
chemical properties vary periodically. - We will look in more detail at three periodic
properties atomic radius, ionization energy, and
electron affinity.
22- Atomic Radius
- While an atom does not have a definite size, we
can define it in terms of covalent radii (the
radius in covalent compounds).
23- Trends
- Within each group (vertical column), the atomic
radius increases with the period number. - This trend is explained by the fact that each
successive shell is larger than the previous
shell.
24- Within each period (horizontal row), the atomic
radius tends to decrease with increasing atomic
number (nuclear charge).
25- Effective Nuclear Charge
- Effective nuclear charge is the positive charge
that an electron experiences from the nucleus. It
is equal to the nuclear charge, but is reduced by
shielding or screening from any intervening
electron distribution (inner shell electrons).
26- Effective nuclear charge increases across a
period. Because the shell number (n) is the same
across a period, each successive atom experiences
a stronger nuclear charge. As a result, the
atomic size decreases across a period.
27- Atomic radius is plotted against atomic number in
the graph below. Note the regular (periodic)
variation.
28A representation of atomic radii is shown below.
29- Refer to a periodic table and arrange the
following elements in order of increasing atomic
radius Br, Se, Te.
Te is larger than Se. Se is larger than Br.
Br lt Se lt Te
30- First Ionization Energy (first ionization
potential) - The minimum energy needed to remove the
highest-energy (outermost) electron from a
neutral atom in the gaseous state, thereby
forming a positive ion
31- Trends
- Going down a group, first ionization energy
decreases. - This trend is explained by understanding that the
smaller an atom, the harder it is to remove an
electron, so the larger the ionization energy.
32- Generally, ionization energy increases with
atomic number. - Ionization energy is proportional to the
effective nuclear charge divided by the average
distance between the electron and the nucleus.
Because the distance between the electron and the
nucleus is inversely proportional to the
effective nuclear charge, ionization energy is
inversely proportional to the square of the
effective nuclear charge.
33- Small deviations occur between Groups IIA and
IIIA and between Groups VA and VIA. - Examining the valence configurations for these
groups helps us to understand these deviations - IIA ns2
- IIIA ns2np1
- VA ns2np3
- VIA ns2np4
It takes less energy to remove the np1 electron
than the ns2 electron.
It takes less energy to remove the np4 electron
than the np3 electron.
34- Electrons can be successively removed from an
atom. Each successive ionization energy
increases, because the electron is removed from a
positive ion of increasing charge. - A dramatic increase occurs when the first
electron from the noble-gas core is removed.
35- Left of the line, valence shell electrons are
being removed. Right of the line, noble-gas core
electrons are being removed.
36- Refer to a periodic table and arrange the
following elements in order of increasing
ionization energy As, Br, Sb.
Sb is larger than As. As is larger than Br.
Ionization energies Sb lt As lt Br
37- Electron affinity (E.A.)
- The energy change for the process of adding an
electron to a neutral atom in the gaseous state
to form a negative ion - A negative energy change (exothermic) indicates a
stable anion is formed. The larger the negative
number, the more stable the anion. Small negative
energies indicate a less stable anion. - A positive energy change (endothermic) indicates
the anion is unstable.
38(No Transcript)
39The electron affinity is gt 0, so the element must
be in Group IIA or VIIIA. The dramatic
difference in ionization energies is at the third
ionization.
The element is in Group IIA.
40- Broadly speaking, the trend is toward more
negative electron affinities going from left to
right in a period. - Lets explore the periodic table by group.
41- Groups IIA and VIIIA do not form stable anions
their electron affinities are positive. - Group Valence Anion Valence
- IA ns1 ns2 stable
- IIIA ns2np1 ns2np2 stable
- IVA ns2np2 ns2np3 stable
- VA ns2np3 ns2np4 not so stable
- VIA ns2np4 ns2np5 very stable
- VIIA ns2np5 ns2np6 very stable
- Except for the members of Group VA, these values
become increasingly negative with group number.
42- Metallic Character
- Elements with low ionization energies tend to be
metals. Those with high ionization energies tend
to be nonmetals. This can vary within a group as
well as within a period.
43- Oxides
- A basic oxide reacts with acids. Most metal
oxides are basic. If soluble, their water
solutions are basic. - An acidic oxide reacts with bases. Most nonmetal
oxides are acidic. If soluble, their water
solutions are acidic. - An amphoteric oxide reacts with both acids and
bases.
44- Group IA, Alkali Metals (ns1)
- These elements are metals their reactivity
increases down the group. - The oxides have the formula M2O.
- Hydrogen is a special case. It usually behaves as
a nonmetal, but at very high pressures it can
exhibit metallic properties.
45- Group IIA, Alkaline Earth Metals (ns2)
- These elements are metals their reactivity
increases down the group. - The oxides have the formula MO.
46- Group IIIA (ns2np1)
- Boron is a metalloid all other members of Group
IIIA are metals. - The oxide formula is R2O3.
- B2O3 is acidic Al2O3 and Ga2O3 are amphoteric
the others are basic.
47- Group IVA (ns2np2)
- Carbon is a nonmetal silicon and germanium are
metalloids tin and lead are metals. - The oxide formula is RO2 and, for carbon and
lead, RO. - CO2, SiO2, and GeO2 are acidic (decreasingly so).
- SnO2 and PbO2 are amphoteric.
48- SiO2 (crystalline solid quartz)
49- Group VA (ns2np3)
- Nitrogen and phosphorus are nonmetals arsenic
and antimony are metalloids bismuth is a metal. - The oxide formulas are R2O3 and R2O5, with some
molecular formulas being double these. - Nitrogen, phosphorus, and arsenic oxides are
acidic antimony oxides are amphoteric bismuth
oxide is basic.
50- Group VIA, Chalcogens (ns2np4)
- Oxygen, sulfur, and selenium are nonmetals
tellurium is a metalloid polonium is a metal. - The oxide formulas are RO2 and RO3.
- Sulfur, selenium, and tellurium oxides are acidic
except for TeO2, which is amphoteric. PoO2 is
also amphoteric.
51- Group VIIA, Halogens (ns2np5)
- These elements are reactive nonmetals, with the
general molecular formula being X2. All isotopes
of astatine are radioactive with short
half-lives. This element might be expected to be
a metalloid. - Each halogen forms several acidic oxides that are
generally unstable.
52- Group VIIIA, Noble Gases (ns2np6)
- These elements are generally unreactive, with
only the heavier elements forming unstable
compounds. They exist as gaseous atoms.
53For R2O5 oxides, R must be in Group VA. R is a
metalloid, so R could be As or Sb. The oxide is
acidic, so
R is arsenic, As.