Explaining periodicity

Slides:



Advertisements
Similar presentations
Electron Configuration and Periodic Properties
Advertisements

Trends in the Periodic Table (Chpt. 7). 1. Atomic radius (size) 2. Ionization energy 3. Electronegativity The three properties of elements whose changes.
The Periodic Table.
Trends in the periodic table. Atomic radius Atomic radii trends and explanations Atomic radius decreases across a period because each successive element.
Periodic Trends. Predicting Periodic Trends A number of physical and chemical properties of elements can be predicted from their position in the periodic.
1 Periodic Table II Periodic table arranged according to electron arrangement Periodic table also arranged according to properties? Properties must depend.
Agenda Block 4 Attendance Make Groups for element assignment
By the end of this section, I will be able to:
Periodic Trends MYP/Honors Chemistry.
Electron Configuration and Periodic Properties
Periodic Trends.
Periodic Trends.
Periodic Trends Mrs. Coyle Chemistry.
and Electronegativity
Lecture 29 Periodic trends Ozgur Unal
Aim: What are the Properties of Groups and how does the atomic radius change across a period and down a group? Do Now: Answer in your notebook If an atom.
Periodic Trends.
Shielding Effect The shielding effect is the reduction of attractive force between the nucleus (+) and its outer electrons (-) due to the blocking affect.
Suggested Reading Pages Section 5-3
Periodic Trends.
Trends in the Periodic Table
Mr. Bablu Kumar Assistant professor PGGC Sector 11 Chandigarh
Periodic Trends Chemistry.
Aim: Determining ionization energy and electronegativity of elements
Examination of properties reveals why
Ions, Electron Affinity and Metallic Character
Periodic Trends.
Ionic Radius Ionization Energy Electron Affinity
Dr. Vatsala Soni PGGC Sector 11 Chandigarh
Periodic Table Trends.
Periodic Trends.
Periodic Trends Chemistry 5(C)
Trends In The Periodic Table
Periodic Trends.
Elemental Properties and Patterns
5.3 Electron Configuration & Periodic Properties
Exploring Periodic Trends
Periodic Trends.
Valence Electrons Highest or outermost energy level electrons
Bellwork Get out the worksheets you worked on last class period, the periodic table we colored, and a blank sheet of paper.
Part IV: Periodic Trends
Section 4.5—Periodicity – Notable trends of the table
Periodic Trends.
Periodic Trends.
Graph #1: Atomic Radius vs. Atomic Number
Trends In the periodic table
Section 4.5—Periodicity – Notable trends of the table
Periodic Trends Glencoe: Section 6.3.
Bellwork: I am going to give you 15 min as a group to explain each of your trends. So, get your computer and start discussing.
Elemental Properties and Patterns
Periodic Trends.
Periodic Trends Chapter 14.2.
TRENDS IN THE PERIODIC TABLE.
Periodic Table Trends.
Periodic Table & Periodic Trends
Warm Up Write the longhand electron configuration for the following elements: Cr F Sr.
Section 3 Trends and the Periodic Table
Periodic Trends.
Section 4.5—Periodicity.
Trends of the Periodic Table
5.3 Electron Configuration & Periodic Properties
Periodic Trends.
Ionization energy, Atomic Radii and Electronegativity
Chemical Periodicity.
1.4 Learning Outcomes down a group
Atomic Radii Ionic Radii Ionization Energies Electronegativity
Periodic Trends.
Periodic Trends.
Periodic Trends Chemistry.
Periodic Trends.
Presentation transcript:

Explaining periodicity When asked to compare atoms or ions of different elements start by comparing the fundamental factors and determine how they affect the other properties. What are the fundamental factors?

Fundamental Factors Nuclear charge of atom or ion (number of protons) Effective nuclear charge (= atomic number – number of electrons on filled inner principal energy levels) energy level being filled/ number of filled energy main energy levels/ shielding effect number of electrons: the more electrons , the greater the repulsion

Atomic Radius Describe the trends in the atomic radius across period 3 and also down group 1 You need to refer to all three fundamental factors

Across period 3 from left to right Atomic size/radius decreases as you move across because: the nuclear charge increases; electrons are added to same main energy level /similar shielding effect as the number of complete inner energy levels is the same. As a result of the above two factors the effective nuclear charge increases and the outer electrons are attracted more strongly. The increased repulsion between the electrons which would cause the radius to increase is cancelled out by the increased nuclear charge.

Down the group Increases as you go down because: the number of main energy levels increases (more electrons) which cancels out the increase in nuclear charge; outermost electron is placed in a higher energy level which is further away from the nucleus. the shielding effect increases as you go down as there are more filled energy levels.

Ionic radius The atomic radius changes when atoms form ions Positive ions always have a smaller ionic radius that the original atom. Because: the loss of electron(s) means that the remaining electrons each have a greater share of the positive charge of the nucleus so are more tightly bound And when an ion in formed, a whole ion shell is usually lost

Ionic Radius Negative ion has a larger atomic radius than that of the original atom even though the extra electrons are in the same electron shell, the addition of the negative charge means that the electrons are less tightly bound to the nucleus So the atomic radius is larger

Questions Arrange the following from shortest to longest atomic radium Sodium, Lithium, Potassium Magnesium, sulfur, Germanium Argon, Potassium or calcium Cl-, S2-, P3-, Ar Na+, Ne or F-

Answers Li  Na  K S  Mg  Ge Ar  Ca  K Ar Cl-  S2-  P3- Na+  Ne  F-

Electron Affinity Electron affinity of an element is the enthalpy change that occurs when one electron is gained by each atom in a mole of gaseous atoms of the element to give one mole of gaseous ions, each with a single negative charge (at standard temperature and pressure). Electron affinity can be negative (usually e.g. halogens) which means it is an exothermic process as energy is released or it can be positive (like some group 2 elements or the noble gases in group 18) indicating an endothermic process. The equation defines first electron affinity: X (g) + e-  X- (g) The more negative the electron affinity value the greater the ability of the atoms of the element to accept electrons.

Horizontal trend Overall electron affinities become more negative as you go across a period because when moving to the across the periods: the positive nuclear charge increases; the atomic radius decreases so the nucleus can attract other electrons better; the difference in shielding effect is minimal as all have the same number of filled inner shells.

Vertical trend Trends differ in different groups but generally electron affinity values become less negative as you go down a group because ... the number of main energy levels increases, increasing the shielding effect on free electrons (=electrons part of another atom), increased nuclear charge but this is cancelled out by the increased shielding – similar effective nuclear charge; increased atomic radius;

Electronegativity Electronegativity is the ability for an atom to attract a bonding pair of electrons (a shared pair in a diatomic covalent bond). The more commonly used scale is the Pauling scale in which all values are measured relative to fluorine that has the maximum electronegativity of 4.0.

Horizontal trend Increases when moving to the across the periods because: the positive nuclear charge increases; the atomic radius decreases so the nucleus can attract other electrons better; the difference in shielding effect is minimal as all have the same number of filled inner shells.

Vertical trend Decreases as you go down groups: the number of main energy levels increases, increasing the shielding effect on free electrons (=electrons part of another atom), increased the atomic radius; the two above cancel out the increased nuclear charge.

Ionization energy Ionization energy refers to the minimum amount of energy required to remove an electron from one mole of gaseous atoms (or ions); it is measured in kilojoules per 1 mole and is defined by the following equation:   atom in ground state (g) + IE atom + (g) + e - Ionization energy has a positive value as it is an endothermic process – energy is needed.

Horizontal trend Overall trend = ionisation energy increases when moving across because more energy is needed because: the increased nuclear charge; smaller atomic radius (outermost electron closer to nucleus); electrons go in the same energy level (similar shielding effect).   The result is a stronger attraction that pulls the valence electrons closer to the nucleus/stronger attraction.

Vertical trend Ionisation energy decreases as you go down groups because: Atomic radius increases/outer electron to be removed is further away from nucleus, reducing the attraction between the valence electrons and the nucleus (this offsets the increased nuclear charge). Increased shielding as there are more energy levels so there is less effective nuclear charge; increased shielding also offsets increased nuclear charge.

Summary physical property horizontal trend vertical trend   atomic radius decreases increases ionization energy electronegativity cation radius anion radius electron affinity

Summary questions

On mini white boards

Answers A B C

Questions

Answers D