Course Information

Course Title	Code	Semester	L+U Hour	Credits	ECTS
INORGANIC CHEMISTRY I	KİM0307	5. Semester	4 + 0	4.0	5.0

Prerequisites

None

Language of Instruction	Turkish
Course Level	Bachelor's Degree
Course Type	Compulsory
Mode of delivery
Course Coordinator
Instructors	Mustafa HAYVALI
Assistants
Goals	To acquire basic information about the properties of metals, their mineral, methods of obtaining metals, reactions, compounds and industrial applications of metals.
Course Content	Structure of atom and atomic models, periodic properties of the atoms, intramolecular chemical bonds and structure of molecules, polarization theory and acids and bases.
Learning Outcomes	1) He/She describes the similarities and differences in the properties of the elements in the same and / or different groups and blocks of the periodic chart, based on the atomic structure. 2) He/She follows the current news and literature about inorganic chemistry. 3) He/She explains and compares Bohr, Quantum and Vector atom models related to the structure of atom. 4) He/She compares quantum mechanical approaches for wave functions of single-electron systems and multi-electron systems. 5) He/She asssociates the macro properties of elements with electron configurations of atoms. 6) He/She explains the bond type in compounds by using chemical bonding theories. 7) Discuss the geometry, magnetic and spectral properties of molecules using covalent bond theories. 8) He/She associates the properties of strong-weak and hard-soft in acids and bases with molecular structures. 9) He/She estimates the direction in which a chemical reaction will proceed.

Weekly Topics (Content)

Week	Topics	Teaching and Learning Methods and Techniques	Study Materials
1. Week	ATOMIC MODELS: Atom, Dalton atomic theory, Thomson atomic model, Black body radiation, Electromagnetic spectrum, The photoelectric effect.	Lecture; Question Answer; Discussion	Homework
2. Week	ATOMIC MODELS: Bohr atomic model, Calculation of Bohr radius, Energies of Bohr orbitals, Developments after the Bohr atomic model, Orbital.	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)
3. Week	ATOMIC MODELS: Quantum atomic model (Heisenberg uncertainty principle, de Broglie wavelength, Schrödinger wave equation), Quantum numbers (The principal quantum number, The angular quantum number or the angular momentum quantum number, The magnetic quantum number, The spin quantum number), Aufbau principle, Pauli Principle, Hund rule, Multiplicity.	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)
4. Week	ATOMIC MODELS: Quantum atomic model (Effective nuclear charge Z* and Slater’s rules and Magnetic properties).	Lecture; Question Answer; Discussion; Case Study	Presentation (Including Preparation Time)
5. Week	ATOMIC MODELS: Vector model of atom (Energies of terms (Hund’s selectivity rule), The ground state term symbol, Finding atomic term symbols, Spectroscopic transitions).	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)
6. Week	PERIODIC PROPERTIES OF ATOMS: Periodic table, Electron configurations of atoms, Atomic size (Covalent radius, Metallic radius, Ionic radius, Van der Waals radius), The lanthanide contraction.	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)
7. Week	PERIODIC PROPERTIES OF ATOMS: Ionization energy, Methods for calculating the ionization energy (Finding ionization energy of a single-electron system, Finding ionization ener gy for isoelectronic systems, Finding ionization energy by using Slater method, Finding ionization energy by solution of Schrödinger equation (Clamenti Raimondi), Finding ionization energy by the spectroscopic method (valence orbital ionization energy)).	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)
8. Week	PERIODIC PROPERTIES OF ATOMS: Electron affinity.	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)
9. Week	PERIODIC PROPERTIES OF ATOMS: Electronegativity (Pauling electronegativity, Mulliken electronegativity, Mulliken-Jaffe electronegativity, Alred-Rochow electronegativity, Sanderson electronegativity, Gordy electronegativity, Electronegativity of functional groups, Allen electronegativity (spektroscopik electronegativity), Hybridization and electronegativity, Benefits of electronegativity value, Equilibrium of electronegativity).	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)
10. Week	CHEMICAL BONDING: Classifications of chemical bonds, Intermolecular chemical bonds (Ionic bonds, Covalent bonds (Apolar covalent bonds, Polar covalent bonds, Coordinate covalent bonds), Metallic bonds).	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)
11. Week	CHEMICAL BONDING: Hybridization and Valence shell electron pair repulsion (VSEPR) theory.	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)
12. Week	CHEMICAL BONDING: Formal charge, Resonance, Resonance and stability of resonance structures, Bond order, Bond energy and Bond length, The contribution of σ and π bonds to multiple bonds, Bond force constant and bond energy, Bond energy and bond length, Use of bond energies to determine molecular structure and reaction enthalpy, Dipol moment.	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)
13. Week	POLARIZATION THEORY: Polarizing power and polarization, Fajans rules, Transition between ionic and covalent bond.	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)
14. Week	ACIDS AND BASES: Acid-Base Definitions (Arrhenius definition, Bronsted-Lowry definition, Definition of solvent system, Lewis sefinition, Gutman definition, Lux-Flood definition, Usanovich definition, Generalized definition, Ingold-Robinson definition, Definition of hard-soft acid-base), Power in acids and bases, Superacids.	Lecture; Question Answer; Discussion	Presentation (Including Preparation Time)

Sources Used in This Course

Recommended Sources

Anorganik Kimya; D. F. Shriver and P. W. Atkins, üçüncü baskı, çeviri editörleri: S. Özkar, A. Gül ve Y. Gök, Bilim Yayıncılık, 1999.

Chemistry of the Elements; N.N. Greenwood and A. Earnshaw, second edition, Elsevier 1997.

ICE Manual of Construction Materials: Metals and Alloys; Wei Sha, ICE, 2010.

İnorganik Kimya 2; Cemal Kaya, Palme Yayıncılık, 2008.

İnorganik Kimya; G. L. Miessler and D. A. Tarr, ikinci baskı, çeviri editörleri: N. Karacan ve P. Gürkan, Palme Yayıncılık, 2002.

Konu ile ilgili makaleler.

Metals and Alloys; Mark Anthony Benvenito, De Gruyter, 2016.

Temel Üniversite Kimyası; E. Erdik ve Y. Sarıkaya, Gazi Kitabevi, 2004.

Relations with Education Attainment Program Course Competencies

Program Requirements	Contribution Level	DK1	DK2	DK3	DK4	DK5	DK6	DK7	DK8	DK9
PY1	5	5	0	0	0	0	0	0	0	0
PY2	5	0	0	0	0	0	0	0	0	0
PY3	5	0	0	0	5	0	0	0	0	0
PY4	5	5	0	0	0	0	0	0	0	0
PY5	5	0	0	0	0	0	0	0	0	0

*DK = Course's Contrubution.

	0	1	2	3	4	5
Level of contribution	None	Very Low	Low	Fair	High	Very High

ECTS credits and course workload

Event	Quantity	Duration (Hour)	Total Workload (Hour)
Course Duration (Total weeks*Hours per week)	14	3	42
Work Hour outside Classroom (Preparation, strengthening)	14	2	28
Presentation (Including Preparation Time)	1	24	24
Report (Including Preparation and presentation Time)	1	8	8
Midterm Exam	1	1.5	1.5
Time to prepare for Midterm Exam	1	24	24
Final Exam	1	1.5	1.5
Time to prepare for Final Exam	1	24	24
Total Workload
Total Workload / 30 (s)
ECTS Credit of the Course			30

Quick Access

Chemistry
Normal Education

Course Information

Course Information
Weekly Topics (Content)
Sources Used in This Course
Relations with Education Attainment Program Course Competencies
ECTS credits and course workload

Course Information

Course Information

Weekly Topics (Content)

Sources Used in This Course

Relations with Education Attainment Program Course Competencies

ECTS credits and course workload

Quick Access

Chemistry Normal Education

Course Information

Chemistry
Normal Education