Inhalt
[ 290MAFSTMAK26 ] KV (*)Tutorium Mathematics for Chemistry
|
|
|
|
| (*) Leider ist diese Information in Deutsch nicht verfügbar. |
 |
| Workload |
Ausbildungslevel |
Studienfachbereich |
VerantwortlicheR |
Semesterstunden |
Anbietende Uni |
| 1,5 ECTS |
B1 - Bachelor 1. Jahr |
Mathematik |
Markus Passenbrunner |
1 SSt |
Johannes Kepler Universität Linz |
|
|
 |
| Detailinformationen |
| Quellcurriculum |
Bachelorstudium Chemistry and Chemical Technology 2026W |
| Lernergebnisse |
Kompetenzen |
| (*)Build clear mathematical arguments in plain language, translate between symbols, graphs, and real-world descriptions, and spot common logical mistakes.
Model simple chemical and physical situations with functions, equations, vectors, and matrices; choose suitable analytic or numerical methods; and judge whether results are reasonable.
Move comfortably between exact solutions and approximations, quantify error or uncertainty, and communicate assumptions and limitations.
Work effectively in groups: explain reasoning, critique solutions constructively, and identify gaps in understanding.
|
|
Fertigkeiten |
Kenntnisse |
(*)- Definitions to decisions: read and use definitions (set, function, limit, derivative, integral, vector, basis) and build/check counterexamples. (k1, k2, k3)
- Single-variable analysis: evaluate limits and continuity; differentiate; use derivatives to optimize and interpret rates of change; estimate with linearization. (k2, k3, k4)
- Multivariable analysis: compute partial derivatives, gradients, Jacobians, and Hessians; interpret sensitivity and curvature; find and classify extrema (intro to constraints/Lagrange multipliers). (k2, k3, k4)
- Integration as accumulation: compute definite integrals; apply the Fundamental Theorem of Calculus; use substitutions and basic coordinate changes; interpret areas, masses, totals; do simple line/curve integrals. (k2, k3, k4)
- Linear systems and matrices: solve systems via Gaussian elimination; understand rank and consistency; compute and interpret determinants, eigenvalues, and eigenvectors in small cases. (k2, k3, k4)
- Sequences and series for approximation: decide convergence with core tests; use geometric and Taylor series to approximate functions and estimate errors; understand Fourier coefficients for periodic signals. (k2, k3, k4)
- Differential equations: solve separable and first-order linear ODEs; analyze fixed points and qualitative behavior; connect to kinetics and relaxation processes. (k2, k3, k4)
- Numerical methods and data: apply bisection and understand Newton’s method conceptually; perform least-squares linear regression; report error bounds and check stability/conditioning. (k3, k4, k5)
- Coordinate transformations: use polar/cylindrical/spherical changes with the Jacobian to simplify integrals. (k2, k3, k4)
- Sanity checks and estimation: dimensional analysis, order-of-magnitude estimates, bounding arguments, and limit-case checks. (k2, k3, k4)
|
(*)- Core objects and structures: sets and functions; real numbers and completeness (why limits exist); sequences and series; vector spaces, linear independence, bases; norms, inner and cross products.
- Key theorems and ideas (at an intuitive, usable level): Intermediate Value and Mean Value ideas; Bolzano–Weierstrass (compactness intuition); Fundamental Theorem of Calculus; Taylor’s theorem with remainder; convergence test intuition (geometric, comparison, ratio, alternating/Leibniz); Implicit Function idea for local solvability; Fubini and change of variables with the Jacobian; Schwarz’s theorem for mixed partials.
- Common formulas and tools worth memorizing or recognizing: binomial and geometric series; basic Taylor expansions (exp, sin, cos, log) and their error terms; small-matrix determinants and eigenpairs; cross product; least-squares normal equations.
- Problem-solving heuristics: sketch first; pick a simple model; approximate before calculating exactly; check units; test extreme and special cases; compare against bounds or known values; communicate the “why” with the “what.”
|
|
| Beurteilungskriterien |
(*)compulsory attendance, written examination
|
| Lehrinhalte wechselnd? |
Nein |
| Sonstige Informationen |
(*)- The Chemistry Maths Book, Erich Steiner, Oxford University Press, 1996, ISBN 0-19-855913-5
- Mathematics for Physical Chemistry, Robert G. Mortimer, Elsevier, 2005, ISBN 0-12-508347-5
- Maths for Chemistry: A chemist’s toolkit of calculations, Paul Monk and Lindsey J. Munro, Oxford University Press, 2010, ISBN 0-19-954129-9
- Mathematics for Chemists, G. Francis, Springer, 1984, ISBN 978-94-010-8950-0
Until termin 2026S known as: 663MAPHIMAK19 Introduction to Mathematics
|
| Äquivalenzen |
(*)290MAFSMA1U26: UE Exercises for Mathematics in Chemistry I (3 ECTS) in combination with
290MAFSTMAK26: KV Tutorium Mathematics for Chemistry (1,5 ECTS)
is equivalent to
290MAFSMC1K19: KV Applications of Mathematics in Chemistry with Exercises I (4,5 ECTS)
|
| Gilt als absolviert, wenn |
(*)663MAPHIMAK19: KV Introduction to Mathematics (1.5 ECTS)
|
|
|
 |
| Präsenzlehrveranstaltung |
| Teilungsziffer |
35 |
| Zuteilungsverfahren |
Direktzuteilung |
|
|
|