Lectures related to Experimental Techniques: Sensitivity

The Biochemistry of Fear and Organic Chemistry Concepts

Delves into the biochemistry of fear and organic chemistry concepts.

Heat Capacity and Degrees of Freedom in Thermodynamics

Covers heat capacity, degrees of freedom, and their implications in thermodynamics.

Internal Energy and Specific Heat

Covers the calculation of internal energy and specific heat for gases, electrons, phonons, and photons.

Thermal Energy and Degrees of Freedom

Explores energy equipartition in ideal gases, heat capacity, and thermodynamic transformations.

Thermodynamics: Internal Energy and Heat Capacity

Covers internal energy, heat capacity, and their roles in thermodynamics.

Specific Heat and Latent Heat in Matter States

Explores heat exchange, specific heat, and latent heat in different materials and phase transitions.

Protein Folding: Principles and Thermodynamics

Explores protein folding principles, thermodynamics, Boltzmann distribution, and NMR structures in biomolecules.

First Law of Thermodynamics: Energy Conservation

Explores the conservation of energy in thermodynamic systems through heat and work interactions, introducing internal energy, enthalpy, and heat capacity.

Resonance Techniques: ESR, NMR, and mu SR

Explores electron spin resonance, nuclear magnetic resonance, and mu spin resonance techniques.

Organic Chemistry: Delocalization and Resonance Structures

Discusses organic chemistry's role in everyday compounds and the concept of resonance structures, exploring factors affecting stability and the significance of resonance in understanding reactivity.

Magnetic Resonance Spectroscopy: Nanoliter Scale Advances

Explores magnetic resonance spectroscopy at the nanoliter scale, covering state-of-the-art techniques and advancements in single chip detectors.

Experimental Techniques: Specific Heat & ESR

Discusses challenges in determining system entropy and multiple contributions to specific heat.

Nuclear Overhauser Effect

Explores the Nuclear Overhauser effect in magnetic resonance and its impact on spin relaxation and enhancement.

Spin Relaxation in Magnetic Resonance

Introduces the fundamentals of spin relaxation in magnetic resonance, covering spin-lattice and spin-spin relaxation, and rotational motion in liquids.

Specific Heat at Constant Pressure

Explores specific heat at constant pressure, enthalpy, ideal gases, adiabatic exponent, and solid-specific heat.

Organic Chemistry: Acidity Analysis and Resonance Stabilization

Explores acidity analysis, resonance stabilization, and factors influencing acid strength in organic chemistry.

Hyperfine Coupling: Experimental Techniques & Specific Heat

Explores hyperfine coupling between electronic and nuclear spins, affecting energy levels.

Thermo1: Evaluating Properties

Explores evaluating properties of substances, including liquids, solids, ideal gases, and real gases, emphasizing specific heat and enthalpy.

Thermophysical Properties: Models and Applications

Explores classical and quantum models to understand heat capacity in solids and discusses the relation between heat capacities at constant volume and pressure.

The Science of Fear: Biochemistry and Brain Response

Delves into the biochemistry of fear and the role of resonance structures in acid-base reactions.