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15: Adiabatic Demagnetization

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    7311

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    • 15.1: Introduction
      This page discusses cooling methods for gases and materials, focusing on isothermal and adiabatic processes. It covers isothermal compression, adiabatic expansion, rubber band cooling techniques, and adiabatic demagnetization with paramagnetic salts for low temperatures. Additionally, it addresses work related to tension, pressure, and magnetization, and introduces several state functions. The author hints at future sections dedicated to temperature change derivations in adiabatic processes.
    • 15.2: Adiabatic Decompression
      This page explains how to calculate the partial derivative \((∂T/∂P)_S\), highlighting a positive correlation between temperature and pressure. It introduces a cyclic relation using entropy as a function of temperature and pressure, deriving the expression for \((∂T/∂P)_S\) with measurable quantities.
    • 15.3: Adiabatic Demagnetization
      This page covers adiabatic demagnetization, detailing the relationship between temperature (T) and magnetic field (B) with constant entropy (S). It derives the positive relationship \((∂T/∂B)_S\) and uses the cyclic relation to find \((∂T/∂B)_{S} = M / C_{B}\), linking magnetization (M) and heat capacity (C_{B}). The cooling effect is emphasized as being more significant at low temperatures.
    • 15.4: Entropy and Temperature
      This page discusses cooling by adiabatic demagnetization, involving isothermal magnetization that increases order and adiabatic demagnetization that lowers temperature, as shown in an entropy-temperature diagram. The described processes form a cycle that suggests a theoretical path to absolute zero. However, a forthcoming chapter will highlight a significant flaw in the assumption that reaching absolute zero is straightforward.

    This page titled 15: Adiabatic Demagnetization is shared under a CC BY-NC 4.0 license and was authored, remixed, and/or curated by Jeremy Tatum.