Abstract
We developed a new technique for measuring the thermodynamic entropy as a function of the magnetic field angle. This technique enables high-resolution angle-resolved measurements of the entropy in an unprecedentedly short measuring time. When the magnetic field is rotated under adiabatic conditions, the sample temperature changes owing to the field-angle variation of its entropy, which is referred to as the rotational magnetocaloric effect. By investigating this effect along with the specific heat, the field-angle dependence of the entropy can be determined. To demonstrate this technique, we chose the spin-ice compound Dy$_2$Ti$_2$O$_7$ as a benchmark and showed good agreement between the measured and theoretical entropies as a function of the field angle. This development provides a new approach to studying condensed-matter physics, in which multiple degrees of freedom play an important role.
Highlights
The entropy S is one of the most fundamental thermody- In this paper, we propose a new experimental technique namic quantities and is related to the number of microscopic configurations of the system
We developed a new technique for measuring the thermodynamic entropy as a function of the magnetic field angle
When the magnetic field is rotated under adiabatic conditions, the sample temperature changes owing to the field-angle variation of its entropy, which is referred to as the rotational magnetocaloric effect
Summary
The entropy S is one of the most fundamental thermody- In this paper, we propose a new experimental technique namic quantities and is related to the number of microscopic configurations of the system. Field-rotational Magnetocaloric Effect: A New Experimental Technique for High-resolution Measurement of the Anisotropic Magnetic Entropy Shunichiro Kittaka1 ∗, Shota Nakamura1 †, Hiroaki Kadowaki2, Hiroshi Takatsu3, and Toshiro Sakakibara1
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