Accurate temperature measurement by temperature field analysis in diamond anvil cell for thermal transport study of matter under high pressures

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Diamond negatively charged nitrogen-vacancy (NV − ) centers provide an opportunity for the measurement of the Meissner effect on extremely small samples in a diamond anvil cell (DAC) due to their high sensitivity in detecting the tiny change of magnetic field. We report on the variation of magnetic field distribution in a DAC as a sample transforms from normal to superconducting state by using finite element analysis. The results show that the magnetic flux density has the largest change on the sidewall of the sample, where NV − centers can detect the strongest signal variation of the magnetic field. In addition, we study the effect of magnetic coil placement on the magnetic field variation. It is found that the optimal position for the coil to generate the greatest change in magnetic field strength is at the place as close to the sample as possible.

Section: Theoretical Modelsmentioning

confidence: 99%

Magnetic field analysis in a diamond anvil cell for Meissner effect measurement by using the diamond NV ^– center

Zhao¹,

Yue²,

Liu³

et al. 2019

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“…[9][10][11][12][13][14] When a DAC is subjected to high temperatures it can simulate the conditions in the earth's interior in the laboratory, which is of great importance for investigating the thermal properties of minerals and rocks. [15][16][17] However, it is an enormous challenge to characterize the thermophysical properties of the material under test at conditions of extremely high temperature and high pressure (HT-HP). [18] This challenge is even more pronounced in the DAC platform.…”

Section: Introductionmentioning

confidence: 99%

“…In order to accurately measure the heat transport properties of materials under extreme conditions, innovations have been proposed to measure the steady-state heat conductivity of materials through a DAC. [17] The main idea in this regard was to realize the temperature gradient of samples by directly heating the upper and lower diamond anvils (DAs) in a high-temperature resistant furnace. Therefore, it is essential to calculate the temperature distributions in the sample to study the in situ heat transport properties in the DAC.…”

Section: Introductionmentioning

confidence: 99%

Investigating the thermal conductivity of materials by analyzing the temperature distribution in diamond anvils cell under high pressure

Jia¹,

Cao²,

Ji³

et al. 2022

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Investigating the thermal transport properties of materials is of great importance in the field of earth science and for the development of materials under extremely high temperatures and pressures. However, it is an enormous challenge to characterize the thermal and physical properties of materials using the diamond anvil cell (DAC) platform. In the present study, a steady-state method is used with a DAC and a combination of thermocouple temperature measurement and numerical analysis is performed to calculate the thermal conductivity of the material. To this end, temperature distributions in the DAC under high pressure are analyzed. We propose a three-dimensional radiative–conductive coupled heat transfer model to simulate the temperature field in the main components of the DAC and calculate in situ thermal conductivity under high-temperature and high-pressure conditions. The proposed model is based on the finite volume method. The obtained results show that heat radiation has a great impact on the temperature field of the DAC, so that ignoring the radiation effect leads to large errors in calculating the heat transport properties of materials. Furthermore, the feasibility of studying the thermal conductivity of different materials is discussed through a numerical model combined with locally measured temperature in the DAC. This article is expected to become a reference for accurate measurement of in situ thermal conductivity in DACs at high-temperature and high-pressure conditions.

“…The designed apparatus is equipped with a vacuum device to realize a stable heat flow field in the DAC. [7] Thermal loads are caused by temperature inhomogeneity in the steady-state heating, and the influence of thermal loads on the structural reliability of DAC and measuring the sample thickness are the main challenges in the early stage of the experiment. [8][9][10] Yue et al in our research group proposed the method of multi-thermocouple in situ temperature measurement combined with the numerical model to simulate the distribution of sample temperature field in DAC by heat conduction, and established a brand-new sample thermal conductivity measurement method.…”

Section: Introductionmentioning

confidence: 99%

“…[8][9][10] Yue et al in our research group proposed the method of multi-thermocouple in situ temperature measurement combined with the numerical model to simulate the distribution of sample temperature field in DAC by heat conduction, and established a brand-new sample thermal conductivity measurement method. [7] However, the in situ thermal conductivity of samples studied by this method depends on the structural size of the main components of DAC. It is worth noting that at this moment, the stress state and deformation degree of diamond anvils (DAs) and sample under HTHP conditions are not clear.…”

Section: Introductionmentioning

confidence: 99%

Effect of deformation of diamond anvil and sample in diamond anvil cell on the thermal conductivity measurement*

Jia¹,

Jiang²,

Cao³

et al. 2021

Self Cite

Studies show that the sample thickness is an important parameter in investigating the thermal transport properties of materials under high-temperature and high-pressure (HTHP) in the diamond anvil cell (DAC) device. However, it is an enormous challenge to measure the sample thickness accurately in the DAC under severe working conditions. In conventional methods, the influence of diamond anvil deformation on the measuring accuracy is ignored. For a high-temperature anvil, the mechanical state of the diamond anvil becomes complex and is different from that under the static condition. At high temperature, the deformation of anvil and sample would be aggravated. In the present study, the finite volume method is applied to simulate the heat transfer mechanism of stable heating DAC through coupling three radiative-conductive heat transfer mechanisms in a high-pressure environment. When the temperature field of the main components is known in DAC, the thermal stress field can be analyzed numerically by the finite element method. The obtained results show that the deformation of anvil will lead to the obvious radial gradient distribution of the sample thickness. If the top and bottom surfaces of the sample are approximated to be flat, it will be fatal to the study of the heat transport properties of the material. Therefore, we study the temperature distribution and thermal conductivity of the sample in the DAC by thermal-solid coupling method under high pressure and stable heating condition.