The present paper reports on a Finite Element Method (FEM) analysis of the experimental situation corresponding to the measurement of the temperature variation in a single cell plated on bulk diamond by means of optical techniques. Starting from previous experimental results, we have determined—in a uniform power density approximation and under steady-state conditions—the total heat power that has to be dissipated by a single cell plated on a glassy substrate in order to induce the typical maximum temperature increase DTglass = 1 K. While keeping all of the other parameters constant, the glassy substrate has been replaced by a diamond plate. The FEM analysis shows that, in this case, the maximum temperature increase is expected at the diamond/cell interface and is as small as DTdiam = 4.6 × 10−4 K. We have also calculated the typical decay time in the transient scenario, which resulted in t ≈ 250 μs. By comparing these results with the state-of-the-art sensitivity values, we prove that the potential advantages of a longer coherence time, better spectral properties, and the use of special field alignments do not justify the use of diamond substrates in their bulk form.

Limitations of Bulk Diamond Sensors for Single-Cell Thermometry

Alessio, A.
First
;
Truccato, M.
Last
2024-01-01

Abstract

The present paper reports on a Finite Element Method (FEM) analysis of the experimental situation corresponding to the measurement of the temperature variation in a single cell plated on bulk diamond by means of optical techniques. Starting from previous experimental results, we have determined—in a uniform power density approximation and under steady-state conditions—the total heat power that has to be dissipated by a single cell plated on a glassy substrate in order to induce the typical maximum temperature increase DTglass = 1 K. While keeping all of the other parameters constant, the glassy substrate has been replaced by a diamond plate. The FEM analysis shows that, in this case, the maximum temperature increase is expected at the diamond/cell interface and is as small as DTdiam = 4.6 × 10−4 K. We have also calculated the typical decay time in the transient scenario, which resulted in t ≈ 250 μs. By comparing these results with the state-of-the-art sensitivity values, we prove that the potential advantages of a longer coherence time, better spectral properties, and the use of special field alignments do not justify the use of diamond substrates in their bulk form.
2024
Inglese
Esperti anonimi
24
Special Issue - Quantum Sensors and Sensing Technology
200
210
11
https://www.mdpi.com/1424-8220/24/1/200
bio-sensing, diamond temperature sensors, finite element analysis
no
   TRUCCATO M. - Progetto M-ERA.NET Call 2016 "BIOMB: Advanced biodegradable materials based on MgB2 resistant to microbial colonization"
   MINISTERO DELL'ISTRUZIONE, DELL'UNIVERSITA' E DELLA RICERCA

   Photonic and nAnomeTric High-sensitivity biO-Sensing
   PATHOS
   European Commission
   Horizon 2020 Framework Programme
   828946
1 – prodotto con file in versione Open Access (allegherò il file al passo 6 - Carica)
262
6
Alessio, A.; Bernardi, E.; Moreva, E.; Degiovanni, I.P.; Genovese, M.; Truccato, M.
info:eu-repo/semantics/article
open
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2318/1950073
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