Enhancement of energy performance in betavoltaic cells by optimizing self-absorption of beta particles

Kim, Sang Woo; Lee, Nam-Ho; Jung, Heon; Kim, Ji Hyun

doi:10.1002/er.3470

Cited by 11 publications

(12 citation statements)

References 26 publications

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“…Rahmani et al, Kim et al, and Wu et al used a combination of closed form equations and Monte Carlo simulations to maximize nuclear and electrical power output based on a defined domain (i.e., radioisotope source layer thicknesses and dopant concentrations of the semiconductor junctions). However, η was never maximized nor prioritized in these publications …”

Section: Introductionmentioning

confidence: 99%

“…However, η was never maximized nor prioritized in these publications. [7][8][9][10][11] Optimization of 3-D coupling configuration with textured semiconductors and radioisotope source using experimental, analytical, and numerical methods was attempted with tritium gas and Si cylindrical array, 12 63 Ni and GaN pyramidal and cylindrical pillar array, 13 and 147 Pm and hexagonal array. 14 These textures semiconductor surfaces are produced from high aspect ratio microstructure technology (HARMST).…”

Section: Introductionmentioning

confidence: 99%

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Planar and textured surface optimization for a tritium‐based betavoltaic nuclear battery

et al. 2019

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Summary Remote, terrestrial, and space sensors require sources that have high enough power and energy densities for continuous operation for multiple decades. Conventional chemical sources have lower energy densities and lifetimes of 10 to 15 years depending on environmental conditions. Betavoltaic (βV) nuclear batteries using β‐‐emitting radioisotopes possess energy densities approximately 1000 times greater than conventional chemical sources. Their electrical power density (Pe,vol in W/cm3) in a given volume is a function of β‐‐flux surface power density ()Pβ−, surface interface type between radioisotope and transducer, β‐ range, and transducer thickness and conversion efficiency (ηs). Tritium is the most viable β‐‐emitting radioisotope because of its commercial availability, low biotoxicity, half‐life, and low energy, which minimizes the penetration depth and damage of transducer. To maximize Pe,vol, tritium in solid or liquid form must be used in the βV nuclear battery. A Monte Carlo source model using MCNP6 was developed to maximize the Pe,vol of a tritium‐based βV nuclear battery. First, a planar coupling configuration with different tritiated compounds (ie, titanium tritide and tritiated nitroxide) and a semiconductor transducer (4H‐SiC) with thicknesses of 1 and 100 μm were modeled. The results showed that β‐‐source efficiency (ηβ), which is the percentage of energy deposited in the transducer, decreased as the tritiated compound's mass density increased. The highest Pe,vol was dependent on a combination of characteristics: specific activity (Am in Ci/g), mass density, and 4H‐SiC layer thickness. The tritiated nitroxide with the highest Am at 2372 Ci/g produced the highest Pe,vol at 2.46 mW/cm3. Second, a 3‐D coupling configuration was modelled to increase surface interfacing between the radioisotope source and textured transducer surface. 3‐D coupling configuration increased the percentage of energy deposited into the transducer because of more surface interfacing between the transducer and source in the same volume. The tritiated nitroxide was selected as the radioisotope source coupled with five different textured surface feature types. The Pe,vol as a function of textured surface feature and gap, where the radioisotope is located, width was calculated for 1‐ and 100‐μm 4H‐SiC layer thicknesses. Results showed that ηβ increased compared with planar coupling configuration (ie, approximately 56.2% increase over planar with cylindrical hole array) except with the rectangular pillar array. Still, the rectangular pillar array produced the highest Pe,vol at 4.54 mW/cm3 with an increasing factor of 2.29 compared with the planar coupling configuration.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Planar and textured surface optimization for a tritium‐based betavoltaic nuclear battery

et al. 2019

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“…The indirect energy conversion mode can effectively reduce the radiation damage effect of the energy conversion unit in the device. This energy conversion method is expected to be applied to radiation sources with high activity and energy density …”

Section: Introductionmentioning

confidence: 99%

Radioluminescent nuclear battery containing CsPbBr ₃ quantum dots: Application of a novel wave‐shifting agent

et al. 2019

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Summary Radioluminescent nuclear battery has been widely studied for its miniaturization and long life. In this study, all‐inorganic perovskite quantum dots (CsPbBr3 QDs) were selected as a novel wave‐shifting agent combined with liquid scintillator PPO (2,5‐diphenyloxazole). The QDs were used to regulate the emission spectrum to match different GaAs devices. The maximum output power of the RL nuclear battery was greatly enhanced by 1.91 to 2.53 times. Perovskite QDs with adjustable emission spectra were used as wave‐shifting agents and exhibited more excellent properties and application prospects than traditional wave‐shifting agents. The Monte Carlo method was used to simulate the energy deposition of fluorescent materials under various radioactive source models. Results verified the advantages of using liquid radioactive sources and liquid fluorescent materials. The application and reference value of perovskite QDs in nuclear detection and nuclear medical imaging were also discussed.

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“…Specific research contents include changing experimental materials, varying physical parameters, optimizing structural design, and analyzing environmental factors . According to previous research results, it was found that selecting the excellent performance materials, proper coupling between these materials, and optimizing the battery structure are required to achieve maximum nuclear‐to‐electrical conversion efficiency . Meanwhile, in view of the indirect energy conversion mechanism of this nuclear battery, the phosphor layer is an intermediate energy transducer.…”

Section: Introductionmentioning

confidence: 99%

“…[10][11][12][13][14] According to previous research results, it was found that selecting the excellent performance materials, proper coupling between these materials, and optimizing the battery structure are required to achieve maximum nuclear-toelectrical conversion efficiency. 15,16 Meanwhile, in view of the indirect energy conversion mechanism of this nuclear battery, the phosphor layer is an intermediate energy transducer. On the one hand, the phosphor layer absorbs radiation particles bombarding, undergoes radiative excitation, and releases luminescent photons of a specific wavelength range.…”

Section: Introductionmentioning

confidence: 99%

Enhanced radioluminescent nuclear battery by optimizing structural design of the phosphor layer

Liu

Zhang

et al. 2018

Int J Energy Res

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Summary Radioluminescent nuclear battery is a type of energy conversion device that can be miniaturized, which has the ability to convert nuclear energy into light energy, and again into electrical energy. To explore the response relationship between the phosphor layer structure and the electrical performance of radioluminescent nuclear battery, the physical model was established to research the deposition energy distribution by using Monte Carlo method. The radioluminescence spectra and current‐voltage characteristic curves were used to investigate the optical and electrical properties. Through a comprehensive comparison of single plane layer, double plane layer, and V groove layer structures, the simulated results are consistent with experimental results. The results indicate that the Monte Carlo simulation is applicable to analysis of the phosphor layer structure of radioluminescent nuclear battery. Additionally, the results also show that the structure type and physical parameters of the phosphor layer have great influence on the energy deposition. A suitable phosphor layer structure can provide a new route to exhibit higher energy conversion efficiency as well as improving the matching degree between the range of radioactive particles and the thickness of the phosphor layer.

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Enhancement of energy performance in betavoltaic cells by optimizing self-absorption of beta particles

Cited by 11 publications

References 26 publications

Planar and textured surface optimization for a tritium‐based betavoltaic nuclear battery

Planar and textured surface optimization for a tritium‐based betavoltaic nuclear battery

Radioluminescent nuclear battery containing CsPbBr ₃ quantum dots: Application of a novel wave‐shifting agent

Enhanced radioluminescent nuclear battery by optimizing structural design of the phosphor layer

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Enhancement of energy performance in betavoltaic cells by optimizing self-absorption of beta particles

Cited by 11 publications

References 26 publications

Planar and textured surface optimization for a tritium‐based betavoltaic nuclear battery

Planar and textured surface optimization for a tritium‐based betavoltaic nuclear battery

Radioluminescent nuclear battery containing CsPbBr 3 quantum dots: Application of a novel wave‐shifting agent

Enhanced radioluminescent nuclear battery by optimizing structural design of the phosphor layer

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Radioluminescent nuclear battery containing CsPbBr ₃ quantum dots: Application of a novel wave‐shifting agent