Electrochemical Desalination of a 50% w/w Sodium Hydroxide Solution, a Pharmaceutical Sterilization Agent

Lee, Jae Hong; Yang, Ji-Hyun; Huh, Eugene; Park, Sewon; Koo, Bonmoo; Ahn, In Soo

doi:10.33961/jecst.2022.00472

“…However, their thermal conductivity coefficients ( λ ) are relatively low (~0.2 W/(m ⋅ K)). Although researchers commonly incorporate thermally conductive and electrically insulating fillers, such as boron nitride (BN), aluminum nitride (AlN), and silicon carbide (SiC), etc ., into polymers to fabricate thermally conductive and electrically insulating composites, [17–19] the value of λ of the reported thermally conductive and electrically insulating polymer composites are not particularly outstanding (with λ difficult to exceed 10 W/(m ⋅ K)) [20] . Silver nanowires (AgNWs), characterized by high λ (~420 W/(m ⋅ K)), large aspect ratios, and good chemical stability, [21,22] thus become ideal thermally conductive fillers for preparing high‐performance thermally conductive polymer composites [23,24] .…”

Section: Introductionmentioning

confidence: 99%

Highly Thermally Conductive Aramid Nanofiber Composite Films with Synchronous Visible/Infrared Camouflages and Information Encryption

Han,

Ruan,

He

et al. 2024

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The highly thermally conductive composites that combine visible light/infrared camouflage and information encryption has been endowed with great significance in facilitating the application of 5G communication technology in military fields. This work uses aramid nanofibers (ANF) as the matrix, hetero‐structured silver nanowires@boron nitride nanosheets (AgNWs@BNNS) prepared by in‐situ growth as fillers, which are combined to fabricate sandwich structured thermally conductive and electrically insulating (BNNS/ANF)‐(AgNWs@BNNS)‐(BNNS/ANF) (denoted as BAB) composite films by “filtration self‐assembly, air spraying, and hot‐pressing” method. When the mass ratio of AgNWs@BNNS to BNNS is 1:1 and the total mass fraction is 50 wt%, BAB composite film has the maximum in‐plane thermal conductivity coefficient (λ∥ of 10.36 W/(m·K)), excellent electrical insulation (breakdown strength and volume resistivity of 41.5 kV/mm and 1.21×1015 Ω·cm, respectively) and mechanical properties (tensile strength of 170.9 MPa). 50 wt% BAB composite film could efficiently reduce the equilibrium temperature of the central processing unit (CPU) working at full power, resulting in 7.0oC lower than that of the CPU solely integrated with ANF directly. In addition, BAB composite film boasts adaptive visible light/infrared dual camouflage properties on cement roads and jungle environments, as well as the function of fast encryption of QR code information within 24 seconds.

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“…[ 3 ] Perovskite is used as a photovoltaic material, which has the chemical structure of ABX 3 (A = monovalent cation, such as Cs + , CH 3 NH 3 + (MA + ), and CH(NH 2 ) 2 + (FA + ); B = divalent cation, such as Pb 2+ , Sn 2+ , Ge 2+ , Bi 3+ , and Sb 3+ ; X = halide anion, such as I ‐ , Br ‐ , and Cl ‐ ) and excellent optoelectronic properties, such as long carrier lifetime, long diffusion length, and high absorption coefficient, as well as the advantages of tunable bandgap, low cost, and ease of manufacturing. [ 4–12 ] In particular, the properties of perovskite absorbents can be easily controlled by changing the elemental composition of the precursor used. In other words, it is possible to control the bandgap of perovskites by simply changing the halide composition from I ‐ to Br ‐ .…”

Section: Introductionmentioning

confidence: 99%

“…According to the thermodynamically determined maximum efficiency limit, known as the Shockley‐Queissier (S‐Q) limit, it can be observed that the perovskite absorbers currently being studied with a bandgap of 1.5 to 1.6 eV have a low theoretical power conversion efficiency (PCE) limit of approximately 30–31%. [ 9 ] Moreover, the S‐Q limit of ideal perovskite single‐junction solar cells with a bandgap of 1.3 to 1.4 eV is limited to approximately 33%. Single‐junction solar cells also suffer from thermalization loss and the limited absorption of photons with energy below the bandgap ( E g ) due to the mismatch between the solar spectrum and mono‐energetic absorption, combined with the interaction between excited carriers and lattice phonons, leading to the cooling of carriers towards the bandgap edge.…”

Section: Introductionmentioning

confidence: 99%

Recent Advances in Wide Bandgap Perovskite Solar Cells: Focus on Lead‐Free Materials for Tandem Structures

Jang

¹

,

Jang

²

,

Kim

³

2023

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A tandem solar cell, which is composed of a wide bandgap (WBG) top sub‐cell and a narrow bandgap (NBG) bottom subcell, harnesses maximum photons in the wide spectral range, resulting in higher efficiency than single‐junction solar cells. WBG (>1.6 eV) perovskites are currently being studied a lot based on lead mixed‐halide perovskites, and the power conversion efficiency of lead mixed‐halide WBG perovskite solar cells (PSCs) reaches 21.1%. Despite the excellent device performance of lead WBG PSCs, their commercialization is hampered by their Pb toxicity and low stability. Hence, lead‐free, less toxic WBG perovskite absorbers are needed for constructing lead‐free perovskite tandem solar cells. In this review, various strategies for achieving high‐efficiency WBG lead‐free PSCs are discussed, drawing inspiration from prior research on WBG lead‐based PSCs. The existing issues of WBG perovskites such as VOC loss are discussed, and toxicity issues associated with lead‐based perovskites are also addressed. Subsequently, the natures of lead‐free WBG perovskites are reviewed, and recently emerged strategies to enhance device performance are proposed. Finally, their applications in lead‐free all perovskite tandem solar cells are introduced. This review presents helpful guidelines for eco‐friendly and high‐efficiency lead‐free all perovskite tandem solar cells.

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Highly Thermally Conductive Aramid Nanofiber Composite Films with Synchronous Visible/Infrared Camouflages and Information Encryption

Han,

Ruan,

He

et al. 2024

Angewandte Chemie

8

0

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The highly thermally conductive composites that combine visible light/infrared camouflage and information encryption has been endowed with great significance in facilitating the application of 5G communication technology in military fields. This work uses aramid nanofibers (ANF) as the matrix, hetero‐structured silver nanowires@boron nitride nanosheets (AgNWs@BNNS) prepared by in‐situ growth as fillers, which are combined to fabricate sandwich structured thermally conductive and electrically insulating (BNNS/ANF)‐(AgNWs@BNNS)‐(BNNS/ANF) (denoted as BAB) composite films by “filtration self‐assembly, air spraying, and hot‐pressing” method. When the mass ratio of AgNWs@BNNS to BNNS is 1:1 and the total mass fraction is 50 wt%, BAB composite film has the maximum in‐plane thermal conductivity coefficient (λ∥ of 10.36 W/(m·K)), excellent electrical insulation (breakdown strength and volume resistivity of 41.5 kV/mm and 1.21×1015 Ω·cm, respectively) and mechanical properties (tensile strength of 170.9 MPa). 50 wt% BAB composite film could efficiently reduce the equilibrium temperature of the central processing unit (CPU) working at full power, resulting in 7.0oC lower than that of the CPU solely integrated with ANF directly. In addition, BAB composite film boasts adaptive visible light/infrared dual camouflage properties on cement roads and jungle environments, as well as the function of fast encryption of QR code information within 24 seconds.

show abstract

Electrochemical Desalination of a 50% w/w Sodium Hydroxide Solution, a Pharmaceutical Sterilization Agent

Cited by 3 publications

References 23 publications

Highly Thermally Conductive Aramid Nanofiber Composite Films with Synchronous Visible/Infrared Camouflages and Information Encryption

Highly Thermally Conductive Aramid Nanofiber Composite Films with Synchronous Visible/Infrared Camouflages and Information Encryption

Recent Advances in Wide Bandgap Perovskite Solar Cells: Focus on Lead‐Free Materials for Tandem Structures

Highly Thermally Conductive Aramid Nanofiber Composite Films with Synchronous Visible/Infrared Camouflages and Information Encryption

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