Cold Compaction Behavior of Unsaturated Titanium Hydride Powders: Validation of Two Compaction Equations

Luo, Liu; Sun, Yuchu; Tang, Yongbai

doi:10.3390/met13020360

Cited by 4 publications

(1 citation statement)

References 27 publications

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“…Using this superposition, the behavior of the repaired photocatalyst is described very well. The similar fitting function has already proven successful in various applications including modelling biosensor response functions, molecule production rate, metallic powder compressibility or the reaction rate of substrate conversion, but this model has never been demonstrated for light‐driven catalysis applications [19,28–32] . In contrast to the asymmetric sigmoidal function, the limit value of the two‐phase exponential association function results from the superposition of the two parameters

{{c}_{1}}

and

{{c}_{3}}

, i. e .,

{\mathop{{\rm lim}}\limits_{t\to {\rm \infty }}f\left(t\right)={c}_{1}\ +\ {c}_{3}}

.…”

Section: Resultsmentioning

confidence: 99%

An Algebraic Blueprint for Predicting Turnover Numbers and Endpoints in Photocatalysis

Klingler,

Hlavatsch,

Bagemihl

et al. 2024

ChemPhysChem

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Photocatalysis is a contemporary research field given that the world’s fossil energy resources including coal, mineral oil and natural gas are finite. The vast variety of photocatalytic systems demands for standardized protocols facilitating an objective comparison. While there are commonly accepted performance indicators such as the turnover number (TON) that are usually reported, to date there is no unified concept for the determination of TONs and the endpoint of the reaction during continuous measurements. Herein, we propose an algebraic approach using defined parameters and boundary conditions based on partial least squares regression for generically calculating and predicting the turnover number and the endpoint of a photocatalytic experiment. Furthermore, the impact of the analysis period was evaluated with respect to the fidelity of the obtained TON, and the influence of the data point density along critical segments of the obtained fitting function is demonstrated.

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{{c}_{1}}

and

{{c}_{3}}

, i. e .,

{\mathop{{\rm lim}}\limits_{t\to {\rm \infty }}f\left(t\right)={c}_{1}\ +\ {c}_{3}}

.…”

Section: Resultsmentioning

confidence: 99%

An Algebraic Blueprint for Predicting Turnover Numbers and Endpoints in Photocatalysis

Klingler,

Hlavatsch,

Bagemihl

et al. 2024

ChemPhysChem

View full text Add to dashboard Cite

show abstract

Ultralow‐Temperature Sintering of Titanium Powder by Spark Plasma Sintering Under Cyclic Pressure

Manabe,

Suzuki,

Ninagawa

et al. 2024

Adv Eng Mater

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Spark plasma sintering (SPS) is a promising method for producing titanium components from powder but a limitation is that high sintering temperatures (>900 °C) are normally required to eliminate porosity. Herein, the SPS of commercially pure titanium powder is reported using both cyclic and constant uniaxial pressure and compare densification, microstructure, and mechanical behavior. The following parameters are varied: sintering temperature, TS, 400 to 900 °C; cyclic and constant pressures, 100 to 500 MPa; with and without an isothermal dwell of 60 min at TS. The mechanical behavior is determined by bend and tensile testing. It is demonstrated that the application of cyclic pressure (cyclic‐SPS) gives superior densification over the range of parameters investigated compared with a constant pressure. Bend testing reveals improved ductility after cyclic‐SPS compared with a constant pressure. The dwell at TS further improves mechanical properties, giving excellent tensile ductility and strength. Consequently, at the ultralow temperature of 500 °C, nearly fully dense, ductile, titanium is achieved. It is shown that cyclic pressure enhances the degree of powder compaction at room temperature, and mechanisms are proposed to rationalize the effect of cyclic‐SPS on enhancing the rates of densification and sintering as the temperature increases during processing.

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Analysis of densification mechanisms of feed pelleting

Sun,

Wang,

et al. 2023

Biosystems Engineering

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Cold Compaction Behavior of Unsaturated Titanium Hydride Powders: Validation of Two Compaction Equations

Cited by 4 publications

References 27 publications

An Algebraic Blueprint for Predicting Turnover Numbers and Endpoints in Photocatalysis

An Algebraic Blueprint for Predicting Turnover Numbers and Endpoints in Photocatalysis

Ultralow‐Temperature Sintering of Titanium Powder by Spark Plasma Sintering Under Cyclic Pressure

Analysis of densification mechanisms of feed pelleting

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