Metal‐Organic Framework Templated Synthesis of Copper Azide as the Primary Explosive with Low Electrostatic Sensitivity and Excellent Initiation Ability

Wang, Qianyou; Feng, Xiao; Wang, Shan; Song, Ning; Chen, Yifa; Tong, Wenchao; Han, Young‐Kyu; Yang, Li; Wang, Bo

doi:10.1002/adma.201601371

Cited by 115 publications

(102 citation statements)

References 49 publications

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“…33 Their attractive properties include large surface area, tunable porosity, organic functionality, stable shelf-life and excellent thermal stability. 34–37 Incorporation of biomolecules into these hybrid materials to form MOF biocomposites has opened up novel prospects in the utilization of MOFs. 38 Progress in the synthesis and application of MOF biocomposites has been recently reviewed by Falcaro and co-authors.…”

mentioning

confidence: 99%

Ultrarobust Biochips with Metal–Organic Framework Coating for Point-of-Care Diagnosis

Wang

Tadepalli

et al. 2018

ACS Sens.

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Most biosensors relying on antibodies as recognition elements fail in harsh environment conditions such as elevated temperatures, organic solvents or proteases because of antibody denaturation, and require strict storage conditions with defined shelf-life, thus limiting their applications in point-of-care and resource-limited settings. Here, a metal-organic framework (MOF) encapsulation is utilized to preserve the biofunctionality of antibodies conjugated to nanotransducers. This study investigates several parameters of MOF coating (including growth time, surface morphology, thickness and precursor concentrations) that determine the preservation efficacy against different protein denaturing conditions in both dry and wet environments. A plasmonic biosensor based on gold nanorods as the nanotransducers is employed as a model biodiagnostic platform. The preservation efficacy attained through MOF encapsulation is compared to two other commonly employed materials (sucrose and silk fibroin). The results show that MOF coating outperforms sucrose and silk fibroin coatings under several harsh conditions including high temperature (80 °C), dimethylformamide and protease solution, owing to complete encapsulation, stability in wet environment and ease of removal at point-of-use by the MOF. We believe this study will broaden the applicability of this universal approach for preserving different types of on-chip biodiagnostic reagents and biosensors/bioassays, thus extending the benefits of advanced diagnostic technologies in resource-limited settings.

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confidence: 99%

Ultrarobust Biochips with Metal–Organic Framework Coating for Point-of-Care Diagnosis

Wang

Tadepalli

et al. 2018

ACS Sens.

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“…For a good catalytic performance of Co, pyrrolic or Co bonded N seems to be crucial . In addition, the Co contents of MOFs have been shown to promote the formation of highly graphitic frameworks even at low temperatures . The outstanding electrical conductivity of graphene can greatly promote the electron transfer, which enhances the electrochemical response towards the oxidation of dopamine .…”

Section: Resultsmentioning

confidence: 99%

Co/Co‐N@Nanoporous Carbon Derived from ZIF‐67: A Highly Sensitive and Selective Electrochemical Dopamine Sensor

et al. 2018

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Co/Co‐N nanoparticles incorporated nitrogen‐doped nanoporous carbon (Co/Co‐N@NPC) nanostructures were fabricated via pyrolysis of metal organic framework, ZIF‐67, under argon atmosphere. The ZIF‐67 derived Co/Co‐N@NPC modified carbon paste electrode exhibited excellent performance during electroanalysis of dopamine, displaying two linear ranges; 10 nM to 50 μM, and 50 μM–500 μM with sensitivity of 12.4±0.3 μA/μM/cm2 and11.69±0.06 μA/μM/cm2, respectively. The modified electrodes were observed to be highly selective towards dopamine even in presence of other interfering biomolecules such as ascorbic acid, glucose and uric acid. To the best of our knowledge, the sensing ability of Co/Co‐N@NPC with a lower limit of detection as 6 nM is the best compared to the previously reported cobalt mediated sensors for dopamine. Practical feasibility of the sensor was demonstrated in real sample analysis of dopamine measurement in human urine samples and dopamine hydrochloride injection samples.

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“…[6] Up to now,anumber of alternative candidates have been synthesized and can be generally classified into two species:m etal-free primary explosives and metal-organic primary explosives. [6] Up to now,anumber of alternative candidates have been synthesized and can be generally classified into two species:m etal-free primary explosives and metal-organic primary explosives.…”

Section: Introductionmentioning

confidence: 99%

Potassium Nitraminofurazan Derivatives: Potential Green Primary Explosives with High Energy and Comparable Low Friction Sensitivities

Shi

Huang

et al. 2017

Chemistry A European J

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Lead-based primary explosives were widely applied in military and civilian ammunition, which have subsequently caused serious environmental and health-related problems. Therefore, the development of green alternatives for the lead-based primary explosives has been one of the major focuses in the field of energetic materials. Four potassium salts based on nitraminofurazan have been easily synthesized and show excellent comprehensive performances. Among them, potassium 3-dinitromethyl-4-nitraminofurazan (K DNMNAF, 1) showed better thermal stability (T : 281.4 °C), higher density (2.174 g cm ), and lower friction sensitivities (72 N) than that of potassium 4,5-bis(dinitromethyl)furoxanate (K BDNMF, T : 218.3 °C, density: 2.130 g cm , FS: 5 N, P: 27.3 GPa, v : 7759 m s ); furthermore, it displayed comparable detonation performances (P: 27.2 GPa, v : 7758 m s ). The promising properties of these salts make this kind of material a competitive alternative to lead azide as a primary explosive.

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Metal‐Organic Framework Templated Synthesis of Copper Azide as the Primary Explosive with Low Electrostatic Sensitivity and Excellent Initiation Ability

Cited by 115 publications

References 49 publications

Ultrarobust Biochips with Metal–Organic Framework Coating for Point-of-Care Diagnosis

Ultrarobust Biochips with Metal–Organic Framework Coating for Point-of-Care Diagnosis

Co/Co‐N@Nanoporous Carbon Derived from ZIF‐67: A Highly Sensitive and Selective Electrochemical Dopamine Sensor

Potassium Nitraminofurazan Derivatives: Potential Green Primary Explosives with High Energy and Comparable Low Friction Sensitivities

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