Rugged nanoparticle tracers for mass tracking in explosive events

Abstract: Abstract

“…[1][2][3] The authors have reported previously on the survivability of ruggedized particulate tracers during explosions. [4] Present results inform the survivability of silica-coated luminescent tracer particles in the environment as well as synthesis paths to control particle size while maintaining luminescent intensity. The ability to control particle size and emissive color, and to ensure the tracer's long-lasting endurance provides an elegant solution for tracking mass through harsh environments.…”

“…In previous work, shielding zinc sulfide (ZnS:Mn) quantum dots in 100-nm-thick silica shells lead to a two-to-three-fold increase in luminescent intensity post-explosion when compared to bare quantum dots. [4] As previously reported results have explored the ruggedization of silica-covered ZnS:Mn quantum-dot tracers, this work expands the scope to explore the environmental endurance of the ruggedized tracers.…”

“…3(a). In this comparison, 100-nmdiameter silica-covered particles around manganese-doped zinc sulfide quantum dots, which had been molecularly bonded to 485-nm-emitting commercial strontium aluminate in deionized water, [4] were compared over 2 years. Peaks associated with the inner quantum dots [20] were seen to be enhanced while the emission peak of the aluminate at 485 nm remained constant.…”

“…The quantum-dot synthesis followed a previously published method. [4] The synthesis method is briefly described as follows.…”

“…Moving from an organicbased tracer to a particulate such as inorganic quantum dots can increase the survivability of a tracer but still lead to large degradations as the environment directly attacks the particulates. [4] To increase a tracer's environmental endurance, a chemically inert, signal-transmissive layer can be added to protect the tracer from the hostile environment (i.e., serve as a shield). This layer of the tracer protects the inner signal-producing portion while allowing the signal to be received during sampling and debris analysis.…”

Luminescent silica microagglomerates, synthesis, and environmental testing

“…[1][2][3] The authors have reported previously on the survivability of ruggedized particulate tracers during explosions. [4] Present results inform the survivability of silica-coated luminescent tracer particles in the environment as well as synthesis paths to control particle size while maintaining luminescent intensity. The ability to control particle size and emissive color, and to ensure the tracer's long-lasting endurance provides an elegant solution for tracking mass through harsh environments.…”

“…In previous work, shielding zinc sulfide (ZnS:Mn) quantum dots in 100-nm-thick silica shells lead to a two-to-three-fold increase in luminescent intensity post-explosion when compared to bare quantum dots. [4] As previously reported results have explored the ruggedization of silica-covered ZnS:Mn quantum-dot tracers, this work expands the scope to explore the environmental endurance of the ruggedized tracers.…”

“…3(a). In this comparison, 100-nmdiameter silica-covered particles around manganese-doped zinc sulfide quantum dots, which had been molecularly bonded to 485-nm-emitting commercial strontium aluminate in deionized water, [4] were compared over 2 years. Peaks associated with the inner quantum dots [20] were seen to be enhanced while the emission peak of the aluminate at 485 nm remained constant.…”

“…The quantum-dot synthesis followed a previously published method. [4] The synthesis method is briefly described as follows.…”

“…Moving from an organicbased tracer to a particulate such as inorganic quantum dots can increase the survivability of a tracer but still lead to large degradations as the environment directly attacks the particulates. [4] To increase a tracer's environmental endurance, a chemically inert, signal-transmissive layer can be added to protect the tracer from the hostile environment (i.e., serve as a shield). This layer of the tracer protects the inner signal-producing portion while allowing the signal to be received during sampling and debris analysis.…”

Luminescent silica microagglomerates, synthesis, and environmental testing

Interpol review of the analysis and detection of explosives and explosives residues

Detection of SARS-COV-2 by functionally imprinted micelles