The present invention relates in general to an explosive material, and in particular to a carbon nanotube plus solid oxidizer explosive material.
Explosive materials-and their use to destroy, move, and/or manipulate components, devices, etc. are known. Such explosive materials typically undergo an exothermic chemical reaction that produces heat and/or a large volume of gas. In addition, the chemical reaction occurs at a rapid rate such that a shockwave propagates from the chemical reaction.
The use of explosive materials is critical in a variety of areas such as military operations, espionage operations, counter-espionage operations, movement of desired devices, and the like. In addition, the ability to precisely control quantity of explosive and the amount of energy released can provide for more accurate, reliable, and controllable effects. Therefore, a micro-explosive device and/or material would be desirable.
A micro-explosive material is provided. The micro-explosive material can include a carbon nanotube and a solid oxidizer attached to or arranged in close proximity to the carbon nanotube. The carbon nanotube combined with the solid oxidizer is operable to bum per an exothermic chemical reaction between the carbon nanotube and the solid oxidizer such that a controlled bum and/or an explosive burn is provided.
The solid oxidizer can be a salt that is attached to or in close proximity to an outer surface or wall of a carbon nanotube, to an inner wall of a hollow carbon nanotube, or combinations thereof. In the alternative, the carbon nanotube with the solid oxidizer attached thereto can afford a micro-thruster, and the micro-thruster can be attached to a micro-device such as a micro-robot, a micro-satellite, a small-caliber ballistic, etc. In some instances, the carbon nanotube and the solid oxidizer can be a generator such as a heat generator, a gas generator, a shockwave generator, and the like. In other instances, the carbon nanotube and the solid oxidizer attached thereto can be a primer charge that is operable to ignite a separate and possibly a larger explosive material.
The micro-explosive material can also include a plurality of carbon nanotubes with a solid oxidizer attached thereto. The solid oxidizer can be attached to outer surfaces of the carbon nanotubes and/or attached to inner walls if the plurality of carbon nanotubes are hollow carbon nanotubes. It is appreciated that the plurality of carbon nanotubes and the solid oxidizer can also be used as a micro-thruster, a generator, a primer, and the like in order to afford movement of a micro-device and/or destruction of at least a portion of a micro-device.
A process for producing the micro-explosive material is also provided, the process including providing a carbon nanotube and a solid oxidizer. The solid oxidizer is attached to the carbon nanotube with the carbon nanotube plus solid oxidizer operable to exothermally chemically react with each other to provide a controlled and/or explosive burn.
The carbon nanotube and/or solid oxidizer can be provided by a micro-fabrication technique and, as such, the micro-explosive material can be well suited for manufacture using techniques known to those skilled in the art of semiconductor and semiconductor device production and/or fabrication. The micro-explosive material and the process for producing a micro-explosive material can further include an electronic and/or optical initiator mechanism that is used to ignite the chemical reaction between the carbon nanotube and the solid oxidizer.
The micro-explosive material disclosed herein has utility as a micro-thruster, a micro-generator, and/or a micro-explosive. The micro-explosive material can include a carbon nanotube and a solid oxidizer attached thereto. The carbon nanotube and the solid oxidizer, are selected to afford an exothermic chemical reaction and provide a controlled burn and/or an explosive burn. The solid, oxidizer can be a salt, a fluorocarbon, or any other type of oxidizer known in the art. and may be attached to an outer surface of the carbon nanotube and/or to an inner wall of the carbon nanotube in the event that the nanotube is a hollow carbon nanotube. The carbon nanotube with the solid oxidizer attached thereto can be used for and/or provide a micro-thruster that is attached to a micro-device such as a micro-robot, a micro-satellite, a small-caliber ballistic, etc. Furthermore, the carbon nanotube with the solid oxidizer attached thereto can be a micro-generator that generates heat, gas, a shockwave, etc.
The carbon nanotube with the solid oxidizer attached thereto can also be used as a primer charge that is operable to ignite a separate explosive material. It is appreciated that the separate explosive material can be a larger amount of explosive material.
In some instances, a plurality of carbon nanotubes with solid oxidizer attached thereto can be provided and used to provide a micro-thruster, a micro-generator, a primer charge, and the like.
A process for producing the micro-explosive material is also provided, the process including providing a carbon nanotube, a solid oxidizer and attaching the solid oxidizer to the carbon nanotube. An electronic initiator mechanism and/or an optical initiator mechanism can also be included for the purpose of igniting the micro-explosive material.
It is appreciated that the burning of the carbon nanotube is the result of an exothermic chemical reaction between the carbon of the nanotube and the oxygen contained within the solid oxidizer. The solid oxidizer can be in the form of a salt such as potassium nitrate (KNO3), sodium perchlorate (NaClO4), etc.; however, this is not required. Stated differently, any solid oxidizer that provides sufficient oxygen to react with a carbon nanotube and provides a self-propagating exothermic chemical reaction can be used.
The micro-explosive material can afford for a low or high explosion, a low explosion resulting from rapid burning of the carbon nanotube, and a high explosion resulting from detonation of the micro-explosive material. More particularly, the micro-explosive material can provide for deflagration, i.e. the decomposition of the micro-explosive material by propagation of a flame front. In the alternative, the micro-explosive material can result in detonation, i.e. the decomposition of the carbon nanotube and solid oxidizer by propagation of an explosive shockwave traversing the material. It is appreciated that the propagation of the flame front through the micro-explosive material is relatively slow compared to the propagation of the shockwave through the material via detonation. In addition, it is further appreciated that physical and/or chemical properties/characteristics of the carbon nanotubes and the solid oxidizer can be selected such that a desired burn rate, deflagration rate, detonation rate, and the like is provided.
Turning now to
Turning now to
In addition to the substrate 140 and integrated circuit 142, a plurality of nanotubes and solid oxidizer 150 with an initiator 144 can be included such that initiation of an exothermic chemical reaction of the plurality of carbon nanotubes with oxidizer 150 is afforded. In this manner, a relatively small area or volume of a micro-device can be burned, heated, melted, etc. with minimum impact to surrounding areas, as in applications such as microwelding or thermally initiated thin film batteries.
Looking at the plurality of carbon nanotubes with solid oxidizer 150 in greater detail,
For example and for illustrative purposes only, the carbon can react with a solid oxidizer according to the reaction:
2(KNO3)+S+3C→K2S+N2+3(CO2)
in which sulfur can be added to assist in a gunpowder-like reaction. It is appreciated that the sulfur can be present as a coating on the carbon nanotubes, as part of the initiation mechanism, as part of the solid oxidizer, as a vapor, and the like. In the alternative, a solid oxidizer that does not require the presence of sulfur, e.g. NaClO4, in order for a desired exothermic chemical reaction to occur can be used.
The micro-explosive material disclosed herein can have a plurality of uses, illustratively including the embodiments shown in
A process for producing the micro-explosive material is shown generally at reference numeral 30 in
The attachment or embedding of solid oxidizer can be accomplished in a number of ways, including but not limited to exposing the carbon nanotubes to a liquid solution of the oxidizer by dropcasting, soaking, spray-coating, etc, then allowing the solvent to sublimate or evaporate away; gas-phase-deposition via evaporation or sputtering of the oxidizer material onto the carbon nanotubes; and producing the oxidizer on the chip by reacting one or more chemicals with the substrate or each other.
In order to better explain an embodiment of the micro-explosive material and a process for providing the micro-explosive material, and yet not limit the scope of the invention in any way, an example is provided below.
Multiwalled carbon nanotubes were produced using a thermal chemical vapor deposition technique which exposed a mixture of ferrocene and xylene vapor to a patterned SiO2/Si substrate in a quartz tube furnace. The substrate within the quartz tube was held at 770° C. and the gas mixture was allowed to flow through the tube for times between 30 to 60 minutes. Before passing the ferrocene-xylene gas mixture through the quartz, argon gas at a pressure of approximately 100 mTorr was present to prevent the patterned SiO2/Si substrate surface from oxidizing. Then, and after the furnace was heated to the deposition temperature of 770° C., a solution of ferrocene (0.5 mg) in xylene (50 mL) was pre-vaporized at 180° C. and introduced into a quartz tube and allowed to flow over the substrate. It is appreciated that the pre-vaporized ferrocene/xylene mixture served as both a carbon source and a catalyst with the xylene providing the carbon atoms and iron from the ferrocene serving as the catalyst for multiwalled carbon nanotube growth.
After a desired exposure time had elapsed, the reaction terminated by stopping the flow of the ferrocene/xylene gas mixture flow while passing H2/Ar gas through the furnace tube to remove or blow away any residual hydrocarbon vapor. In this manner, the reaction time for the growth of the carbon nanotubes was well controlled.
The above-described process provided mats of carbon nanotubes which were then heated in air at 350° C. for 2 hours to remove any carbonaceous impurities. The air-oxidized samples were further purified by exposure to concentrated nitric acid (HNO3) for 24 hours in order to remove any catalytic impurities. It is appreciated that hydrophobic carbon nanotubes will change to hydrophilic material upon nitric acid treatment due to the attachment of —OH functional groups at defective sites.
The resulting nitric acid treated carbon nanotubes were then washed with de-ionized water several times and dried in vacuum at 500° C. for 4 hours. After washing and drying, the nitric acid treated carbon nanotubes were then exposed to a 1 M sodium perchlorate (NaClO4) solution at room temperature for 24 hours. This end product was then dried again in vacuum at 100° C. for 24 hours.
Various analyses were conducted on the as-prepared mats of carbon nanotubes, the nitric acid treated carbon nanotubes, and the final end product using techniques such as x-ray diffraction, scanning electron microscopy, Raman spectroscopy, Fourier transform infrared spectroscopy, and x-ray photoelectron spectroscopy. In addition, the results clearly demonstrated that sodium perchlorate was attached to the carbon nanotubes that had been exposed to the NaClO4 solution.
In order to investigate the thermal stability and heat flow properties of the carbon nanotube-sodium perchlorate samples, thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC) were performed thereon. In particular, samples weighing approximately 10 mg were heated in an air atmosphere from 30° C. to 1000° C. at a rate of 5° C./min and the weight of a given sample was recorded as a function of temperature.
Looking at
The foregoing description is illustrative of particular embodiments of the invention, but is not meant to be a limitation upon the practice thereof. The following claims, including all equivalents thereof, are intended to define the scope of the invention.
The invention described herein may be manufactured, used, and licensed by or for the United States Government.