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Detonation nanodiamond


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Detonation nanodiamond, TEM image

*Detonation nanodiamond* (DND), often also called ultradispersed diamond
(UDD), is diamond that originates from a detonation . When an explosive
mixture of TNT /RDX is detonated, diamond particles with a diameter of ca.
5 nm are formed.


trinitrotoluene (TNT) structure

	

hexogen (RDX) structure


Contents

[hide ]

* 1 Properties 
* 2 Alternative synthesis methods 
* 3 Applications 
* 4 Use in medicine 
* 5 References 
* 6 External links 


[edit ] Properties

The diamond yield after detonation crucially depends on the synthesis
condition and especially on the heat capacity of the cooling medium in the
detonation chamber (water, air, CO_2 , etc.). The higher the cooling
capacity, the larger the diamond yield, which can reach 90%. After the
synthesis, diamond is extracted from the soot using high-temperature
high-pressure (autoclave ) boiling in acid for a long period (ca. 1–2
days). The boiling removes most of the metal contamination, originating
from the chamber materials, and non-diamond carbon.

Various measurements, including X-ray diffraction ^[1] and high-resolution
transmission electron microscopy ^[2] revealed that the size of the
diamond grains in the soot is distributed around 5 nm. The grains are
unstable with respect to aggregation and spontaneously form
micrometre-sized clusters (see figure above). The adhesion is strong and
contacts between a few nano-grains can hold a micrometre-sized cluster
attached to a substrate.^[2]


Nanosized diamond has extremely large relative surface area. As a result,
its surface spontaneously attaches water and hydrocarbon molecules from
the ambient atmosphere.^[3] However, clean nanodiamond surface can be
obtained with appropriate handling.^[2]


The detonation nanodiamond grains mostly have diamond cubic lattice and
are structurally imperfect. The major defects are multiple twins , as
suggested by High-resolution transmission electron microscopy .^[2]
Despite the carbon source for the diamond synthesis - TNT/RDX explosive
mixture - being rich in nitrogen, concentration of paramagnetic nitrogen
inside diamond grains is below 1 part per million (ppm).^[1] Paramagnetic
nitrogen (neutral nitrogen atoms substituting carbon in the diamond
lattice) is the major form of nitrogen in diamond, and thus the nitrogen
content in DND is probably very low.


[edit ] Alternative synthesis methods

Diamond nanocrystals can also be synthesized from a suspension of graphite
in organic liquid at atmospheric pressure and room temperature using
ultrasonic cavitation. The yield is approximately 10%. The cost of
nanodiamonds produced by this method are estimated to be competitive with
the HPHT process. ^[4] ^[5]

An alternative synthesis technique is irradiation of graphite by
high-energy laser pulses. The structure and particle size of the obtained
diamond is rather similar to that obtained in explosion. In particular,
many particles exhibit multiple twinning.^[6]


[edit ] Applications

Commercial products based on nanodiamonds are available for the following
applications:

1. Lapping and polishing (e.g. Sufipol); 2. Additives to engine oils (e.g.
ADDO); 3. Dry lubricants for metal industry (Drawing of W-, Mo-, V-,
Rh-wires); 4. Reinforcing fillers for plastics and rubbers; 5. Additives
to galvanic electrolytes (e.g. DiamoSilb).


[edit ] Use in medicine

Prof. Dean Ho , Dr. Houjin Huang, and Dr. Erik Pierstorff at Northwestern
University, in collaboration with Dr. Eiji Osawa at The NanoCarbon
Research Institute in Japan, have demonstrated that nanomaterials can
shuttle chemotherapy drugs to cells without producing the negative effects
of today's delivery agents.

Clusters of the nanodiamonds surround the drugs ensuring that they remain
separated from healthy cells, preventing unnecessary damage; upon reaching
the intended targets, the drugs are released into the cancer cells. The
leftover diamonds, hundreds of thousands of which could fit into the eye
of a needle, do not induce inflammation in cells once they have done their
job.


[edit ] References

1. ^ ^/*a*/ ^/*b*/ "Structure and defects of detonation synthesis
nanodiamond" Diamond and Related Materials 9 (2000) 861

2. ^ ^/*a*/ ^/*b*/ ^/*c*/ ^/*d*/ "High-resolution electron microscopy of
detonation nanodiamond" Nanotechnology 19 (2008) 155705 3. *^ * "FTIR
study of the adsorption of water on ultradispersed diamond powder surface"
Appl. Surf. Sci 133 (1998) 231 4. *^ * "Experimental Corroboration of the
Synthesis of Diamond in the Cavitation Process" Doklady Physics 49(2004)
150 5. *^ * "Graphite-to-diamond transformation induced by ultrasonic
cavitation" Diamond and Related Materials 17 (2008) 931

6. *^ * "The formation of multiply twinning structure and
photoluminescence of well-dispersed nanodiamonds produced by pulsed-laser
irradiation" Diamond and Related Materials 17 (2008) 142