Bromination of high-pressure, high-temperature
(HPHT) nanodiamond
(ND) surfaces has not been explored and can open new avenues for increased
chemical reactivity and diamond lattice covalent bond formation. The
large bond dissociation energy of the diamond lattice–oxygen
bond is a challenge that prevents new bonds from forming, and most
researchers simply use oxygen-terminated NDs (alcohols and acids)
as reactive species. In this work, we transformed a tertiary-alcohol-rich
ND surface to an amine surface with ∼50% surface coverage and
was limited by the initial rate of bromination. We observed that alkyl
bromide moieties are highly labile on HPHT NDs and are metastable
as previously found using density functional theory. The strong leaving
group properties of the alkyl bromide intermediate were found to form
diamond–nitrogen bonds at room temperature and without catalysts.
This robust pathway to activate a chemically inert ND surface broadens
the modalities for surface termination, and the unique surface properties
of brominated and aminated NDs are impactful to researchers for chemically
tuning diamond for quantum sensing or biolabeling applications.
Bromination of high-pressure high-temperature (HPHT) nanodiamond (ND) surfaces has not been explored and can open new avenues for increased chemical reactivity and diamond lattice covalent bond formation. The large bond dissociation energy of the diamond lattice-oxygen bond is a challenge that prevents new bonds from forming and most researchers simply use oxygen-terminated ND (alcohols and acids) as a reactive species. In this work, we transformed a tertiary alcohol-rich ND surface to an amine surface with 50% surface coverage and was limited by the initial rate of bromination. We observed that alkyl-bromide moieties are highly labile on NDs and are metastable as previously found using density functional theory. The instability of the bromine terminated ND is explained by steric hindrance and poor surface energy stabilization. The strong leaving group properties of the alkyl-bromide intermediate were found to form diamond-nitrogen bonds at room temperature and without catalysts. The chemical lability of the brominated ND surface led to efficient amination with NH3•THF at 298 K, and a catalyst-free Sonogashira-type reaction with an alkyne-amine produced an 11-fold increase in amination rate. Overlapping spectroscopies under inert, temperature-dependent and open-air conditions provided unambiguous chemical assignments. Amine-terminated NDs and folic acid were conjugated using sulfo-NHS/EDC coupling reagents to form amide bonds, confirming that standard amine chemistry remains viable. This work supports that a robust pathway exists to activate a chemically inert diamond surface at room temperature, which broadens the pathways of bond formation when a reactive alkyl-bromide surface is prepared. The unique surface properties of brominated and aminated nanodiamond reported here are impactful to researchers who wish to chemically tune diamond for quantum sensing applications or as an electron source for chemical transformations.
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