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1 anodiamond, which leads to adsorption of the nanodiamond.
2 ens avenues for numerous new applications of nanodiamond.
3 s of individual nanodiamonds and clusters of nanodiamonds.
4 s regarding the nature and occurrence of the nanodiamonds.
5 rbon nanotubes, graphene, graphene oxide and nanodiamonds.
6 cal simulation of SiV energy levels in small nanodiamonds.
7 e environments are typically used to produce nanodiamonds.
8  non-diamond carbon and stabilization of the nanodiamonds.
9 sive route for the production of high-purity nanodiamonds.
10 al. reported discovery of markers, including nanodiamonds, aciniform soot, high-temperature melt-glas
11 niversal role of quantum nuclear dynamics in nanodiamond across the length scales.
12                          However, creating a nanodiamond aerogel matrix has remained an outstanding a
13                 Here we optically levitate a nanodiamond and demonstrate electron spin control of its
14 stry and phase transformations of individual nanodiamonds and clusters of nanodiamonds.
15 otubes, carbon nanohorns, carbon nanoonions, nanodiamonds and different graphene derivatives, which a
16                 Finally, by introducing both nanodiamonds and gold nanoparticles into a single human
17 , concentrating the membrane proteins on the nanodiamonds and separating out detergents, chaotropic a
18 spherules, (vi) glass-like carbon containing nanodiamonds, and (vii) fullerenes with ET helium, all o
19 t-related proxies, including microspherules, nanodiamonds, and iridium.
20 ine-containing polymer and the suspension of nanodiamond are continued until the desired number of na
21                          Here we report that nanodiamonds are absent or very depleted in fragile, car
22                                              Nanodiamonds are biocompatible, 4- to 5-nm carbon nanopa
23 uperior photostability and biocompatibility, nanodiamonds are considered one of the best choices due
24 tated since the proteins extracted on to the nanodiamonds are exposed on the surface of the nanoparti
25 ternative explanation is that all meteoritic nanodiamonds are indeed presolar, but that their abundan
26                                              Nanodiamonds are of interest as nontoxic substrates for
27                        The widespread use of nanodiamond as a biomedical platform for drug-delivery,
28 t ab initio calculations of the stability of nanodiamond as a function of surface hydrogen coverage a
29                            Using fluorescent nanodiamonds as fiducial markers, we define and achieve
30  fabricate an emerging class of freestanding nanodiamond-based hybrid nanostructures with external fu
31                  Here, the B- and N-co-doped nanodiamond (BND) was reported as an efficient and stabl
32 perpolarization, spins on the surface of the nanodiamond can be distinguished from those in the bulk
33                            Here we show that nanodiamonds can be stably formed in the gas phase at at
34 s, high-temperature minerals and melt glass, nanodiamonds, carbon spherules, aciniform carbon, platin
35 emblage of impact-related markers, including nanodiamonds, carbon spherules, and magnetic spherules w
36 ng of the centre-of-mass motion of a trapped nanodiamond cluster results in cooling of one degree of
37                                          The nanodiamond co-deposition can significantly alter the li
38 tion and elution of the membrane proteins on nanodiamonds, concentrating the membrane proteins on the
39 e study the behaviour of optically levitated nanodiamonds containing NV(-) centres at sub-atmospheric
40     These results suggest that NV centers in nanodiamonds could enable parallel optical detection of
41                        Using 5 nm detonation nanodiamond covalently linked to poly(allylamine) hydroc
42  the tryptic peptides prepared by on-surface nanodiamond digestion of an E. coli membrane fraction fo
43 ) in broth culture media by using detonation nanodiamonds (DNDs) as a platform to effectively capture
44                                     However, nanodiamonds do not form stable suspensions in aqueous b
45    Here, we show that single non-fluorescing nanodiamonds exhibit strong coherent anti-Stokes Raman s
46   Clusters of diamond-phase carbon, known as nanodiamonds, exhibit novel mechanical, optical and biol
47 stigates such interactions using fluorescent nanodiamonds (FNDs) coated with vaccinia envelope protei
48                                  Fluorescent nanodiamonds (FNDs) emit in the near-IR and do not photo
49 ilicon quantum dots (Si QDs) and fluorescent nanodiamonds (FNDs) show almost no photobleaching in a p
50                        The use of functional nanodiamonds (fNDs) to deliver CpG oligonucleotides (ODN
51           We illustrate the effectiveness of nanodiamonds for SDS removal in the preparation of membr
52 nfine it to create a favorable condition for nanodiamond formation from graphite.
53 n of the results is that some (perhaps most) nanodiamonds formed within the inner Solar System and ar
54 ution of extraterrestrial and of terrestrial nanodiamond found in ultradispersed and ultracrystalline
55                     However, in nitrogen the nanodiamonds graphitize below approximately 10 mB.
56 onds (O-NDs), but not on hydrogen terminated nanodiamonds (H-NDs).
57                   The structure of synthetic nanodiamond has been characterized by (13)C nuclear magn
58 ma created by transparent confinement layer, nanodiamond has been formed at laser intensity as low as
59                   So far, mainly fluorescent nanodiamonds have been utilized for cell imaging.
60                                              Nanodiamonds have excellent mechanical and optical prope
61 fortunately, previous reports of YD-boundary nanodiamonds have left many unanswered questions regardi
62    Graphene on hydrogen terminated monolayer nanodiamond heterostructures provides a new way to impro
63 ose applications where stable dispersions of nanodiamond in fuels, polymers or oils are required.
64                           We report abundant nanodiamonds in sediments dating to 12.9 +/- 0.1 thousan
65  we demonstrate three-dimensional control of nanodiamonds in solution with simultaneous readout of gr
66 These results may help explain the origin of nanodiamonds in the cosmos, and offer a simple and inexp
67 R to achieve background-free imaging of NV(-)nanodiamonds in the presence of interfering fluorophores
68  however, options for noninvasive imaging of nanodiamonds in vivo are severely limited.
69 contrast magnetic resonance imaging (MRI) of nanodiamonds in water at room temperature and ultra-low
70 s has been discredited except for reports of nanodiamonds (including the rare hexagonal polytype) in
71 opy and demonstrated for the first time that nanodiamond-induced alterations in both extra- and intra
72 ables the analysis of the number and size of nanodiamonds internalized in living cells in situ, which
73        Layer-by-layer deposition of PAAm and nanodiamond is also studied on planar Si/SiO(2) surfaces
74 nd are continued until the desired number of nanodiamond layers is formed around the microdiamond.
75       A nitrogen-vacancy (NV(-)) centre in a nanodiamond, levitated in high vacuum, has recently been
76                               Self-assembled nanodiamond-lipid hybrid particles (NDLPs) harness the p
77 odiamond: n-diamond, i-carbon, and hexagonal nanodiamond (lonsdaleite), in order of estimated relativ
78  the presence of shock-synthesized hexagonal nanodiamonds (lonsdaleite) in YDB sediments dating to ap
79 ectively functionalize this special class of nanodiamond materials opens new possibilities for surfac
80 he aerogel morphology and composition of the nanodiamond matrix.
81 k, carbon-rich, lacustrine layer, containing nanodiamonds, microspherules, and other unusual material
82 oduced during wildfires, suggests that these nanodiamonds might have formed after, rather than at the
83                                          The nanodiamond-modified electrolyte can lead to a stable cy
84                      Here the interaction of nanodiamond monolayers with human Neural Stem Cells (hNS
85 onstrate the presence of three allotropes of nanodiamond: n-diamond, i-carbon, and hexagonal nanodiam
86 e trapping at voltages as low as 0.45 V with nanodiamonds, nanobeads, and DNA from bulk solution with
87 rized into fullerenes, nanotubes, nanohorns, nanodiamonds, nanodots and graphene derivatives based on
88  nondiamond carbon in detonation-synthesized nanodiamond (ND) severely limits applications of this ex
89 m with photo-cross-linkable hydrogel (G) and nanodiamond (ND) technology to facilitate the targeted a
90 ) harness the potent interaction between the nanodiamond (ND)-surface and small molecules, while prov
91 odes and electrodes modified with a layer of nanodiamond (ND).
92                                              Nanodiamonds (ND) present a unique combination of desira
93                                              Nanodiamonds (NDs) are a unique class of carbon nanopart
94 Here we evaluate the potential of detonation nanodiamonds (NDs) as a delivery vehicle for BMP-2 and b
95                                              Nanodiamonds (NDs) have attracted considerable attention
96                               High levels of nanodiamonds (nds) have been used to support the transfo
97 a bottom-up approach to position fluorescent nanodiamonds (NDs) with nanometer precision on DNA origa
98 carbon electrodes were realized by combining nanodiamonds (NDs) with ta-C thin films coated on Ti-coa
99 he photoluminescence and the ESR contrast of nanodiamond NV centres, indicating potential application
100 lular attachment occurs on oxygen terminated nanodiamonds (O-NDs), but not on hydrogen terminated nan
101 ly modulate the intensity from NV centers in nanodiamonds of various diameters in complex materials s
102 ect of altering surface functionalisation of nanodiamonds on hNSC adhesion and proliferation has show
103  fluorescence of the octadecylamine-modified nanodiamond opens up new avenues for its use as a non-to
104 f performing noninvasive in vivo tracking of nanodiamond over indefinitely long periods of time.
105 pinal fluid (aCSF) using polyarginine-coated nanodiamonds (PA-coated NDs) as affinity sorbents.
106 le when graphene is used in combination with nanodiamond particles and diamondlike carbon (DLC).
107                                          The nanodiamond particles are predominantly between 2 and 5
108 a nonaromatic core-shell structural model of nanodiamond particles has been proposed.
109  linking of octadecylamine to the surface of nanodiamond particles.
110  of membrane proteins using surface-oxidized nanodiamond particles.
111 retations strongly suggest that the reported nanodiamond polymorphs are in fact twinned c-diamond.
112 n conditions attributed to h-, i-, m-, and n-nanodiamond polymorphs has resulted in their receiving m
113 impact--is the alleged occurrence of several nanodiamond polymorphs, including the proposed presence
114 tion with the excellent in vivo stability of nanodiamond, raises the possibility of performing noninv
115                                              Nanodiamonds recovered from meteorites, which originate
116 d lonsdaleite crystal structures, similar to nanodiamonds recovered from meteoritic residues.
117                                         This nanodiamond-rich layer is consistent with the Younger Dr
118 under ambient conditions using a single-spin nanodiamond sensor.
119                   Here the authors show that nanodiamonds serve as an electrolyte additive to co-depo
120                        If that is true, then nanodiamonds should be at least as abundant in comets, b
121 elationship between CARS signal strength and nanodiamond size is quantified.
122   The only previously known co-occurrence of nanodiamonds, soot, and extinction is the Cretaceous-Ter
123 ing that the intrinsic electron spins on the nanodiamond surface can be used to hyperpolarize adsorbe
124 polarization from paramagnetic impurities at nanodiamond surfaces to (1)H spins in the surrounding wa
125 indicate that lithium prefers to adsorb onto nanodiamond surfaces with a low diffusion energy barrier
126 cope (HRTEM) images of natural and synthetic nanodiamonds, that the diffraction features attributed t
127 emical, electronic and optical properties of nanodiamonds through surface doping, interior doping and
128 e patches at a sliding interface wrap around nanodiamonds to form nanoscrolls with reduced contact ar
129                    The relation of the cubic nanodiamonds to glass-like carbon, which is produced dur
130 dicate that excessive optical heating of the nanodiamonds under vacuum may make the method impractica
131                 Hydrophobic blue fluorescent nanodiamond was synthesized by covalent linking of octad
132 hermophilic Bacillus altitudinis immobilized nanodiamond was used as a new biosorbent.
133 gen-vacancy centres in diamond nanocrystals (nanodiamonds), we directly measure the local thermal env
134 xploiting the Brownian motion of a levitated nanodiamond, we extract its internal temperature (T(i))
135                                           No nanodiamonds were found in our study.
136 is then immersed in an aqueous suspension of nanodiamond, which leads to adsorption of the nanodiamon
137                                     Reacting nanodiamond with cBN at moderate pressures and high temp
138 p to 10 mm in longest dimension, by reacting nanodiamond with pre-synthesized cBN in a large-volume p
139 luorescence dynamics of single NV centers in nanodiamonds with different surface terminations can be
140 e absolute internal temperature of levitated nanodiamonds with ESR after calibration of the strain ef
141   Here we present a method for encapsulating nanodiamonds with silica using an innovative liposome-ba
142 all, consistent with the recent detection of nanodiamonds within the accretion discs of other young s
143                       Herein, we report that nanodiamonds work as an electrolyte additive to co-depos

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