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- 1. Nature 210, 692 (1966) , “DISTRIBUTION OF SUBSTITUTIONAL NITROGEN DONORS IN SYNTHETIC DIAMONDS”, M. J. A. Smith, B. R. Angel, R. G. EmmonsConsiderable attention has been devoted to the study of nitrogen impurity in natural diamonds using the technique of electron spin resonance1-3. The spectrum obtained in due to the unpaired electron provided by the substitutional nitrogen atom and the main feature is a triplet at g = 2.0024 caused by interaction with the nitrogen nucleus which has a spin of unity. The distribution of nitrogen is variable and would seem to depend on the method by which the diamond was formed. (Read more)
- 2. Nature 194, 829 (1962) , “DIAMONDS CONTAINING CONTROLLABLE IMPURITY CONCENTRATIONS”, C. M. Huggins, P. CannonThe presence of cosiderable quantities of impurities in natural diamond has recently been confirmed1,2. This led Frank3 to remark that multiple techniques of examination must be used on such material. In view of the report of Yoneda4 concerning possible effects of nitrogen on the X-ray diffraction patterns of diamond, it seems worth-while to us to comment further on some of the results which we have gained by the deliberate introduction of a given impurity into laboratory-grown diamond. We shall limit ourselves to a qualitative examination of the electron spin resonance spectra of a few specimens, in the belief that the profundity of the effects suffices to establish that progress in this area is now limited by the composition variability of natural diamond. (Read more)
- 3. Nature 173, 439 (1954) , “PARAMAGNETIC RESONANCE IN NEUTRON-IRRADIATED DIAMOND AND SMOKY QUARITZ”, Dr. J. H. E. Griffiths, J. Owen, I. M. WardThe nature of lattice defects in neutron-irradiated diamond is a problem of current interest. These defects are known to cause changes in some of the physical properties1 and give rise to a paramagnetic absorption spectrum. We have measured this spectrum in the temperature-range 20º-290ºK., using wave-lengths of 1-2 and 3-1 cm. There are many closely spaced lines, of which two main types can be distinguished. (Read more)
- 4. Nature 198, 981 (1963) , “Electron Spin Resonance in Neutron-irradiated Diamond”, E. A. Faulkner, E. W. J. Mitchell, P. W. WhippeyRecent work has shown that the nature of the electron spin resonance spectrum observed in irradiated diamond depends on the type and amount of irradiation. Faulkner and Lomer used comparatively heavy doses of 2-MeV electrons (up to 8×1019 electron cm-3) and distinguished four systems, all of which show a g-value which is isotropic and equal to the free-spin value within 0-2 per cent: (a) asingle line of width about 5 gauss; (b) a system of 24 lines with symmentry axes near the <221> directions, and a D-value of 0-14 cm-1; (c) a system of 6 lines with symmentry axes along the <100> directions and a D-value of 0-14 cm-1; (d) a broad absorption with a half-power width of about 70 gauss, showing a complicated anisotropic structure. (Read more)
- 5. Nature 210, 1037 (1966) , “Electron Spin Resonance Spectra associated with Nitrogen in Diamonds”, H. J. Bower, M. C. R. SymonsMANY diamonds show an electron spin resonance spectrum which has been attributed to the presence of single nitrogen atoms substituted for carbon at a diamond lattice site. Smith etal.1 found four types of nitrogen donors, equally abundant and differing only in their hyperfine axes, these being the four C–N bond directions. They measured the hyperfine coupling constants for 14N(I=1), and for 13C(I = ½) in the nearest neighbour positions (denoted centre I). Loubser and du Preez2 found additional lines in the spectrum, which they attributed to interaction of the unpaired electron with carbon-13 at other lattice sites (centres II, III and IV). The hyperfine coupling constants are recorded in Table 1, together with the orbital populations. These populations were obtained using values of |ψ2s(0)|2 and
-3>2p calculated from self-consistent-field atomic wave functions derived by Mayers and by Roothaan and Clementi (see ref. 3). (We have omitted any correction for the δ+ charge on nitrogen and the δ- charge on carbon: this would increase the spin density on carbon at the expense of the nitrogen.) (Read more) - 6. phys. stat. sol. (a) 25, 541 (1974) , “Electron Paramagnetic Resonance in Diamond Implanted at Various Energies and Temperatures”, P. R. Brosious, Y. H. Lee, J. W. Corbett, L. J. ChengAmorphous carbon layer EPR measurements have been fitted to a model which predicts the critical fluences at which the layer forms for any temperature and ion species; it predicts the layer will not form during nitrogen ion implantation in diamond above 1031°K. A new anisotropic EPR spectrum labeled D-A4 is observed after hot-implantation (650°C) with nitrogen ions. It is thought to be a spin-one-center arising from a small D-tensor interaction with <111> symmetry. Hot implantation suppresses the formation of the amorphous layer and enhances creation of crystalline lattice defects. (Read more)
- 7. Phys. Rev. Lett. 2, 39 (1959) , “ELECTRON SPIN RESONANCE OF ACCEPTOR STATES IN DIAMOND”, W. V. Smith, I. L. Gelles, and P. P. SorokinPrevious work reporting electron spin resonance in diamond has been concerned exclusively with paramagnetic centers produced by irradiation with fast neutrons. Using standard resonance techniques we have recently detected at room temperature a family of weak, narrow resonance lines near g=2... (Read more)
- 8. Phys. Rev. Lett. 10, 220 (1963) , “ELECTRON PARAMAGNETIC RESONANCE INVESTIGATION OF THE VACANCY IN DIAMOND”, John A. Baldwin, Jr.Griffiths, Owen, and Ward reported that diamonds exposed to reactor neutrons developed an intense isotropic electron paramagnetic resonance (EPR) absorption lone whose g value was very close to that of the free electron. They found that a similar line was produced by 1-MeV electrons. The work herein... (Read more)
- 9. J. Opt. Soc. Am. B 10, 913 (1993) , “Raman-heterodyne-detected nonlinear susceptibility with an arbitrary radio-frequency field strength”, X. -F. He, P. T. H. Fisk, N. B. MansonRaman-heterodyne-detected complex nonlinear susceptibility has been measured and analyzed in detail with a radio-frequency field strength varying from weak to strong. The experiments were carried out on the nitrogen-vacancy color center in diamond involving both nuclear magnetic resonance and electron paramagnetic resonance transitions. The dispersive and the absorptive components of the nonlinear susceptibility are shown to have different saturation behaviors, and an anomalous-amplitude line shape arises where the dispersion component dominates in the response spectrum at high RF powers. The experimental results are found to be in good agreement with theoretical profiles, where no adjustable parameter is included in the calculation. (Read more)
- 10. J. Opt. Soc. Am. B 9, 768 (1992) , “Origin of persistent hole burning of N-V centers in diamond”, D. Redman, S. Brown, S. C. RandNew satellite features and antiholes in the persistent hole-burning spectrum of N–V centers in diamond, as well as their dependences on applied electric fields and frequency within the inhomogeneous absorption line, are reported. These results, together with reassignments of spin states of this center, permit an understanding of the origin of the satellite holes as well as of possible mechanisms for the persistent hole-burning phenomenon itself. In addition we report narrow optical interference fringes in heterodyne-detected spectra of persistent spectral holes in the N–V defect center in diamond and discuss a recent suggestion for high-resolution Ramsey-fringe hole-burning spectroscopy of solids based on phase-separated fields. (Read more)
- 11. Opt. Lett. 15, 1094 (1990) , “Raman heterodyne detected electron-nuclear-double-resonance measurements of the nitrogen-vacancy center in diamond”, N. B. Manson, X. -F. He, P. T. H. FiskWe report two new applications of the Raman heterodyne detection technique. Raman heterodyne detected electron-nuclear double resonance and a double rf resonance technique are used to obtain the hyperfine structure of the nitrogen-vacancy center in diamond. (Read more)
- 12. Opt. Lett. 15, 983 (1990) , “Raman heterodyne detection of electron paramagnetic resonance”, K. Holliday, X. -F. He, P. T. H. Fisk, N. B. MansonWe report the detection of an electron paramagnetic resonance signal using Raman heterodyne spectroscopy, a rf –optical double-resonance technique. The signals are associated with the nitrogen-vacancy center in diamond, which has a spin-triplet ground state. A three-line spectrum associated with the nitrogen hyperfine structure is observed for various magnetic field strengths and crystal orientations. (Read more)
- 13. phys. stat. sol. (a) 21, 677 (1974) , “EPR Measurements in Ion-Implanted Diamond”, P. R. Brosious, J. W. Corbett, J. C. BourgoinA new EPR spectrum, arising from defects in diamond created by boron, carbon, and nitrogen ion-implantation, is observed. The spectrum, lattice damage production, and annealing of damage are discussed and are ascribed to amorphous carbon. (Read more)
- 14. phys. stat. sol. (a) 50, 237 (1978) , “High-Temperature Ion Implantation in Diamond”, Y. H. Lee, P. R. Brosious, J. W. CorbettC+ and N+ implantation into type IIa diamond are performed at various temperatures (25 to 1000°C) and ion-induced damage is studied by EPR measurements at 1.2 to 300 K. Hot implantation at 1000°C results in a reduced spin density of “amorphous” carbon by an order of... (Read more)
- 15. phys. stat. sol. (a) 154, 219 (1996) , “Microstructure Evolution and Defect Incorporation in Highly Oriented and Textured CVD Diamond Films”, Y. von Kaenel, J. Stiegler, E. Blank, O. Chauvet, Ch. Hellwig, K. PlamannA series of highly oriented and textured microwave CVD diamond films, where only the deposition time was varied, was deposited on silicon wafers in order to follow the evolution of the microstructure and defect content with film thickness. SEM, XRD, Raman spectroscopy, luminescence measurements, and... (Read more)
- 16. phys. stat. sol. (a) 121, 63 (1990) , “Point Paramagnetic Defects in Diamond Irradiated by High-Energy Ions”, D. P. Erchak, R. B. Grelfand, N. M. Penina, V. F. Stelmakh, V. P. Tolstykh, A. G. Ulyashin, V. S. Varichenko, A. M. ZaitsevA series of highly oriented and textured microwave CVD diamond films, where only the deposition time was varied, was deposited on silicon wafers in order to follow the evolution of the microstructure and defect content with film thickness. SEM, XRD, Raman spectroscopy, luminescence measurements, and... (Read more)
- 17. phys. stat. sol. (a) 181, 5-10 (2000) , “ESR Study of Phosphorus Implanted Type IIa Diamond”, N. Casanova, E. Gheeraert, A. Deneuville, C. Uzan-Saguy, R. KalishCold Implantation and Rapid Annealing (CIRA) at 1050 °C of P in IIa diamond crystal, then further annealing at 1400 °C were performed. EPR signals were obtained in particular (i) around g = 2.003, from “dangling bond” defects whose total concentration increases with the dose and decreases... (Read more)
- 18. phys. stat. sol. (b) 245, 1298-1314 (2008) , “EPR identification of intrinsic defects in SiC”, J. Isoya, T. Umeda, N. Mizuochi, N. T. Son, E. Janzen, T. OhshimaThe structure determination of intrinsic defects in 4H-SiC, 6H-SiC, and 3C-SiC by means of EPR is based on measuring the angular dependence of the 29Si/13C hyperfine (HF) satellite lines, from which spin densities, sp-hybrid ratio, and p-orbital direction can be determined over... (Read more)Si SiC diamond| EPR Theory electron-irradiation thermal-meas./anneal-exp.| +1 -1 0(neutral) 1.0eV~ 13C 29Si C1h C3v Carbon Csi D2d EI5/6 HEI1 HEI9/10 P6/7 Silicon T1 Td Tv2a V1/2/3 Vc Vsi antisite dangling-bond mono(=1) motional-effect n-type p-type pair(=2) quartet semi-insulating spin-relaxation triplet vacancy .inp files: SiC/Baranov/Baranov_g.inp SiC/EI5_C1h/5.inp SiC/EI5_C3v/5.inp SiC/EI6_RT/6.inp SiC/HEI10/HEI10a.inp SiC/HEI10/HEI10b.inp SiC/HEI1_C1h/1.inp SiC/HEI9/HEI9a.inp SiC/HEI9/HEI9b.inp SiC/SI5_C1h/4.inp SiC/Ky2/Ky2.inp SiC/Tv2a/Main.INP SiC/Vsi-_II_4H/Main.INP SiC/Vsi-_II_6H/Main.INP SiC/Vsi-_I_4H/Main.INP SiC/Vsi-_I_6H/Main.INP | last update: Takahide Umeda
- 19. Phys. Rev. B 74, 161203(R) (2006) , “Room-temperature manipulation and decoherence of a single spin in diamond”, R. Hanson, O. Gywat, and D. D. AwschalomWe report on room-temperature coherent manipulation of the spin of a single nitrogen-vacancy center in diamond and a study of its coherence as a function of magnetic field. We use magnetic resonance to induce Rabi nutations and apply a Hahn spin echo to remove the effect of low-frequency dephasing.... (Read more)
- 20. J. Appl. Phys. 100, 124315 (2006) , “Magnetic resonance study of Ni nanoparticles in single-walled carbon nanotube bundles”, A. A. Konchits, F. V. Motsnyi, Yu. N. Petrov, S. P. Kolesnik, V. S. Yefanov, M. L. Terranova, E. Tamburri, S. Orlanducci, V. Sessa, and M. RossiWe present a detailed study of the electron magnetic resonance (EMR) properties of Ni nanoparticles (NPs) placed in the bundles of single-walled carbon nanotubes produced by arc discharge with Ni catalyst. The behavior of EMR signals has been investigated in the 10–300 K temperature range for... (Read more)
- 21. phys. stat. sol. (b) 215, 109 (1999) , “Zeeman Effect of Lyman Transitions: Electronic Raman Spectrum of Boron Acceptors in Diamond”, H. Kim, R. Vogelgesang, A. K. Ramdas, S. Rodriguez, M. Grimsditch, T. R. AnthonySubstitutional boron impurities in diamond exhibit characteristic Lyman transitions, originating in the lower 1s(p3/2): 8 ground state and terminating in its spin-orbit split 1s(p1/2): 7 counterpart. In addition to the Lyman spectrum observed in the... (Read more)
- 22. phys. stat. sol. (a) 172, 113 (1999) , “On Photocurrent (and EPR) Study of Defect Levels in CVD Diamond”, J. Rosa, M. Van??ek, M. Nesldek, L. M. StalsPhotocurrent spectroscopy is used for studying electronic defect states in the gap of optical-quality CVD diamond. The constant photocurrent method (CPM), allowing to measure the optical (photoionization) cross-section of defects, is applied on samples with a different surface treatment. The... (Read more)
- 23. phys. stat. sol. (a) 174, 137 (1999) , “Effect of Stress on Optical and ESR Lines in CVD Diamond”, K. Iakoubuvskii, A. Stesmans, G. J. Adriaenssens, R. Provoost, R. E. Silverans, V. RaikoCorrelation between the shape of Raman, photoluminescence (PL) and Electron Spin Resonance (ESR) signals in CVD diamond films was examined for both undoped and nitrogen-doped films. No correlation was observed between the shift of the diamond Raman line and its linewidth, even for the films produced... (Read more)
- 24. Phys. Rev. B 59, 12900 (1999) , “Electron-paramagnetic-resonance measurements on the divacancy defect center R4/W6 in diamond”, D. J. Twitchen, M. E. Newton, J. M. Baker, T. R. Anthony, W. F. BanholzerElectron-paramagnetic-resonance (EPR) studies in radiation damaged diamond enriched to 5% 13C have resulted in the identification of the nearest-neighbor divacancy center. It is the isotopic enrichment, and consequent observation of 13C hyperfine lines, that has permitted the... (Read more)
- 25. phys. stat. sol. (a) 186, 167-176 (2001) , “What We Have Learned about Intrinsic Defects in Silicon: A Help in Understanding Diamond?”, G. D. WatkinsWhat we have established by electron paramagnetic resonance (EPR) studies in silicon concerning the properties of its intrinsic defects (vacancies and interstitials) and their interactions with other defects is reviewed. The lessons learned are compared to what is currently being observed in... (Read more)
- 26. phys. stat. sol. (a) 186, 199-206 (2001) , “Characterization of Defects in as-Grown CVD Diamond Films and HPHT Diamond Powders by Electron Paramagnetic Resonance”, K. Iakoubovskii, A. StesmansSeveral defect centers, labeled as KUL1-7, have been detected by electron paramagnetic resonance in CVD diamond films and synthetic diamond powders. Their g values were determined relatively to the P1 (NS0) center, for which the value of g = 2.00216(1) with... (Read more)
- 27. phys. stat. sol. (a) 186, 215-220 (2001) , “First Principles Study of the Self-Interstitial Defect in Diamond”, J. P. Goss, R. Jones, T. D. Shaw, M. J. Rayson, P. R. BriddonFirst principles techniques have been employed to examine the isolated self-interstitial in diamond. The assignment of the R2 EPR center to the self-interstitial has been questioned because of the small fine structure term. We have calculated the spin-spin interaction tensor, which resolves the... (Read more)
- 28. phys. stat. sol. (a) 181, 83-90 (2000) , “Relative Abundance of Single and Vacancy-Bonded Substitutional Nitrogen in CVD Diamond”, I. I. Vlasov, V. G. Ralchenko, A. V. Khomich, S. V. Nistor, D. Shoemaker, R. A. KhmelnitskiiRelations between the concentrations of neutral (N0) and charged (N+) single-substitutional nitrogen and of nitrogen-vacancy (N-V) complexes in chemical vapour deposited diamond films of 0.2 mm thickness with nitrogen impurity concentration levels of 10 ppm are studied. For... (Read more)
- 29. phys. stat. sol. (b) 217, 665-684 (2000) , “Paramagnetic Defects”, U. Gerstmann, M. Amkreutz, H. OverhofAb-initio calculations of paramagnetic hyperfine interactions for deep defects in semiconductors provide information about the magnetization density distribution in space. A comparison of theoretical results with corresponding data from magnetic resonance experiments allows to estimate the accuracy... (Read more)
- 30. Phys. Rev. Lett. 92, 135502 (2004) , “Hydrogen Incorporation in Diamond: The Vacancy-Hydrogen Complex”, C. Glover, M. E. Newton, P. M. Martineau, S. Quinn, D. J. TwitchenWe report the identification of the vacancy-hydrogen complex in single crystal diamond synthesized by chemical vapor deposition. The S = 1 defect is observed by electron paramagnetic resonance in the negative charge state. The hydrogen atom is bonded to one of the carbon atoms neighboring the... (Read more)
- 31. Phys. Rev. Lett. 90, 185507 (2003) , “Hydrogen Incorporation in Diamond: The Nitrogen-Vacancy-Hydrogen Complex”, C. Glover, M. E. Newton, P. Martineau, D. J. Twitchen, J. M. BakerWe report the identification of the nitrogen-vacancy-hydrogen complex in a freestanding nitrogen-doped isotopically engineered single crystal diamond synthesized by chemical vapor deposition. The hydrogen atom is located in the vacancy of a nearest-neighbor nitrogen-vacancy defect and appears to be... (Read more)
- 32. Physica B 376-377, 358-361 (2006) , “Pulsed EPR studies of Phosphorus shallow donors in diamond and SiC”, J. Isoya, M. Katagiri, T. Umeda, S. Koizumi, H. Kanda, N. T. Son, A. Henry, A. Gali, E. JanznPhosphorus shallow donors having the symmetry lower than Td are studied by pulsed EPR. In diamond:P and 3C–SiC:P, the symmetry is lowered to D2d and the density of the donor wave function on the phosphorus atom exhibits a predominant p-character. In 4H–SiC:P with the site symmetry of... (Read more)
- 33. Phys. Rev. Lett. 97, 137206 (2006) , “Electron Spin Resonance of Proton-Irradiated Graphite”, Kyu Won Lee and Cheol Eui LeeIn the case of colossal magnetoresistance in the perovskite manganites, "double exchange" mediated by the itinerant spins is believed to play a key role in the ferromagnetism. In contrast, the conventional "Heisenberg" interaction, i.e., direct (unmediated) interaction between... (Read more)
- 34. Appl. Phys. Lett. 88, 091912 (2006) , “Hydrogen-vacancy related defect in chemical vapor deposition homoepitaxial diamond films studied by electron paramagnetic resonance and cathodoluminescence”, N. Mizuochi, H. Watanabe, H. Okushi, S. Yamasaki, J. Niitsuma, T. SekiguchiHydrogen-vacancy related defect (H1) in chemical vapor deposition homoepitaxial diamond films has been investigated by electron paramagnetic resonance and cathodoluminescence. It is found that the concentration of H1 significantly decreases as the dilution... (Read more)
- 35. Solid State Commun. 9, 313 (1971) , “ELECTRON SPIN RESONANCE OF SPIN S = 1 STATES IN UNIRRADIATED DIAMONDS”, Thomas SzendreiThree types of paramagnetic centres with effective spin S = 1 have been detected in natural unirradiated type Ib diamonds. The values of the zero field spitting are 200 oe, 220 oe and 246 oe. (Read more)
- 36. J. Phys.: Condens. Matter 10, 9833 (1998) , “Optically detected electron paramagnetic resonance of Ni-related defects in synthetic diamond crystals”, Th. Pawlik, C. Noble, J. -M. SpaethSynthetic diamond crystals grown using a solvent catalyst that contains Ni were studied by optical detection of electron paramagnetic resonance (ODEPR) using the magnetic circular dichroism of the optical absorption (MCDA). The MCDA spectra in the infrared spectral region consist of a... (Read more)
- 37. Phys. Rev. 115, 1546 (1959) , “Electron-Spin Resonance of Nitrogen Donors in Diamond”, W. V. Smith, P. P. Sorokin, I. L. Gelles, and G. J. LasherElectron-spin resonance of bound substitutional nitrogen donors in diamond is observed and discussed. The g factor is isotropic at 2.00240.0005. For a given donor, one of the C-N bond directions is a hyperfine axis with constants A=40.8 oersteds, B=29.2 oersteds. There are thus four types of... (Read more)
- 38. Phys. Rev. B 42, 9843 (1990) , “EPR studies of interstitial Ni centers in synthetic diamond crystals”, J. Isoya, H. Kanda, Y. UchidaTwo new electron-paramagnetic-resonance (EPR) spectra, tentatively labeled NIRIM-1 and NIRIM-2, have been studied using synthetic diamond crystals grown from the Ni solvent to which various amounts of nitrogen getters (Ti, Zr) and/or boron were added. The NIRIM-1 spectrum (g=2.0112) having the... (Read more)diamond| EPR| NIRIM1 NIRIM2 .inp files: diamond/NIRIM1 diamond/NIRIM2 | last update: Masatoshi Sasaki
- 39. J. Phys.: Condens. Matter 10, 11781 (1998) , “Electron paramagnetic resonance investigations of nickel defects in natural diamonds”, C. J. Noble, Th. Pawlik, J. -M. SpaethElectron paramagnetic resonance (EPR) and electron nuclear double resonance (ENDOR) spectra of natural blue diamonds from the Argyle mine in Western Australia are reported for the first time. These diamonds are shown to contain the NE2 centre which has been observed primarily in synthetic diamonds... (Read more)
- 40. J. Appl. Phys. 38, 337 (1967) , “Electron Spin Resonance in Semiconducting Diamonds”, M. D. BellElectron spin resonance (ESR) was studied in five semiconducting diamonds in the temperature range 108°370°K and at 4.2°K. The g factor is 2.0030±0.0003, and the linewidth varies from 0.3 to 8 Oe at room temperature. The number of spins contributing to the ESR... (Read more)
- 41. Phys. Rev. B 54, 7881 (1996) , “Hydrogen-related defects in polycrystalline CVD diamond”, X. Zhou, G. D. Watkins, K. M. McNamara Rutledge, R. P. Messmer, S. ChawlaBy simulating the line shapes of a commonly observed S=1/2 electron paramagnetic resonance (EPR) center in polycrystalline chemical vapor deposited (CVD) diamond at 9.8, 14, 20, and 35 GHz, we conclude that the EPR signal, which we label H1, results from a unique defect with a single hydrogen atom... (Read more)
- 42. Physica B 273-274, 651 (1999) , “New paramagnetic defects in synthetic diamonds grown using nickel catalyst”, A. J. Neves, R. Pereira, N. A. Sobolev, M. H. Nazaré, W. Gehlhoff, A. Näser and H. KandaWe report four new EPR spectra found in high-pressure synthetic diamonds with high nitrogen content, grown using nickel, and annealed at 1600°C. Analyzing the complex spectra around g≈2 two trigonal and two orthorhombic defects, all with , were identified from the angular dependence and... (Read more)diamond| EPR| AB1 AB2 AB3 AB4 .inp files: diamond/AB1 diamond/AB2 diamond/AB3 diamond/AB4 | last update: Masatoshi Sasaki
- 43. Diamond Relat. Mater. 10, 480-484 (2001) , “EPR study of preferential orientation of crystallites in N-doped high quality CVD diamond”, S. Nokhrin, J. Rosa, M. Vanecek, A. G. Badalyan and M. NesladekThe directions of preferential growth of free-standing optical-quality CVD diamond wafers have been investigated with the help of electron paramagnetic resonance (EPR). EPR signals of the well-known P1 centre (substitutional nitrogen) have been used as a probe. A computer simulation of EPR spectra... (Read more)
- 44. Diamond Relat. Mater. 10, 1681-1683 (2001) , “EPR and optical imaging of the growth-sector dependence of radiation-damage defect production in synthetic diamond”, G. A. Watt, M. E. Newton and J. M. BakerEPR imaging data are presented for the distribution of single substitutional nitrogen (P1) in a synthetic diamond of mixed IIa/Ib character, and compared with the distribution of the di-001-split interstitial (R1) produced during an electron irradiation. Since the defects are localised in different... (Read more)
- 45. Diamond Relat. Mater. 10, 580-584 (2001) , “Phosphorus site after CIRA implantation of type IIa diamond”, N. Casanova, E. Gheeraert, A. Deneuville, C. Uzan-Saguy and R. KalishA set of type IIa diamond crystals was processed by cold implantation and rapid annealing at 1050°C ex situ annealing at 1400°C and investigated by ESR measurement. The ESR spectra of CIRA and post-annealed samples show an isotropic line at g=2.003, a set of anisotropic hyperfine lines,... (Read more)
- 46. Diamond Relat. Mater. 10, 434-438 (2001) , “Interstitial aggregates in diamond”, J. P. Goss, B. J. Coomer, R. Jones, T. D. Shaw, P. R. Briddon and S. ÖbergTheoretical modelling of magnetic resonance signals lead to convincing models for the first three self-interstitial aggregates in diamond. These in turn suggest the manner in which larger more stable aggregates including the platelet, observed in annealed type I diamonds, are formed. (Read more)
- 47. Sov. Phys. Solid State 10, 1789 (1969) , “THE STATE OF NITROGEN IMPURITIES IN SYNTHETIC DIAMONDS”, E. V. Sobolev, Yu. A. Litvin, N. D. Samsonenko, V. E. Ilin, S. V. Lenskaya, V. P. Butuzov
- 48. Sov. Phys. Solid State 11, 1104 (1969) , “ELECTRON PARAMAGNETIC RESONANCE OF IONIZED NITROGEN PAIRS IN DIAMOND”, M. Ya. Shcherbakova, E. V. Sobolev, N. D. Samsonenko, V. K. Aksenov
- 49. Sov. Phys. Solid State 6, 2460 (1965) , “DISTRIBUTION OF PARAMAGNETIC NITROGEN CENTERS IN SOME TYPE-I DIAMONDS”, N. D. Samsonenko
- 50. Sov. Phys. Solid State 8, 1842 (1967) , “REORIENTATION OF THE JAHN-TELLER DISTORTION IN NITROGEN IMPURITY CENTERS IN DIAMOND”, L. A. Shulman, I. M. Zaritskii, G. A. Podzyarei
- 51. Sov. Phys. Solid State 9, 1545 (1968) , “EXCHANGE PAIRS OF NITROGEN IMPURITIES IN DIAMOND”, L. A. Shulman, I. M. Zaritskii, K. A. Tikhonenko
- 52. Sov. Phys. Solid State 12, 2303 (1971) , “EFFECT OF THE SPIN-SPIN RESERVOIR ON SATURATION OF THE NITROGEN EPR LINE IN DIAMOND”, L. A. Shulman, A. B. Brik, T. A. Nachalnaya, G. A. Podzyarei
- 53. Sov. Phys. Solid State 13, 281 (1971) , “ELECTRON PARAMAGNETIC RESONANCE OF NITROGEN-ALUMINUM PAIRS IN DIAMOND”, M. Ya. Shcherbakova, E. V. Soboleva, N. D. Samsonenko, V. A. Nadolinnyi, P. V. Schastnev, A. G. Semenov
- 54. Sov. Phys. Solid State 13, 1809 (1972) , “DEFECTS IN SYNTHETIC DIAMOND POWDERS AND THE DYNAMIC JAHN-TELLER EFFECT”, Yu. A. Bratashevskii, F. N. Bukhanko, N. D. Samsonenko, O. Z. Shapiro
- 55. Sov. Phys. Solid State 14, 1521 (1972) , “EXCHANGE BROADENING OF THE HYPERFINE COMPONENTS OF THE ESR SPECTRUM OF NITROGEN IN DIAMOND”, L. A. Shulman, G. A. Podzyarei
- 56. Sov. Phys. Solid State 16, 1377 (1975) , “Cross relaxation in ESR spectra of synthetic diamonds”, L. A. Shulman, G. A. Podzyarei
- 57. Sov. Phys. Solid State 16, 2118 (1975) , “Electron paramagnetic resonance spectrum and the infrared absorption of diamonds doped with nitrogen isotopes”, Yu. A. Klyuev, V. I. Nepsha, A. M. Naletov
- 58. Sov. Phys. Solid State 17, 991 (1975) , “Electron spin resonance of Co2+ ions in synthetic diamonds”, V. S. Bagdasaryan, . A. Markosyan, M. A. Matosyan, O. S. Torosyan, E. G. Sharoyan
- 59. Sov. Phys. Solid State 18, 1883 (1976) , “Spin-lattice relaxation of a Jahn-Teller nitrogen center in diamond”, I. M. Zaritskii, V. Ya. Bratus, V. S. Vikhnin, A. S. Vishnevskii, A. A. Konchits, V. M. Ustintsev
- 60. Sov. Phys. Solid State 20, 178 (1978) , “Influence of temperature on spin-spin interaction of nitrogen and nickel centers in diamond”, V. K. Bezobchuk, A. B. Brik, I. V. Matyash, Yu. V. Fedotov
- 61. Nucl. Instrum. Methods Phys. Res. B 127-128, 217 (1997) , “Defects in ion implanted diamond films (ESR study)”, Yoshiyuki Show, Tomio Izumi, Masahiro Deguchi, Makoto Kitabatake, Takashi Hirao, Yusuke Morid, Akimitsu Hatta, Toshimichi Ito and Akio HirakiThe defect structures in ion implanted diamond films have been studied by the electron spin resonance (ESR) method. Two kinds of paramagnetic defect centers were observed in ion implanted layers. One was a carbon dangling bond that existed in crystalline diamond (g = 2.003, ΔHpp = 3 Oe), and... (Read more)
- 62. Diamond Relat. Mater. 9, 424-427 (2000) , “Experimental and theoretical studies of cobalt defects in diamond”, Karl Johnston, Alison Mainwood, Alan T. Collins, Gordon Davies, Daniel Twitchen, Mark Newton and J. M. BakerDiamonds grown with a cobalt/iron solvent catalyst and annealed at 1800°C were cut and polished along the main symmetry directions. The photoluminescence spectrum showed at least four zero phonon lines. One line at 2.367 eV splits and shifts under uniaxial stress indicating that it originates... (Read more)
- 63. Diamond Relat. Mater. 9, 417-423 (2000) , “Spectroscopy of defects and transition metals in diamond”, A. T. CollinsThis article reviews the optical and electron paramagnetic resonance (EPR) studies that have been carried out on diamonds containing nickel-related or cobalt-related defect centres. It is shown that this work is now at a stage where a real understanding may be reached about the nature of the defects... (Read more)
- 64. Diamond Relat. Mater. 9, 337-340 (2000) , “Structural changes in CVD diamond film by boron and nitrogen doping”, Yoshiyuki Show, Toshikazu Matsukawa, Hirokazu Ito, Mitsuo Iwase and Tomio IzumiThe effect of impurity atoms in the defect structures of a diamond film has been studied by electron spin resonance (ESR). It has been observed that introducing boron atoms into the diamond film during chemical vapor deposition (CVD) reduces paramagnetic defects (Pdia and Pac centers) by decreasing... (Read more)
- 65. Diamond Relat. Mater. 9, 1057-1060 (2000) , “New paramagnetic centers in annealed high-pressure synthetic diamond”, A. J. Neves, R. Pereira, N. A. Sobolev, M. H. Nazaré, W. Gehlhoff, A. Näser and H. KandaWe report three new paramagnetic centers found in high-pressure synthetic diamond with high nitrogen and nickel content and annealed at 1600°C. Analysis of the spectra has shown that two of the centers, labeled AB1 and AB2, are related to systems with effective spin S=1/2 and the other is... (Read more)
- 66. Diamond Relat. Mater. 9, 883-886 (2000) , “Mechanisms of nitrogen aggregation in nickel- and cobalt-containing synthetic diamonds”, V. A. Nadolinny, A. P. Yelisseyev, J. M. Baker, D. J. Twitchen, M. E. Newton, B. N. Feigelson and O. P. YuryevaWe present a study of the point defects observed in as-grown and annealed synthetic diamonds using electron paramagnetic resonance (EPR) and infrared spectroscopy. The diamonds were grown by the temperature gradient HPHT method in a split sphere apparatus using Fe–Ni–C or... (Read more)
- 67. Phys. Rev. B 61, 3863-3876 (2000) , “Identification of the neutral carbon ?100?-split interstitial in diamond”, D. C. Hunt, D. J. Twitchen, M. E. Newton, J. M. Baker, T. R. Anthony, W. F. Banholzer, S. S. VagaraliA systematic study has been made of some of the properties of R2, the most dominant paramagnetic defect produced in type-IIa diamond by electron irradiation. R2 has been produced in high-purity synthetic diamonds, which have been irradiated with 2 MeV electrons in a specially developed dewar,... (Read more)
- 68. Phys. Rev. B 62, 6587-6597 (2000) , “EPR data on the self-interstitial complex O3 in diamond”, D. C. Hunt, D. J. Twitchen, M. E. Newton, J. M. Baker, J. K. Kirui, J. A. van Wyk, T. R. Anthony, W. F. BanholzerA previously unreported defect, which is labeled O3, has been observed in the EPR spectrum of synthetic type-IIa diamonds irradiated at 100 K with 2 MeV electrons. This defect was not observed in identical diamonds whose temperature during electron irradiation was ?300 K. This center has also been... (Read more)
- 69. Phys. Rev. B 62, 16587-16594 (2000) , “ESR and optical evidence for a Ni vacancy center in CVD diamond”, K. Iakoubovskii, A. Stesmans, B. Nouwen, and G. J. AdriaenssensCharacterization of a series of correlated electron-spin resonance (ESR) and photoluminescence (PL) lines in diamond grown by chemical vapor deposition is reported. The series consists of a set of structured PL bands in the range 1.82.3 eV, and ESR lines due to an S=1 center with g=2.0039(1) and... (Read more)
- 70. Phys. Rev. B 62, 8038-8052 (2000) , “Zeeman effect of electronic Raman lines of acceptors in elemental semiconductors: Boron in blue diamond”, H. Kim, Z. Barticevic, A. K. Ramdas, S. Rodriguez, M. Grimsditch, T. R. AnthonyThe Zeeman effect of the electronic Raman transition from 1s(p3/2):?8 to the 1s(p1/2):?7 spin-orbit partner (??) of boron acceptors in diamond is studied with magnetic field B along [001], [111], or [110]. As many as eight Zeeman components of... (Read more)
- 71. J. Chem. Phys. 113, 744-750 (2000) , “Dynamic nuclear polarization of diamond. III. Paramagnetic electron relaxation times from enhanced 13C nuclear magnetic resonance signals”, Eduard C. Reynhardt and Grant L. HighIt is shown that by varying pulse lengths and delay times in electron spin resonance microwave pulse sequences, designed to enhance 13C nuclear magnetic resonance signals in diamond, and measuring the resulting 13C nuclear magnetic resonance signal, the paramagnetic impurity... (Read more)
- 72. J. Phys.: Condens. Matter 12, 7807-7817 (2000) , “Electron spin resonance characterization of a divacancy-related centre in CVD diamond”, A. Stesmans, B. Nouwen, K. IakoubovskiiThe electron spin resonance characterization of an undocumented paramagnetic centre in chemical vapour deposited diamond is reported. Successful fitting of the powder pattern-like spectrum characterized the originating defect as an S = 1 centre of spectroscopic splitting factor g =... (Read more)
- 73. Phys. Rev. B 61, 9-11 (2000) , “Identification of cobalt on a lattice site in diamond”, D. J. Twitchen, J. M. Baker, and M. E. NewtonWe report the finding of an electron-paramagnetic-resonance (EPR) center, labeled O4, which contains cobalt on a site in the diamond lattice. O4 is observed at low temperatures (<30?K) in high temperature and pressure synthetic diamonds grown with a cobalt containing metal-solvent catalyst after... (Read more)
- 74. Chem. Phys. Lett. 322, 273-279 (2000) , “Room-temperature field dependence of the electron spin–lattice relaxation times of paramagnetic P1 and P2 centers in diamond”, Cornelis J. Terblanche and Eduard C. ReynhardtElectron spin–lattice relaxation (SLR) times of P1 and P2 centers have been measured at 300 K at X-band and W-band for one synthetic (type-Ib) and three natural (type-Ia) diamonds using electron paramagnetic resonance spectroscopy. Bi-exponential SLR, with a fast and a slow component, was... (Read more)
- 75. J. Phys.: Condens. Matter 13, 2053-2060 (2001) , “Possible evidence of a copper-related electron paramagnetic resonance centre in diamond”, J. M. BakerThe EPR centre W36, found in natural type IIb diamond, has been previously attributed to a boron-related point defect, largely on account of its four line hyperfine structure attributed to 11B. The attribution has been re-examined, and no simple boron-related site has been found... (Read more)
- 76. Phys. Rev. B 64, 041201 (2001) , “Combined optical and microwave approach for performing quantum spin operations on the nitrogen-vacancy center in diamond”, Forrest T. Charnock and T. A. KennedyElectron spin echoes were performed on nitrogen-vacancy (N-V) centers in diamond using optical polarization and detection and 35 GHz microwave control. The experiments demonstrate an approach to quantum information in the solid state. A phase memory time of 3.6??s was measured, and coupling of the... (Read more)
- 77. Phys. Rev. B 63, 195208 (2001) , “Self-interstitial aggregation in diamond”, J. P. Goss, B. J. Coomer, R. Jones, T. D. Shaw, P. R. Briddon, M. Rayson, S. bergFirst-principles methods are used to investigate the self-interstitial and its aggregates in diamond. The experimental assignment of the spin-1 R2 EPR center to the single interstitial has been questioned because of the small fine-structure term observed. We calculate the spin-spin interaction... (Read more)
- 78. Physica B 302-303, 88-100 (2001) , “Magnetospectroscopy of acceptors in "blue" diamonds”, Hyunjung Kim, A. K. Ramdas, S. Rodriguez, Zdenka Barticevic, M. Grimsditch and T. R. AnthonyNaturally occurring, nitrogen-free, p-type diamond—now known to be boron-doped—as well as man-made diamonds deliberately doped with boron display an electronic Raman transition, Δ′, originating in the 1s(p3/2) : Γ8 ground state of the acceptor and terminating in its... (Read more)
- 79. J. Phys.: Condens. Matter 13, 8957-8964 (2001) , “Determination of the W8 and AB5 defect levels in the diamond gap”, R. N. Pereira, W. Gehlhoff, N. A. Sobolev, A. J. Neves, D. BimbergElectron paramagnetic resonance (EPR) and photo-EPR investigations on synthetic diamond crystals have allowed an unambiguous determination of nickel-related defect levels in the diamond bandgap. Indirect photoinduced recharging of the nitrogen donor and detection of two... (Read more)
- 80. J. Phys.: Condens. Matter 13, 2045-2051 (2001) , “An annealing study of the R1 EPR centre (the neatest-neighbour di-<100>-split self-interstitial) in diamond”, D. J. Twitchen, M. E. Newton, J. M. Baker, T. R. Anthony, W. F. BanholzerResults are reported of both isochronal and isothermal annealing studies of the R1 EPR centre (known to be a pair of parallel nearest-neighbouring 100-split self-interstitials) produced by 2 MeV electron irradiation of synthetic type IIa diamonds of very low defect concentration before... (Read more)
- 81. J. Phys.: Condens. Matter 11, 7357 (1999) , “A study of 13C hyperfine structure in the EPR of nickel-nitrogen-containing centres in diamond and correlation with their optical properties”, V. A. Nadolinny, A. P. Yelisseyev, J. M. Baker, M. E. Newton, D. J. Twitchen, S. C. Lawson, O. P. Yuryeva, B. N. FeigelsonElectron paramagnetic resonance (EPR) and optical spectroscopy have been used to determine the structure and electronic state of nickel-nitrogen centres in natural diamonds and in synthetic diamonds enriched in 13C. The latter were grown in an Fe-Ni-C solvent/catalyst system at 1750 K,... (Read more)
- 82. Phys. Rev. Lett. 67, 3420 (1991) , “Spin Dynamics and Electronic States of N-V Centers in Diamond by EPR and Four-Wave-Mixing Spectroscopy”, D. A. Redman, S. Brown, R. H. Sands, S. C. RandA new phase-modulation technique for nonlinear laser spectroscopy is applied with a relative resolving power in the sub-Hz range to measure fundamental relaxation processes of the N-V center in diamond. Complementary EPR experiments versus temperature establish the spin character of the ground state... (Read more)
- 83. Phys. Rev. B 46, 10600 (1992) , “Cross-relaxation dynamics of the N-V center in diamond as studied via optically detected microwave recovery transients”, I. Hiromitsu, J. Westra, M. GlasbeekThe N-V center in diamond is a nitrogen-vacancy pair defect with an electronic triplet spin ground state. Upon optical excitation and in the presence of an applied magnetic field, two subensembles of N-V centers with different spin temperatures are created at liquid-helium temperatures. For certain... (Read more)
- 84. Phys. Rev. B 47, 8809 (1993) , “Paramagnetic resonance of photoexcited N-V defects in diamond. I. Level anticrossing in the 3A ground state”, X. -F. He, N. B. Manson, P. T. H. FiskRaman-heterodyne-detected paramagnetic resonance has been used to study the level anticrossing in the 3A state of the N-V defect in diamond. The electron-paramagnetic-resonance (EPR) frequencies are well accounted for by a triplet-spin Hamiltonian. Comparison of the EPR spectra with the... (Read more)
- 85. Phys. Rev. B 47, 8816 (1993) , “Paramagnetic resonance of photoexcited N-V defects in diamond. II. Hyperfine interaction with the 14N nucleus”, X. -F. He, N. B. Manson, P. T. H. FiskHyperfine interactions associated with the 14N nucleus in the diamond N-V defect have been investigated using Raman-heterodyne techniques. The measured nuclear-magnetic-resonance (NMR) and electron-nuclear-double-resonance frequencies were well accounted for by the triplet-spin... (Read more)
- 86. Phys. Rev. B 56, 16031 (1997) , “Comment on "Electronic structure of the N-V center in diamond: Theory"”, J. P. Goss, R. Jones, P. R. Briddon, G. Davies, A. T. Collins, A. Mainwood, J. A. van Wyk, J. M. Baker, M. E. Newton, A. M. Stoneham, S. C. LawsonIt is argued that the model advanced by Lenef and Rand [Phys. Rev. B 53, 13 441 (1996)] for the nitrogen-vacancy center in diamond, exhibiting the 1.945-eV luminescence is incorrect. Lenef and Rand argue that the electronic ground state consists of two electrons occupying a1 states... (Read more)
- 87. Phys. Rev. B 56, 16033 (1997) , “Reply to "Comment on Electronic structure of the N-V center in diamond: Theory"”, A. Lenef, S. C. RandWe present insights into the electronic structure and relaxation of N-V color centers in diamond which support the contention that Jahn-Teller effects may play a very significant role in the excited E state. We also consider several opposing arguments, but show that the unusual relaxation behavior... (Read more)
- 88. Phys. Rev. B 52, 12657 (1995) , “Magnetic-resonance measurements on the 5A2 excited state of the neutral vacancy in diamond”, J. A. van Wyk, O. D. Tucker, M. E. Newton, J. M. Baker, G. S. Woods, P. SpearThe ground state of the neutral vacancy in diamond is diamagnetic and therefore has not been studied by electron paramagnetic resonance (EPR). We report the observation of EPR from the 5A2 excited state of the neutral vacancy by EPR when illuminating an electron-irradiated... (Read more)
- 89. Phys. Rev. B 49, 15392 (1994) , “g tensor for substitutional nitrogen in diamond”, S. Zhang, S. C. Ke, M. E. Zvanut, H. T. Tohver, Y. K. VohraWe report a measurement of an axially symmetric g tensor for the substitutional nitrogen center in type-IIa synthetic isopure 12C diamond. Because the nitrogen concentration of the diamond studied is exceptionally low the electron-paramagnetic-resonance linewidth is sufficiently narrow to... (Read more)
- 90. Phys. Rev. 118, 939 (1960) , “Cross Relaxation Studies in Diamond”, P. P. Sorokin, G. J. Lasher, and I. L. GellesA microwave double resonance experiment performed on the paramagnetic nitrogen centers in diamond shows that in this system cross relaxation occurs via a four spin flip mechanism which exactly conserves Zeeman energy. In this process, which was first postulated by Bloembergen and co-workers in their... (Read more)
- 91. J. Appl. Phys. 32, 1854 (1961) , “Paramagnetic Resonance of Defects Introduced Near the Surface of Solids by Mechanical Damage”, G. K. Walters and T. L. EstleElectron spin resonance characteristics of a number of materials subjected to violent mechanical treatment are reported. A line with g=2.0055 observed in silicon is attributed to defects introduced near the surface by mechanical damage. The resonance properties are uninfluenced by... (Read more)
- 92. Solid State Commun. 3, 307 (1965) , “EXCHANGE INTERACTION EFFECTS IN THE E.S.R. SPECTRUM OF SUBSTITUTIONAL NITROGEN IN DIAMOND”, J. H. N. Loubser, W. P. van Ryneveld and L. du PreezThe E.S.R. lines due to substitutional nitrogen in synthetic diamond powders, heavily doped with nitrogen, were found to exhibit the characteristic features of exchange interaction. In the coats of natural diamonds additional lines due to exchange interaction between triads of nitrogen atoms were... (Read more)
- 93. J. Chem. Phys. 42, 1898 (1965) , “Irradiation Damage in Type I Diamond”, H. B. Dyer and L. du PreezIn addition to the GRI and uv bands induced in all diamond by 0.78-MeV electron irradiation, another optical absorption feature, which we have named the ND1 band, is found in all Type I diamonds. A single EPR line appears to be associated with the ND1 band.It is suggested that the ND1 center arises... (Read more)
- 94. Brit. J. Appl. Phys. 16, 457 (1965) , “New lines in the electron spin resonance spectrum of substitutional nitrogen donors in diamond”, J. H. N. Loubser, L. du PreezThe electron spin resonance lines of nitrogen impurity in diamond found by Smith, Sorokin, Gelles and Lasher have been re-examined in special samples and at low energy densities. (Read more)
- 95. Brit. J. Appl. Phys. 18, 1029 (1967) , “The dynamic Jahn - Teller and other effects in the high-temperature electron spin resonance spectrum of nitrogen in diamond”, J. H. N. Loubser, W. P. van RyneveldThe re-orientation of the Jahn-Teller distortion of the C-N bond in diamond containing substitutional nitrogen was observed, through its effect on shape of the hyperfine lines of the nitrogen electron spin resonance spectrum, in the range 600-1230°K. The weak satellite lines due to... (Read more)
- 96. J. Appl. Phys. 41, 2977 (1970) , “Analysis of an Electron Spin Resonance Spectrum in Natural Diamonds”, P. E. Klingsporn, M. D. Bell, and W. J. LeivoAn anisotropic electron spin resonance spectrum was observed in three natural Type Ib diamonds. The diamonds which exhibit the spectrum also show the spectrum from substitutional nitrogen donors previously observed by others. The spectrum consists of three anisotropic groups of lines. The spectrum... (Read more)
- 97. J. Appl. Phys. 42, 722 (1971) , “New S = 1 EPR Center in Irradiated Diamond”, Y. M. Kim, G. D. WatkinsElectron spin resonance studies have been made of natural diamond crystals electron-irradiated at room temperature. A radiation-induced spectrum is identified as arising from a new anisotropic S=1 center. The S=1 center is characterized by: g1=2.0026,... (Read more)
- 98. Jpn. J. Appl. Phys. 14, 544 (1975) , “Study of Defects Introduced by Ion Implantation in Diamond”, J. -F. Morhange, R. Beserman, J. C. BourgoinNatural type IIa diamonds have been implanted with 70 keV carbon, nitrogen and boron ions. The behaviour of the defects introduced is monitored using electron paramagnetic resonance, absorption, luminescence and Raman scattering measurements. We first describe and discuss the applicability of these... (Read more)
- 99. Solid State Commun. 22, 767 (1977) , “ESR STUDIES OF DIAMOND POWDERS”, J. H. N. LoubserThe ESR spectrum of two defect centres were observed in finely ground diamond powders (0.5 to 30 μm size). The one centre has been seen before in irradiated and annealed single crystals of natural diamonds (the O1 centre) while the second one has only been seen in synthetic diamonds grown from... (Read more)
- 100. Solid State Commun. 26, 255 (1978) , “EPR STUDIES OF A TWO-NITROGEN-ATOM CENTRE IN NATURAL, PLASTICALLY-DEFORMED DIAMOND”, C. M. WelbournThe hyperfine structure of an EPR system in a natural, brown diamond implies that the system is due to a centre containing two nitrogen atoms on almost equivalent sites. X-ray topographic evidence shows that the sample has been plastically deformed and it is suggested that a possible model for the... (Read more)
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