Showing
10, 25, 50, 100, 500, 1000, all papers per page.
Sort by:
last publication date,
older publication date,
last update date.
- 201. 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. Il’in, S. V. Lenskaya, V. P. Butuzov
- 202. Sov. Phys. Solid State 9, 1545 (1968) , “EXCHANGE PAIRS OF NITROGEN IMPURITIES IN DIAMOND”, L. A. Shul’man, I. M. Zaritskii, K. A. Tikhonenko
- 203. 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)
- 204. 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)
- 205. Sov. Phys. Solid State 8, 1842 (1967) , “REORIENTATION OF THE JAHN-TELLER DISTORTION IN NITROGEN IMPURITY CENTERS IN DIAMOND”, L. A. Shul’man, I. M. Zaritskii, G. A. Podzyarei
- 206. 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)
- 207. 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) - 208. 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)
- 209. 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)
- 210. 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)
- 211. Sov. Phys. Solid State 6, 2460 (1965) , “DISTRIBUTION OF PARAMAGNETIC NITROGEN CENTERS IN SOME TYPE-I DIAMONDS”, N. D. Samsonenko
- 212. 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)
- 213. 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)
- 214. 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)
- 215. 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)
- 216. 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)
- 217. 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 2.0024±0.0005. 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)
- 218. 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)
- 219. 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)
Showing
10, 25, 50, 100, 500, 1000, all papers per page.
Sort by:
last publication date,
older publication date,
last update date.
All papers (3399)
Updated at 2010-07-20 16:50:39
Updated at 2010-07-20 16:50:39
(view as: tree
,
cloud
)
1329 | untagged |
Materials
(111 tags)
Others(101 tags)
Technique
(46 tags)
Details
(591 tags)
Bond(35 tags)
Defect(interstitial)(18 tags)
Defect(vacancy)(15 tags)
Defect-type(19 tags)
Element(65 tags)
Energy(8 tags)
Isotope(56 tags)
Label(303 tags)
Sample(17 tags)
Spin(8 tags)
Symmetry(15 tags)