ライフサイエンスコーパス: nitrogen-vacancy centre

1 applications, as developed with the diamond nitrogen vacancy centre.

2 iamond cantilever to the spin of an embedded nitrogen-vacancy centre.

3 n of the (13)C ensemble in the vicinity of a nitrogen-vacancy centre.

4 ield collection of the fluorescence from the nitrogen-vacancy centre.

5 f functionality not available to the diamond nitrogen-vacancy centre.

6 implemented using a single nuclear spin in a nitrogen-vacancy centre.

7 that are comparable to those of the diamond nitrogen-vacancy centre.

8 band of diamond by two-photon ionization of nitrogen-vacancy centres.

9 gates using the solid-state spins of diamond nitrogen-vacancy centres.

10 33 kHz, which is unprecedented for scanning nitrogen-vacancy centres.

11 strict scalable and feasible manipulation of nitrogen-vacancy centres.

12 neering(10) in a two-dimensional ensemble of nitrogen-vacancy centres.

13 e magnetic dipole-dipole interaction between nitrogen-vacancy centres.

14 mics of a relatively ordered sub-ensemble of nitrogen-vacancy centres.

15 xperiments have been performed with spins in nitrogen-vacancy centres(6), optical photons(7-9) and ne

16 sed on the detection of photons emitted from nitrogen-vacancy centres, a process limited by the effic

17 iple for detecting the magnetic resonance of nitrogen-vacancy centres, allowing the direct photoelect

18 Spin complexes comprising the nitrogen-vacancy centre and neighbouring spins are being

19 , electrons, cavity quantum electrodynamics, nitrogen-vacancy centres and superconducting quantum bit

20 spin bath in diamond by using an ensemble of nitrogen-vacancy centres, and demonstrated excellent agr

21 ize such atomic-scale imaging using a single nitrogen vacancy centre as a quantum sensor, and demonst

22 tically induced spin polarization of diamond nitrogen vacancy centres at room temperature in combinat

23 This is achieved by positioning a single nitrogen-vacancy centre at the end of a high-purity diam

24 Here, we use a diamond-nanocrystal-hosted nitrogen-vacancy centre attached to the apex of a silico

25 gnitude in the spin coherence time (T(2)) of nitrogen-vacancy centres compared with previous measurem

26 The readout of negatively charged nitrogen-vacancy centre electron spins is essential for

27 onstrate experimentally that 42% of a single nitrogen-vacancy centre emission efficiently couples int

28 oom temperature mechanical resonator using a nitrogen-vacancy centre ensemble.

29 ntly, a point defect in diamond known as the nitrogen-vacancy centre has attracted a great deal of in

30 We show detected emission from bright single nitrogen vacancy centres hosted in the fabricated nanodi

31 -state spin qubit system associated with the nitrogen vacancy centre in diamond, using coherent feedb

32 ociated with the single electronic spin of a nitrogen vacancy centre in diamond.

33 ccessfully observed for spins in silicon and nitrogen vacancy centres in diamond, and for orbital mot

34 ing quantum spin magnetometers realized with nitrogen vacancy centres in diamond.

35 ence times that are competitive with typical nitrogen vacancy centres in small nanodiamonds under amb

36 nstrate a single-photon source composed of a nitrogen-vacancy centre in a diamond nanowire, which pro

37 Among solid-state systems, the nitrogen-vacancy centre in diamond has emerged as an exc

38 We use the electron spin of a nitrogen-vacancy centre in diamond to selectively initia

39 e ability to control the interaction between nitrogen-vacancy centres in diamond and photonic and/or

40 Quantum dots or nitrogen-vacancy centres in diamond can be coupled to li

41 Electronic spins of nitrogen-vacancy centres in diamond constitute a promisi

42 In particular, nitrogen-vacancy centres in diamond have recently emerge

43 Using nitrogen-vacancy centres in diamond nanocrystals (nanodi

44 We demonstrate a protocol using individual nitrogen-vacancy centres in diamond to observe the time

45 Alongside research focusing on nitrogen-vacancy centres in diamond, an alternative stra

46 is case, substitutional nitrogen and neutral nitrogen-vacancy centres in diamond, through optically d

47 hallenge, using magnetometry based on single nitrogen-vacancy centres in diamond.

48 n of nuclei located near optically polarized nitrogen-vacancy centres in diamond.

49 eful in other contexts such as ion traps and nitrogen-vacancy centres in diamond.

50 Lateral flow tests using nitrogen-vacancy centres in nanodiamond labels offer hig

51 The nitrogen-vacancy centre is an atomic scale sensor and we

52 quantum information to metrology, where the nitrogen-vacancy centre is the most studied to date.

53 as a stable alternative, and, in the case of nitrogen-vacancy centres, offer spin quantum bits with o

54 allowing the direct photoelectric readout of nitrogen-vacancy centres spin state in an all-diamond de

55 rm for addressing and controlling individual nitrogen-vacancy centre spins in diamond at room tempera

56 nt interest in a hybrid system consisting of nitrogen-vacancy centre spins that interact with the res

57 itate design guidelines for devices based on nitrogen-vacancy centres that use these freestanding hyb

58 patible with the intrinsic symmetries of the nitrogen-vacancy centre to enable functionality at megab

59 ons rely on the ability to position a single nitrogen-vacancy centre within a few nanometres of a sam

60 strate a robust method for scanning a single nitrogen-vacancy centre within tens of nanometres from a