Focusing of light is widely used in optical microprobes where a stable and well-confined beam of photons is scanned or directed over some area of a biological sample or photonic structure. Such focusing microprobes may be useful for laser surgery, optical endoscopy and spectroscopy, high-density optical-data storage, and photo-induced patterning of thin films. A fundamental principle of diffraction-limited optics is that the spatial resolution of focusing devices is limited by the wavelength of the incident light and by the aperture of the objective-lens system. Spatial resolution beyond the classical optical diffraction limit can be obtained using near-field optical phenomena1 or special material properties such as fluorescent, nonlinear,2 or negative refractive-index3 effects. However, low-transmission of nearfield microprobes and difficulties in realizing desirable material properties limit the usefulness of these approaches for many biomedical and photonic applications. A few years ago, it was demonstrated that a small wavelength-scale microsphere with a refractive index of approximately 1.6 produces a narrow focused beam, termed a ‘nanoscale photonic jet.’4 Such a photonic nanojet propagates with little divergence for several wavelengths into the surrounding medium, while maintaining a subwavelength transverse beam width. The concept of nanojets is attractive for designing focusing microprobes with high optical-transmission properties. Note, however, that photonic nanojets from single spheres require strictly plane-wave illumination, which is not readily available in devices using flexible optical-delivery systems. More recently, we observed periodic focusing in chains of polystyrene microspheres assembled on substrates.6, 7 In these chains, the photonic nanojets were quasi-periodically reproduced along the chain, giving rise to novel ‘nanojet-induced modes’ (NIMs). We saw that the coupled nanojets reduced Figure 1. (a) Packing of 125 m spheres inside a microcapillary tube. (b) Ray tracing of paraxial (red) and skew (blue and green) beams for microspheres with refractive index n=1.9 performed by ZEMAX-EE software.5 Only transmitted rays are shown. (c) Microprobe inserted in a gel. (d) Focusing at a wavelength D 0:63 m with microcapillary tube in contact with tissue.
[1]
A. M. Kapitonov,et al.
Observation of nanojet-induced modes with small propagation losses in chains of coupled spherical cavities.
,
2007,
Optics letters.
[2]
S. Hell.
Far-Field Optical Nanoscopy
,
2007,
Science.
[3]
J. Pendry,et al.
Negative refraction makes a perfect lens
,
2000,
Physical review letters.
[4]
V. Astratov,et al.
Photonic nanojet-induced modes in chains of size-disordered microspheres with an attenuation of only 0.08dB per sphere
,
2008
.
[5]
Allen Taflove,et al.
Photonic nanojet enhancement of backscattering of light by nanoparticles: a potential novel visible-light ultramicroscopy technique.
,
2004,
Optics express.
[6]
Olivier J. F. Martin,et al.
Scanning near-field optical microscopy with aperture probes: Fundamentals and applications
,
2000
.