attocube systems - Scanning Near-Field Optical Microscopy SNOM NSOM Low Temperature

Products & Solutions

	INTRODUCTION

	CFM

	attoCFM I

	attoCFM II

	attoCFM IIxs

	attoCFM III

	AFM

	attoAFM I

	attoAFM III

	SNOM

	attoSNOM II

	attoSNOM III

	STM

	attoSTM I

	APPLICATION NOTES

	PUBLICATIONS

	OPTIONS

	SNOM FIBER PROBES

	ACCESSORIES

attoSNOM I
cantilever based low temperature scanning near-field optical microscope, interferometric sensor
:.........................................................................................

The attoSNOM I works by scanning a cantilever in the optical near-field of a sample surface. The near-field probe in attoSNOM I configuration is a cantilever that acts simultaneously as a topographic sensor in contact or modulation mode, and as an optical aperture. The cantilever-based attoSNOM I offers an easy-to-use setup allowing high quality topographic and optical imaging at cryogenic temperatures. The system can be applied for reflection as well as transmission measurements. One of the key features of this system is the ease of use due to the simple tip-handling and wellknown tip-sample distance control using the interferometric detection scheme.

Tip-Sample Distance Control - The distance control is performed using the interferometric deflection detection scheme as also applied in attoAFMs. The schematic drawing to the left describes the setup. A laser beam coupled into a single mode fiber (port 1) is used to illuminate an interferometer via a fiber coupler. At the end of the second interferometer arm (port 2), light is reflected at the end interface of the fiber. The rest of the light is transmitted and partially reflected at the AFM cantilever. Therefore, the tip interface and the fiber end face form a Fabry-Perot interferometer. A large part of the light reflected in this structure is coupled back into the optical fiber and detected with Detector 1. Detector 2 mounted at arm 3 can be used to monitor the intensity emitted by the laser (optional). Monitoring the intensity of the interference fringes allows to measure the tip vibration amplitude. The precision of the vibration amplitude measurement is 160 fm / Hz1/2.

Probes - The microfabricated cantilever SNOM sensor distributed by WITec© consists of a silicon cantilever with a hollow aluminum pyramid as a tip. This pyramid has a small aperture (~100 nm) in diameter at its apex. One major advantage of these mass-produced tips is the ease of probe handling unique in SNOM technology.

Download:

Detailed Specification Sheet

Request Quotation & Support :

Sales contact

Additional Information:
Applications	Publications	Fundamentals

Available Controller for this Product:
ASC500	SPM controller with xy-scan generator incl. feedback control und fully digital phase locked loop (PLL)
ANC150	Piezo step controller for coarse positioning \| 1, 3 or 6-axes control \| Optional: TFT-display, TTL-input
ANC200	Piezo scan controller for ultra high resolution scan \| 1 to 6-axes control

Complete System Solutions:
LTSYS	Complete system configurations for this product.

Topography measurement (top) and simultaneously
obtained near-field measurement in transmission (bottom) using the attoSNOM I. Sample: Vanadium rhomb-structure on glass substrate with a layer thickness of 10 nm and a period of 5 µm. Distance control: interferometric sensor. (attocube application labs, 2007).

Optical transmission measurement of a detector glass plate recorded using the attoSNOMI. Local defects are clearly resolved.