new ideas and questions re hoov's prelim report

"State of the art aerial magnetic/EM surveys have been completed on two "sectors" of Noront's claims, with the final two being flown at present by Terraquest. With 100 metre transects on a 60 metre elevation, the data being obtained is already revealing exciting new targets. Approximately 10 have already been given high priority, all within the southern band of the ring that has given the greatest prior success."

Which claim blocks are these. As Edgy pointed out, that is exciting

Certainly Hoov’s message indicates mining, but still that lingering thought Voisen expressed by saying, “There is just no way.”Hoov spent time with Voisen, so perhaps he’s got an updated opinion. I find it useful to have perspectives from neighboring CEO’s.

QUESTION TO HOOV:

1- “Do you really believe they are going to mine?”

2-Can the Squid be utilized elsewhere to expand E-Nest while waiting for correct AT12 conditions?

-Stock Greed

RESEARCH: SQUID

There are fantastic sites when researching Squid. Here are a few. Go to links and read, the pics really help.

This is just a cool site:

http://tle.geoscienceworld.org/cgi/content/abstract/27/1/70

Application of high-temperature superconductor SQUIDs for ground-based TEM

K. E. Leslie, R. A. Binks, S. K. H. Lam, P. A. Sullivan, D. L. Tilbrook, R. G. Thorn and C. P. Foley

CSIRO, Sydney, Australia

Corresponding author: Keith.Leslie@csiro.au

Superconducting quantum interference devices (SQUIDs) are intrinsically very sensitive detectors of magnetic flux. Flux sensitivities of one millionth of a flux quantum per root Hz (1µ0/Hz) may typically be realized in low-temperature superconductor (LTS) materials, while sensitivities of 5µ0/Hz may be realized in high-temperature superconductor (HTS) materials. LTS devices are typically cooled with liquid helium (4 K) while HTS devices are typically cooled with liquid nitrogen (77 K). Coupling the magnetic field into a SQUID via a flux-transformer can result in a very sensitive magnetometer with, depending on the type of superconducting material used and the effective area of the flux-coupling transformer, achievable magnetic field sensitivities ranging from fT/Hz to pT/Hz over typical bandwidths that span hundreds of kHz. SQUID applications include NDE, biomagnetism and magnetic microscopes.

http://cnx.org/content/m22750/latest/

Theory of A Superconducting Quantum Interference Device (SQUID)

Module by: Samuel Maguire-Boyle, Andrew R. Barron. http://www.npl.co.uk/quantum-phenomena/nanophysics/research/squid-magnetometer