The original message was received at Thu, 26 Jan 2006 02:18:24 -0900 (AKST) from rdbck-2615.palmer.mtaonline.net ----- The following addresses had permanent fatal errors ----- ----- Transcript of session follows ----- <[email protected]>... Deferred: Connection refused by ultra5.eskimo.com. Message could not be delivered for 12 hours Message will be deleted from queue Reporting-MTA: dns; eng-prv.mtaonline.net Arrival-Date: Thu, 26 Jan 2006 02:18:24 -0900 (AKST) Final-Recipient: RFC822; [email protected] Action: failed Status: 4.4.7 Remote-MTA: DNS; ultra5.eskimo.com Last-Attempt-Date: Thu, 26 Jan 2006 23:51:23 -0900 (AKST) From: Horace Heffner <[EMAIL PROTECTED]> Date: January 26, 2006 2:15:31 AM AKST Subject: Re: questions about Horacs's paper On Jan 25, 2006, at 10:03 AM, thomas malloy wrote:
I responded: "Well I thought I made it crystal clear in: "Oxygen, best of all in the table, provides a prospective nucleus for interaction in the plasma-liquid environment of the anode glow." Oxygen is the most prominent heavy element in water. It has the highest projected temperature. This is *why* I put it in the table. It [is] hot and it is ubiquitous in the anode interphase. This is a no brainer. The only other element always present in water is hydrogen, and extracting uncertainty energy may mean interacting down at the quark level - which is not realistic or practical. Deuterons may be a possibility though." It just dawned on me you might be asking the *reason* or *method* for interacting with the oxygen. The idea is that the nucleus has a high heat sustained there by interaction with the zero point field. The problem is to interact with the nucleus at a high rate in order to sample and thus extract that heat. This can be done continually because if the heat is bled off the ZPF replaces it. The extremely high field in the interphase provides two possible mechanism for interacting with the nucleus. First, the oxygen orbital orbitals are highly deformed in the extreme interphase electrostatic field, thus greatly increasing the probability of interaction of the K shell electrons with it. Second, the plasma avalanche created by protons free at the anode interface may ionize some of the oxygen and permit direct interaction with it by medium energy electrons, especially under high pressures. The result of localized avalanch ionization effect might be called nano-sonoluminescence. Horace Heffner |
