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Cytomic the glue vs ni supercharger how to#
Advocating, asking for, or giving advice on how to pirate is prohibited.If you're not sure if your post will fit or not, message the moderators. Users posting links to tracks for views or feedback, soliciting/offering services, promoting fan pages, using follow-gates/download-gates, or otherwise benefiting financially from the sub will be banned for a day and informed to read the rules. Spam & self-promotion (outside of the Marketplace thread, where ads are encouraged) will be removed.Keep it productive, intelligent, intelligible, and constructive.If your thread is vague, unclear, or easily answered by searching ("does anyone else.?" "Any suggestions for.?") it may be removed. If your thread is only tangentially related, it is probably considered off-topic. Please submit only content and discussion that is specifically relevant to music production.Repeated or egregious offenses will be countered with a ban. If you disagree with something, make your case politely. No flame wars, disrespect, condescension based on level of experience, or tactless posts stereotyping any group of people will be tolerated. Posts and comments are expected to be civil, even when there are disagreements.Please report threads and comments that violate the following rules: Be respectful This stepwise decrease in both the friction coefficient and the desorption energy may be due to molecular layering of the ethanol.This subreddit is for those wishing to discuss electronic dance music production. At coverages between 1.0 and 2.5 ML of ethanol on each Ni(100) surface, the static friction coefficient decreases in a stepwise manner that is correlated with discontinuities in the ethanol desorption energy. The friction coefficient drops to μ s = 3.1 ± 1, while the adhesion coefficient is lowered to μ ad ≈ 0.25. An abrupt decrease in both the friction coefficient and adhesion coefficient occurs at a coverage of 1 ML of ethanol on each surface. In the submonolayer coverage regime of either atomic sulfur or adsorbed ethanol, the behavior is characterized by a high friction coefficient (μ s > 5.5) accompanied by high adhesive forces (μ ad = 1.5 ± 0.7). During shearing, sliding never commences between clean Ni(100) surfaces or sulfided Ni(100) surfaces without adsorbed ethanol. Friction measurements made with ethanol coverages ranging from 0 to 10 monolayers (ML) on each Ni(100) surface reveal that the friction coefficient is discontinuous in coverage and can be correlated to the coverage dependence of the ethanol desorption energy. Friction measurements have been made between a pair of clean Ni(100) surfaces, modified by the presence of adsorbed atomic sulfur with and without adsorbed ethanol. The combined use of an ultrahigh vacuum tribometer and a variety of surface science techniques has enabled us to explore the tribological properties of interfaces between Ni(100) surfaces and to observe phenomena attributable to molecular layering.
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