XFT is about CHEMISTRY not CHEMICALS

Proprietary Chemistry

The driving component, or primary active ingredient in Xtreme Fuel Treatment organo-metallic fuel catalyst, has been evaluated utilizing some of the most stringent testing procedures by reputable and reliable laboratories and government entities. This organo-metallic chemistry is an important component in Xtreme Fuel Treatment and has been evaluated by the following reputable entities:

SAE Paper 900154 concluded that the active ingredient included in Xtreme Fuel Treatment improved fuel octane qualitiy, reduced emissions dramatically, while improving fuel efficiency.

U.S. Dept. of Interior; Bureau of Mines Paper RI 9438 determined that the active ingredient utilized in Xtreme Fuel Treatment catalyst reduces emissions significantly.

Southwest Research Paper Diesel Engine Emission Control Technologies; Appendix B, subsection B.3.5 describes the active ingredient in Xtreme Fuel Treatment as a component that increases cetane and reduces burnout time and temperature requirements in new Diesel Particulate Filters (DPF).

Southwest Research Paper, Hydrocarbon Fuel Chemistry provides documentation that the active ingredient in Xtreme Fuel Treatment reduces compression ignition emissions as much as 20% and improves fuel efficiency as much as 10%.

NIOSH IC 9462, Department of Health and Human Services Paper; subsection 2.3.3 indicates that the active ingredient incorporated in Xtreme Fuel Treatment reduces smoke particulate by 25% and reduces burnout time and temperature in new Diesel Particulate Filters (DPF).

Canadian Environmental Protection Agency Paper; subsection 5.2.4.1 determined that the active ingredient utilized in Xtreme Fuel Treatment reduces Diesel Particulate Filter (DPF) filterable matter by 23% and reduces total particulate matter by 22%.

California Air Resource Board (CARB), 3D Air Quality – Emissions Report; appendix B states that the active ingredient contained in Xtreme Fuel Treatment reduces burnout time and temperature in new Diesel Particulate Filters (DPF). Tests show reductions of particulates by 20% without the DPF and two-fold reductions with the DPF.

Olsen Laboratories determined that Xtreme Fuel Treatment reduced emission during the EPA Highway Fuel Economy Test (HFET) and Federal Test Procedure (FTP).

There are many more such tests available documenting the performance of the organo-metallic active ingredient which is a vital part of the success of the Xtreme Fuel Treatment. For this reason, critical thinking entities, such as those mentioned in this document, have evaluated this organo-metallic component many times to insure qualitative and quantitative performance.

The organo-metallic that is in Xtreme Fuel Treatment was created by two Nobel prize winning scientists.  Their names are Ernst Otto Fischer and Geoffrey Wilkinson.

Ernst Otto Fischer

Ernst Otto Fischer (November 10, 1918 – July 23, 2007) was a German chemist who won the Nobel Prize for pioneering work in the area of organo-metallic chemistry.

Early life

He was born in Solln, near Munich. His parents were Karl T. Fischer, Professor of Physics at the Technical University of Munich (TU), and Valentine née Danzer. He graduated in 1937 with Abitur. Before the completion of two years' compulsory military service, the Second World War broke out, and he served in Poland, France, and Russia. During a period of study leave, towards the end of 1941 he began to study chemistry at the Technical University of Munich. Following the end of the War, he was released by the Americans in the autumn of 1945 and resumed his studies, graduating in 1949.

Career

Fischer worked on his doctoral thesis as an assistant to Professor Walter Hieber in the Inorganic Chemistry Institute, His thesis was entitled "The Mechanisms of Carbon Monoxide Reactions of Nickel(II) Salts in the Presence of Dithionites and Sulfoxylates". After receiving his doctorate in 1952, he continued his research on the organo-metallic chemistry of the transition metal and indicated with his lecturer thesis on "The Metal Complexes of Cyclopentadienes and Indenes". that the structure postulated by Pauson and Kealy might be wrong. Shortly after he published the structural data of ferrocene, the sandwich structure of the η⁵ (pentahapto) compound. He was appointed a lecturer at the TU in 1955 and, in 1957, professor and then, in 1959, C4 professor. In 1964 he took the Chair of Inorganic Chemistry at the TU.

In 1964, he was elected a member of the Mathematics/Natural Science section of the Bavarian Academy of Sciences. In 1969 he was appointed a member of the German Academy of Natural Scientists, Leopoldina and in 1972 was given an honorary doctorate by the Faculty of Chemistry and Pharmacy of the University of Munich.

He lectured across the world on metal complexes of cyclopentadienyl, indenyl, arenes, olefins, and metal carbonyls. In the 1960s his group discovered a metal alkylidene and alkylidyne complexes, since referred to as Fischer carbenes and Fischer-carbynes. Overall he published about 450 journal articles and he trained many PhD and postdoctoral students, many of whom went on to noteworthy careers. Among his many foreign lectureships, he was Firestone Lecturer at the University of Wisconsin–Madison (1969), visiting professor at the University of Florida (1971), and Arthur D. Little visiting professor at the Massachusetts Institute of Technology (1973).

He has received many awards including, in 1973 with Geoffrey Wilkinson, the Nobel Prize in Chemistry for his work on organo-metallic compounds.

Death

He died on July 23, 2007 in Munich. At the time of his death, Fischer was the oldest living German Nobel laureate. He was succeeded by Manfred Eigen, who shared the Nobel Prize in Chemistry in 1967 and is nine years younger than Fischer was.

                                      
Geoffrey Wilkinson

Sir Geoffrey Wilkinson FRS (14 July 1921 – 26 September 1996) was a Nobel laureate English chemist who pioneered inorganic chemistry and homogeneous transition metal catalysis.

Biography

Wilkinson was born at Springside, Todmorden, in Yorkshire. His father, also a Geoffrey, was a master house painter and decorator; his mother worked in a local cotton mill. One of his uncles, an organist and choirmaster, had married into a family that owned a small chemical company making Epsom and Glauber's salts for the pharmaceutical industry; this is where he first developed an interest in chemistry.

He was educated at the local council primary school and, after winning a County Scholarship in 1932, went to Todmorden Secondary School. His physics teacher there, Luke Sutcliffe, had also taught Sir John Cockcroft, who received a Nobel Prize for "splitting the atom".

In 1939 he obtained a Royal Scholarship for study at Imperial College London, from where he graduated in 1941. In 1942 Professor Friedrich Paneth was recruiting young chemists for the nuclear energy project. Wilkinson joined and was sent out to Canada, where he stayed in Montreal and later Chalk River Laboratories until he could leave in 1946. For the next four years he worked with Professor Glenn T. Seaborg at University of California, Berkeley, mostly on nuclear taxonomy. He then became a Research Associate at the Massachusetts Institute of Technology and began to return to his first interest as a student - transition metal complexes of ligands such as carbon monoxide and olefins.

He was then at the Harvard University from September 1951 until he returned to England in December 1955, with a sabbatical break of nine months in Copenhagen. At Harvard, he still did some nuclear work on excitation functions for protons in cobalt, but had already begun to work on olefin complexes.

In June 1955 he was appointed to the chair of Inorganic Chemistry at Imperial College London, and from then on worked almost entirely on the complexes of transition metals. Imperial College London named a new hall of residence after him, which opened in October 2009.

He was married, with two daughters.

Work

He is well known for his invention of Wilkinson's catalyst RhCl(PPh₃)₃, and for the discovery of the structure of ferrocene. Wilkinson's catalyst is used industrially in the hydrogenation of alkenes to alkanes.

He received many awards, including the Nobel Prize for Chemistry in 1973 for his work on “organo-metallic compounds” (with Ernst Otto Fischer). He is also well known for writing, with his former doctoral student F. Albert Cotton, "Advanced Inorganic Chemistry", often referred to simply as "Cotton and Wilkinson", one of the standard inorganic chemistry textbooks.

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