Future Pacing

This technique is to take the subject to a time in the future and see/hear/feel himself making a decision right there. Or, you can have the subject see clearly a future event that you want to happen. 

This technique will enable you to make sure that once you secure a commitment or agreement, they won t back out or change their mind in the future. 

Create a situation in the future where that commitment might be challenged. 

As them what will cause them to keep their commitment anyway. 

This technique is actually a TIME-RELEASED Suggestion. When the situation arises, the memory of the reason to keep the commitment will magically pop into their mind. 

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Deshmukh PM, Romanyshyn M. Direct His-bundle pacing, present and future. PACE 2004 27 862. 

We cannot solve the Schroedinger equation in closed fomi for most systems. We have exact solutions for the energy E and the wave function (1/ for only a few of the simplest systems. In the general case, we must accept approximate solutions. The picture is not bleak, however, because approximate solutions are getting systematically better under the impact of contemporary advances in computer hardware and software. We may anticipate an exciting future in this fast-paced field. 

Particle trajectories can be calculated by utilizing the modern CFD (computational fluid dynamics) methods. In these calculations, the flow field is determined with numerical means, and particle motion is modeled by combining a deterministic component with a stochastic component caused by the air turbulence. This technique is probably an effective means for solving particle collection in complicated cleaning systems. Computers and computational techniques are being developed at a fast pace, and one can expect that practical computer programs for solving particle collection in electrostatic precipitators will become available in the future. 

As the years progress, so the pace of new technological development seems to follow an exponential curve. It is impossible to predict all the changes that will occur, even in the near future, so we have selected four which we feel will have a significant impact on the work of pesticide residue analysts over the next 1-2 decades. 

Clearly, it would be difficult at present to predict future development of the field, but the results already obtained leave no doubts that such applications are very promising. A great deal of further work is needed to develop these demonstrations into a practical set of tools for routine use, and the current pace of the progress in the field of non-medical MRI applications leaves no doubts that this goal can be achieved. 

There is some dispute among analysts as to whether world production of conventional oil will peak before the year 2020 or whether the peak will be delayed by another decade or two (Kerr, 1998), but in either case the current era of relatively cheap oil will end within several decades. A similar scenario is likely to follow for natural gas, although at a slower pace, and at a still slower pace, for coal. If our responsibilities to future generations include the relatively small problems that nuclear waste repositories may create in 10,000 years, they also include preparing for fossil fuel scarcity that will occur very much sooner. 

We expect the development of the mechanistic aspects of organic photochemistry to continue at the present pace as new methods are developed to probe in increasing detail and shorter time scales the photochemical dynamics of both old and new photoreactions. Since photochemistry is no longer the sole domain of the specialist, it is relatively safe to predict a dramatic increase in the near future of the synthetic and industrial uses of organic photochemistry. 

Finally, all scenarios analysed in PACE-T(H2) assume the same international import export structures of hydrogen and conventional cars (structural identity assumption). In other words, if a country is producing and exporting conventional cars at present, the assumption is made that this country will also produce and export hydrogen cars in the future. 

Research on FLAP has continued at a rapid pace, with gene cloning, promoter analysis and site-directed mutagenesis in progress [498,499], This promises to be an area of great interest in the future. 

The state of the art has now advanced to the point that synchrotron sources are frequently not the hmiting factor in biological XAS. In particular, there is concern that sample measurement techniques have not kept pace with the development of new sources. Several new detection schemes are under development, however it may be several years before detectors will be available which are capable of fully utilizing the intensity available firom new sources. In addition, there is concern that very intense sources may compromise sample integrity. Taken together, these concerns suggest that it is not reasonable to extrapolate past experience when attempting to predict the effect of new sources on future concentrations limits. Metal ion concentrations below ca. 100 )tM are likely to remain inaccessible for many years. 

World War II helped shape the future of polymers. Wartime demands and shortages encouraged scientists to seek substitutes and materials that even excelled those currently available. Polycarbonate (Kevlar), which could stop a speeding bullet, was developed, as was polytetrafluoroethylene (Teflon), which was super slick. New materials were developed spurred on by the needs of the military, electronics industry, food industry, etc. The creation of new materials continues at an accelerated pace brought on by the need for materials with specific properties and the growing ability to tailor-make giant molecules macromolecules—polymers. 

Psychopharmacotherapy is still an empirically based approach. Advances in the neurosciences, however, are occurring at an increasingly rapid pace and will ultimately provide a much more complete understanding of cerebral structure and function, as well as guide clinical drug therapies in the future. 

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