Emotional energy meter
Imagine your body as an orchestra where every cell plays in harmony under the guidance of a conductor—your body’s weak nonlinear electromagnetic field (NEMF). This field keeps everything in sync so that you feel healthy and balanced.
2/25/20253 min read
Negative Emotions (Stress):
When you experience stress or negative emotions, the NEMF spins faster in a counterclockwise direction. Think of it like a misfiring conductor; the energy of the field drops and becomes unbalanced. This energy loss can cause one of your organs—often the one that’s genetically weaker—to slow down, leading to pain, chronic diseases, or even cancer.Positive Emotions:
On the flip side, positive emotions make the NEMF spin clockwise. This spinning boosts the field’s energy and helps restore balance, much like a well-coordinated orchestra playing a beautiful symphony.
How It Works
A Russian scientist named Shkatov used a device called a “torsemeter” to measure the spinning of this field. His findings were clear:
Counterclockwise spinning (from negative emotions) leads to energy loss and imbalance.
Clockwise spinning (from positive emotions) helps you feel healthier by increasing energy and balance.
Using principles from nonlinear physics, the study explains that each negative emotion has a stronger impact on your body’s energy. In fact, it might take about three to four positive emotions to counterbalance just one negative emotion.
Key Takeaway
Taking care of your emotional well-being isn’t just about feeling good—it might actually protect your body from chronic illnesses. By nurturing positive thoughts and reducing stress, you help maintain the harmonious “music” of your body, keeping everything in sync and promoting overall health.
This engaging perspective shows that our emotions could play a direct role in our physical health, suggesting that a little positivity can go a long way toward keeping you well.
In the realm of unconventional science, the exploration of torsion fields has captivated researchers seeking to understand the deeper layers of physical reality. One notable figure in this field is V.T. Shkatov, whose work has significantly advanced our comprehension of torsion fields and their potential applications.
Understanding Torsion Fields
Torsion fields, also known as spinor fields, are theoretical constructs that arise from the spin of particles in quantum physics. Unlike electromagnetic fields, which are generated by electric charge, torsion fields are produced by the spin angular momentum of particles. These fields are hypothesized to transmit information instantaneously across vast distances, a concept that challenges traditional understandings of space and time.
Shkatov's Pioneering Research
V.T. Shkatov has been at the forefront of experimental research into torsion fields. Collaborating with V. Zamsha, Shkatov developed innovative methods to detect and measure these elusive fields. One such approach involves the use of photodiodes to measure dark current as a means of detecting torsion fields. In this method, a sealed photodiode, shielded from light and electromagnetic interference, is monitored for variations in dark current, which are believed to correspond to the presence of torsion fields. This technique has opened new avenues for understanding non-electromagnetic interactions in physical systems.
Applications and Implications
The potential applications of torsion field research are vast and varied. One intriguing possibility is in the realm of communication. Shkatov and Zamsha have proposed that torsion fields could facilitate instantaneous information transfer, a concept that could revolutionize our approach to interstellar communication. This idea is based on the phenomenon where photo images from a single source can "sense" each other through their auras across the universe, suggesting a medium for communication that transcends the limitations of light speed.
Challenges and Controversies
Despite the promising avenues of research, the study of torsion fields is not without controversy. The scientific community remains divided, with some researchers questioning the reproducibility and theoretical foundations of torsion field experiments. Critics argue that more rigorous methodologies and peer-reviewed studies are necessary to substantiate the claims made in this field.
Conclusion
V.T. Shkatov's contributions to the study of torsion fields have undeniably pushed the boundaries of conventional physics. His innovative approaches and experimental techniques offer a glimpse into a realm of science that challenges our fundamental understanding of the universe. As research continues, the exploration of torsion fields may unlock new technologies and insights, transforming the way we perceive and interact with the cosmos.