CAN YOUR HEART’S ENERGY CHANGE THE WORLD?

By Rose Caiola |  originally published here on RewireMe.com

Helen Keller once wrote, “The best and most beautiful things in the world cannot be seen nor even touched, but just felt in the heart.” Her words have always rung true for me but have grown in meaning as I’ve been become more aware of and interested in the scientific research emerging about heart intelligence. Heart intelligence, as defined by the Institute of HeartMath, is “the flow of awareness, understanding, and intuition we experience when the mind and emotions are brought into coherent alignment with the heart.”

So when I came across this from HeartMath, I was immediately intrigued.

The Heart’s Intuitive Intelligence: A path to personal, social and global coherence

Most of us know what it’s like to experience a state of flow or harmony, when our emotions and our brains are in sync—it can happen when we’re holding a new baby or falling in love. This is what HeartMath calls coherence. The idea of coherence suggests that we can take control of the relationship between our hearts and our brains. At first, it may seem like the idea of accessing your heart’s energy is a little otherworldly (or as I like to say, woo-woo) but HeartMath’s documented scientific research demonstrates that it’s not as strange as you might think.

Here are the most interesting pieces of information I picked up from the video and plan to keep in mind during my own journey to heart coherence:

  1. When we are in a coherent state, the heart and brain operate synergistically. We can learn how to improve and actively control this synergy to both prevent stress-producing emotions and enhance our mental clarity.
  2. When we’re in control of our synergy, we are more likely to face our challenges in a creative and intuitive way.
  3. Accessing our heart’s intuitive intelligence can make us better communicators and decision-makers.
  4. When we experience genuine feelings like appreciation and compassion, our heart coherence increases.
  5. According to HeartMath research, when we are in a state of coherence, our heart radiates a more coherent electromagnetic energy field and this can have an impact on other people, animals, and the environment!
  6. The Global Coherence Initiative is in the process of placing 14 sensors around the world to measure the Earth’s magnetic resonance. This research will help scientists determine whether there is a connection between the planet’s magnetic field and human emotions.

The biggest lesson I learned from the video is how, if we all take responsibility for the energy we project by becoming more conscious of our thoughts, feelings, and attitudes, it may be possible to increase global coherence and eventually sustainable peace. What an amazing possibility.

What do you think? Do you believe that your heart intelligence could make a positive change in the people around you or even in the world?

Rose Caiola

Inspired. Rewired.

Scientists have confirmed a brand new phase of matter: time crystals.

FIONA MACDONALD  |  28 JAN 2017

originally published here in Science Alert

 

Constant motion without energy.

For months now, there’s been speculation that researchers might have finally created time crystals – strange crystals that have an atomic structure that repeats not just in space, but in time, putting them in constant oscillation without energy.

Now it’s official – researchers have just reported in detail how to make and measure these bizarre crystals. And two independent teams of scientists claim they’ve actually created time crystals in the lab based off this blueprint, confirming the existence of an entirely new phase of matter.

The discovery might sound pretty abstract, but it heralds in a whole new era in physics – for decades we’ve been studying matter that’s defined as being ‘in equilibrium’, such as metals and insulators.

But it’s been predicted that there are many more strange types of matter out there in the Universe that aren’t in equilibrium that we haven’t even begun to look into, including time crystals. And now we know they’re real.

The fact that we now have the first example of non-equilibrium matter could lead to breakthroughs in our understanding of the world around us, as well as new technology such as quantum computing.

“This is a new phase of matter, period, but it is also really cool because it is one of the first examples of non-equilibrium matter,” said lead researcher Norman Yao from the University of California, Berkeley.

“For the last half-century, we have been exploring equilibrium matter, like metals and insulators. We are just now starting to explore a whole new landscape of non-equilibrium matter.”

Let’s take a step back for a second, because the concept of time crystals has been floating around for a few years now.

First predicted by Nobel-Prize winning theoretical physicist Frank Wilczek back in 2012, time crystals are structures that appear to have movement even at their lowest energy state, known as a ground state.

Usually when a material is in ground state, also known as the zero-point energy of a system, it means movement should theoretically be impossible, because that would require it to expend energy.

But Wilczek predicted that this might not actually be the case for time crystals.

Normal crystals have an atomic structure that repeats in space – just like the carbon lattice of a diamond. But, just like a ruby or a diamond, they’re motionless because they’re in equilibrium in their ground state.

But time crystals have a structure that repeats in time, not just in space. And it keep oscillating in its ground state.

Imagine it like jelly – when you tap it, it repeatedly jiggles. The same thing happens in time crystals, but the big difference here is that the motion occurs without any energy.

A time crystal is like constantly oscillating jelly in its natural, ground state, and that’s what makes it a whole new phase of matter – non-equilibrium matter. It’s incapable of sitting still.

But it’s one thing to predict these time crystals exist, it’s another entirely to make them, which is where the new study comes in.

Yao and his team have now come up with a detailed blueprint that describes exactly how to make and measure the properties of a time crystal, and even predict what the various phases surrounding the time crystals should be – which means they’ve mapped out the equivalent of the solid, liquid, and gas phases for the new phase of matter.

Published in Physical Review Letters, Yao calls the paper “the bridge between the theoretical idea and the experimental implementation”.

And it’s not just speculation, either. Based on Yao’s blueprint, two independent teams – one from the University of Maryland and one from Harvard – have now followed the instructions to create their own time crystals.

Both of these developments were announced at the end of last year on the pre-print site arXiv.org (here and here), and have been submitted for publication in peer-reviewed journals. Yao is a co-author on both articles.

While we’re waiting for the papers to be published, we need to be skeptical about the two claims. But the fact that two separate teams have used the same blueprint to make time crystals out of vastly different systems is promising.

The University of Maryland’s time crystals were created by taking a conga line of 10 ytterbium ions, all with entangled electron spins.

Chris Monroe, University of Maryland

The key to turning that set-up into a time crystal was to keep the ions out of equilibrium, and to do that the researchers alternately hit them with two lasers. One laser created a magnetic field and the second laser partially flipped the spins of the atoms.

Because the spins of all the atoms were entangled, the atoms settled into a stable, repetitive pattern of spin flipping that defines a crystal.

That was normal enough, but to become a time crystal, the system had to break time symmetry. And observing the ytterbium atom conga line, the researchers noticed it was doing something odd.

The two lasers that were periodically nudging the ytterbium atoms were producing a repetition in the system at twice the period of the nudges, something that couldn’t occur in a normal system.

“Wouldn’t it be super weird if you jiggled the Jell-O and found that somehow it responded at a different period?” said Yao.

“But that is the essence of the time crystal. You have some periodic driver that has a period ‘T’, but the system somehow synchronises so that you observe the system oscillating with a period that is larger than ‘T’.”

Under different magnetic fields and laser pulsing, the time crystal would then change phase, just like an ice cube melting.

Norman Yao, UC Berkeley

The Harvard time crystal was different. The researchers set it up using densely packed nitrogen vacancy centres in diamonds, but with the same result.

“Such similar results achieved in two wildly disparate systems underscore that time crystals are a broad new phase of matter, not simply a curiosity relegated to small or narrowly specific systems,” explained Phil Richerme from Indiana University, who wasn’t involved in the study, in a perspective piece accompanying the paper.

“Observation of the discrete time crystal… confirms that symmetry breaking can occur in essentially all natural realms, and clears the way to several new avenues of research.”

Yao’s blueprint has been published in Physical Review Lettersand you can see the Harvard time crystal paper here, and the University of Maryland paper here.

Update 31 January 2017: We had previously compared the constant oscillation of the time crystals as being in perpetual motion at ground state, which isn’t accurate. We’ve now corrected this explanation.