Earth and the solar wind. | Credit: NASA/GSFC
There’s a nuclear fusion reactor in the neighborhood that weighs 300,000 times more than Earth. It’s eight minutes away at the speed of light, has 99.8% of the mass of the solar system, and surrounds us with changing magnetic and electric fields while it rains down charged particles. Some years the Sun throws ten times as much extreme-UV our way as it does in other years. Virtually none of this is included in mainstream climate models.
The constant wind of charged particles blows at a million miles an hour — the flow waves and wiggles, shifting direction. The speed of the solar wind correlates with sea surface temperatures in the Atlantic. The solar magnetic field reaches right to the edge of the solar system, but despite that size, it turns itself completely upside down every 11 years. Reconnecting magnetic field lines cause explosions in space, and we have barely started to collect data on this. During the magnetic cycle the sun changes color, though the changes are invisible to us. The spectrum rolls from more UV to […]
It’s always the same. A new paper adds one more magical fine-tuning-cog to the models and promises “more accurate predictions”. There are a million small cogs we can add and it takes years to show they don’t deliver. These wheels can spin forever. The real climate machine has a whole extra exhaust pipe to which the models are blind.
Why some climate processes are more effective at warming Earth
Conventional models assume increasing atmospheric CO2 warms the surface, then apply the feedbacks to the surface warming. But if feedbacks start up in the atmosphere instead, everything changes.
The assumption (bolded below) is the problem —
There are many processes which affect the surface climate: changes to the sun’s activity, to the cloud cover, precipitation patterns, or soil water content to name just a few. Currently climate scientists relate these processes by looking at how much they change the energy budget, described by perturbations in the radiative forcing. The existing assumption is that if a given process introduces a certain radiative forcing, then there will always be the same response in the surface air temperature. However, this assumption doesn’t hold for the temperature response […]
Is Force X two different forces? The Sun could influence Earths climate through magnetic fields, solar particle flows, or spectral changes. | Image: ESA
There are two key clues, almost contradicting each other, which we must solve to figure out what Force X is. How do we explain that mysterious pattern — the little spike of extra sunlight each sunspot cycle doesn’t warm the Earth as it arrives — and it should. Instead, the warming appears greatly amplified 11 years later (or one sunspot cycle later). What’s going on? Logically the sunlight itself is not the direct cause, but only a signal, a leading indicator of something else going on — perhaps the solar wind, the magnetic fluxes, or the changes in the UV-Infra Red spectrum. Any one of these (or all of them) or maddeningly, even something else, could be influencing cloud cover on Earth — and some action on clouds is by far the most likely mechanism to amplify the solar effect. They blanket 60% of Earth, and small changes make large differences. We live on a Water-Planet. So having looked at the reasons for Force X, we now split it into two different forces (N and […]
What is Force x? The Sun could influence Earths climate through magnetic fields, solar particle flows, or spectral changes. | Image: ESA
What’s going on with the Sun?
In the last post in the climate research series we described David’s major finding that changes in total sunlight lead Earth’s temperature by one sunspot cycle. But what’s going on with the Sun — what is the mechanism? In this post David lays out four puzzling clues about solar influence on our global temperature, then puts forward a hypothesis. What force (or forces) are required to resolve all these odd points?
To recap: Both his Fourier analysis and many independent papers suggest there is a delay between total solar irradiation (TSI) and global temperature. David reasoned that the delay is a true delay, not just a smoothing effect while increased heat propagates around the planet. Because the timing is so tied to solar cycles, the trigger for the delay must start on the Sun, not on the Earth. This is not just a case of our oceans slowly absorbing the extra energy from the Sun — and there simply isn’t enough, in any case. Something quite different […]
We’re launching headlong back into the New Science series with a major post
Lots of things will fall into place — as befits a potential paradigm step forward. For decades, people have been looking to see if the Sun controlled our climate but the message was perplexingly muddy. In the long run, solar activity appears linked to surface temperatures on Earth. (Solar activity was at a record high during the second half of the 20th century when temperatures were also high.) But when we look closely, firstly the solar peaks don’t exactly coincide with the surface temperature peaks, and secondly, the extra energy supplied during the solar peaks is far too small to do much warming. So how could changes in surface temperature be due to the Sun?
A few researchers noted an esoteric correlation of long solar cycles with lower temperatures in the next solar cycle, but mostly those papers were left on the shelf, ignored. Dr David Evans’ notch-delay solar delay theory can explain this odd pattern.
To unravel the connections David took a new approach which cleared out the dead-end complexity of the current climate research. Instead of trying to predict everything from a bottom […]