Yes. You would also have exactly the same experience
if you moved toward the south pole instead.
If one end the Earth's axis always pointed toward the sun, then one pole would ALWAYS be in daylight, and the other pole would NEVER see daylight. Which is which would depend on which end of the axis pointed toward the sun. The Earth's "poles" are the ends of its axis of rotation. It's not possible for either end of the axis to point toward the equator or toward my latitude.
The earth is hotter at its core and cooler as we look farther out. As regards the surface of the planet, it is warmer at the equator, and cooler toward and at the poles. There will be some slight variation owing to seasonal changes, but that is the basic answer.
A tropical cyclone, (i.e. a hurricane or typhoon) could not cross the equator. All cyclones depend on the Coriolis force in order to spin. The Coriolis force is greatest at the poles and nonexistent at the equator. A tropical cyclone that approaches the equator would likely degenerate into a disorganized cluster of thunderstorms. Such an event would be unusual in any case as the general wind pattern tends to steer tropical cyclones away from the equator rather than toward it.
You would need to travel toward the south to reach the equator. Because Dallas is in the Northern Hemisphere not the southern hemisphere. BTW the Northern Hemisphere is the upper half of the earth. The Southern Hemisphere is the lower part of the earth.
I would have to say aluminum foil, since radiation can travel through glass. radiation is reflected from the surface of aluminum foil. With a mirror the radiation has to travel through a small layer of glass twice before the mirror is finished with it. Glass is not totally transparent, some light is absorbed so the naked aluminum reflects better.
Radiation? You don't get radiation flying!
If you mean straight down, you would be near the equator.
NONE
Because at the equator, radiation from the sun strikes the earth head on. So if the sun had a heating effect of 1W/m3 (not accurate), every square metre on the equator would get 1W. However, at the poles of the earth, sunlight strikes at an angle. As a result, the 1W of heat would be spread over a larger area. As a result, the poles receive less heat energy and are colder than the equator.
If one end the Earth's axis always pointed toward the sun, then one pole would ALWAYS be in daylight, and the other pole would NEVER see daylight. Which is which would depend on which end of the axis pointed toward the sun. The Earth's "poles" are the ends of its axis of rotation. It's not possible for either end of the axis to point toward the equator or toward my latitude.
The amount of radiation you get from flying is low and considered safe. The level of radiation exposure during a typical flight is similar to what you would receive from a chest X-ray.
Radiation treatment is a treatment to treat people with various different forms of cancer that uses high energy ray to destroy or slow down the growth of cancer cells and as you would expect the place to receive radiation treatment would be under the care of health care professional in a dedicated oncology ward or hospital
The earth is hotter at its core and cooler as we look farther out. As regards the surface of the planet, it is warmer at the equator, and cooler toward and at the poles. There will be some slight variation owing to seasonal changes, but that is the basic answer.
The polar regions will receive less radiation. The amount of solar radiation that impacts a particular area of the Earth is proportional to the cosine of the angle between the normal of the surface area and the incoming "ray" of radiation. So if the axial tilt was 0 then the angle of the solar radiation would be 90 degrees, the cosine of 90 is 0. At 10 degree tilt there will be an increase of ice, snow and glaciation due less solar radiation in summer.
Without Earth's rotation, the air at the equator would move from high to low pressure in a straight line towards the poles. This is because air moves from areas of high pressure to areas of low pressure, creating a simple north-south airflow pattern.
If we are talking about solar heating it warms mostly the equator. If we are talking about actual radiation we are least protected from it at the North and South pole. So even though the radiation itself may not be directed at the poles that is where a person would experience it the most.
A tropical cyclone, (i.e. a hurricane or typhoon) could not cross the equator. All cyclones depend on the Coriolis force in order to spin. The Coriolis force is greatest at the poles and nonexistent at the equator. A tropical cyclone that approaches the equator would likely degenerate into a disorganized cluster of thunderstorms. Such an event would be unusual in any case as the general wind pattern tends to steer tropical cyclones away from the equator rather than toward it.