Jheri tagged me to a challenge making its way around:
Tell me something amazing about your field in a sentence and then spend five or ten minutes on something that isn't well known.
It's probably meant to be a video chat challenge, but I'll write and go with astrophysics. You might want to try this for your own field or maybe a passion.
It takes more energy to melt a snowflake than all of the energy received by all of the radio telescopes on Earth since they were invented in 1932.
Now for something that would take about five minutes to talk about. Something most people don't know about black holes using nothing more than a bit of first semester high school physics and your imagination. (If you don't remember much of that you can skip to the last paragraph.)
Let's say you have a rocket and want to escape the Earth's gravity - really escape rather than go into orbit. There are two energies to consider. The energy of motion of your rocket - its kinetic energy, and the energy from the gravitational attraction between your rocket and the Earth - the gravitational potential energy.
The kinetic energy is just 1/2 mv2, where m is the mass of the rocket and v is its velocity. The gravitational potential energy is -GMm/r where G is the gravitation constant, M is the mass of the Earth, r is the radius of the Earth (the distance from the center of the Earth to the surface where you launch the rocket from), and m is the mass of your rocket.1 So the total energy is
E = 1/2 mv2 - GMm/r
If you keep increasing the velocity you get to a point where E becomes is no longer negative. When that happens you've escape Earth's gravity. The escape velocity is when the kinetic energy equals the gravitational potential energy. Setting them equal and a bit of algebra we get.
v2 = 2GM/r about 11.2 kilometers per second for Earth.
You probably saw this in your physics class and are probably wondering what this Newtonian result has to do with black holes. This is where it gets interesting.
About a century after Newton figured this out an English cleric named John Michell wondered what would happen if you kept increasing the mass M. He knew the speed of light was large, but not infinite. If you were on a body that was massive enough there was a point where the escape velocity would be greater than the speed of light! People didn't know the speed of light was constant or that light could be influenced by a mass, but Michell had discovered idea of a black hole in 1784. Remarkably the result is within a factor of two of the value you get using General Relativity.
Let's play around a bit. c2 = 2GM/r is the classical escape velocity for light. Rearrange to get (on the path to something interesting)
M/r = c2/2G
Now consider the density (we're getting close to the fun bit!). The mass of an object is proportional to its density times its volume or M ~ ρ r3 (ρ is the density). Now substitute in and solve for density
ρ ~ c2/2Gr2
You're probably used to thinking of a black hole as an incredibly dense object. But density falls as the square of the radius of the black hole. So as black holes get bigger the density you need gets smaller! A black hole with the mass of the Sun has a radius of about 3 kilometers and is extremely dense. The supermassive black hole at the center of M87 that was imaged about a year ago has a diameter roughly four times that of Neptune's orbit - what we usually think of as our Solar System would easily fit inside - but its density is a bit less than that of water!
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1 The negative sign is from the convention that the Earth has no influence over the rocket at an infinite distance. The negative potential means the rocket is bound to the planet. It's trapped until it has enough energy to escape.
a covid-19 recovery story and psa
A departure from the norm - something worth the read and potentially useful.
This is from an old Bell Labs colleague .. the story of how they helped his 89yr old stepfather in Brooklyn. This is no substitute for real medical advise, but might give a sense of reasonable supporting steps. Pulse oximeters are cheap ($25 to $50) and a good way to check your blood oxygenation level. Finding an oxygen concentrator would be a big challenge these days. If you see low reading early on it may be possible to take early steps and this may be increasingly useful information as more is learned about treatment.
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Sharing a miracle! My 89 year old stepfather Richard, was saved by love, science, creativity, and courage. He tested COVID-19 positive on March 19, with fever, fatigue, and a cough, followed by weeks of extreme exhaustion, spiking fever, and bacterial pneumonia. Now he’s been fever free for ten+ days and is gaining strength daily.
This was a miracle not only because COVID-19 can be so dangerous for any of us but even more so based on his age (he is almost 90!) combined with multiple underlying conditions. We are so grateful to see Richard on a path to recovery now; our goal for this post is to share what we did and what we learned with a goal to help others battling COVID-19.
Below are more than a dozen actions that were taken as an extended family to help Richard fight the virus at home, avoiding the need to go to hospital:
1. Pulse oximeter: we purchased an inexpensive ($25) but essential device in the home to measure blood oxygen levels. Levels need to stay above 90 otherwise a doctor should be consulted; measurements are taken multiple times a day, in tandem with temperature checks.
2. Oxygen concentrator: Richard’s doctor prescribed an oxygen concentrator because his blood oxygen levels were in the 80s. A portable, lightweight, battery powered, multi flow oxygen concentrator (Inogen device) was acquired for him as a result. Think of this as an practical in-home option between normal breathing and a hospital ventilator; it can be used in conjunction with the oximeter for measurement and can be covered by insurance/Medicare, if prescribed by a doctor.
3. Respiratory therapist: A respiratory therapist came to the home to demonstrate how to use the oxygen concentrator; this visit was included as part of receiving the oxygen device.
4. Crowd sourced masks, gloves, and hand sanitizer: hitting roadblocks at pharmacies and online sites, we received a heartwarming response from family, friends, and extended networks sending home made masks, gloves, and hand sanitizer from all over the country.
5. Simulated hospital environment: knowing the severe challenges at NYC hospitals in COVID-19 wards, we did everything we could to keep Richard at home, effectively creating a simulated hospital environment but with the comfort and care of being at home with a loved one.
6. CDC home protocol: my mother followed CDC home protocols for disinfecting and mask usage, ensuring her own safety and physical health, critical for a sustained role operating 24 x 7.
7. Virus warrior mindset: the battle at times was as much psychological as it was physical, and my Mom and Richard were champs of the highest order, mustering extraordinary emotional strength at times to keep going when darkness was pervasive.
8. Breathing and movement exercises: Richard’s doctors recommended a set of breathing, stretching, and walking exercises which he did three times a day. In the beginning it was daunting; over time, he was able to steadily increase the number of repetitions.
9. Virtual Urgent Care: we arranged for my mother to have a virtual urgent care visit, using an iPhone app with video streaming to consult with a doctor on her own health.
10. Real World Urgent Care: we finally found an Urgent Care facility in Brooklyn that would treat COVID-19 patients and had an x-ray machine, after trying more than ten different options at the time; many facilities were closed or refused any one with COVID-19. They did a blood test and a chest x-ray using remote radiologists to read the scans, confirming the bacterial pneumonia diagnosis and prescribing antibiotics (see below); this was much easier than visiting an emergency room at a hospital and a key bridge towards recovery.
11. Nurse/home health aide: we worked with a firm that specializes in home care for COVID-19 patients to bring in an experienced nurse/home health aide at a critical time, to help out for three days in a row.
12. Food and pharmacy delivery, and car services: Family members brought chicken soup to the front door. Delivery services brought food to make it practical to stay in. We had to try more than a dozen car services until one was found that agreed to take COVID-19 patients. A local pharmacy delivered supplies to the home.
13. Hydration and electrolytes: Throughout the height of the virus, Richard had little to no appetite. The doctor impressed upon us how critical it was to drink lots of fluids complemented by drinks with electrolytes such as Gatorade and Pedialyte. For nourishment, a drink such as Ensure can be helpful; for those with diabetes, Glucerna is an easy way to support nourishment.
14. Dual track antibiotics: A combination of Azithromycin and Cefdinir, running for ten days, was effective to battle his bacterial pneumonia. The use of these antibiotics was a key turning point in his recovery. However with viral pneumonia this approach may not be applicable. Note that early on hydroxychloroquine was ruled out due to cardiac risks and limited testing.
We hope that this summary of the approach that we took was useful and can help others battle COVID-19 in the broader war to fight this powerful virus and return to normalcy over time. It’s worth noting that love and care from immediate and extended family, along with friends and colleagues, played a critical role to aid recovery; although this can only go so far with respect to the real world ravages and harsh statistics of this disease, don’t underestimate the role love and care can play in this type of miracle, complemented by the application of science, creativity, and courage.
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