Oh man, there's a great opportunity for a part 2 of this conversation. Sub-3 second cars have almost become common, especially with electric cars, and not on prepared surfaces either. The McMurtry and the variable speed fan system is particularly interesting, along with other cars that depend on the venturi effect. In this episode, they barely touched on the impact of active and passive aero. Deceleration is also a fun topic, as there are many cars with active aero tricks there. Then there's the benefits of driving 2 wheels versus 4 in achieving the maximum grip on launch, the complicated launch systems and procedures sports cars have now, and treaded vs slick tires increasing contact patch with the surface. So much to continue this conversation!

To be honest I initially didn't like Chuck cracking jokes while Neil deGrasse Tyson was explaining something, but now I can't even watch a single episode without him . 🙌

I'm gonna demand that Chuck Nice be on with every special guest episode 💯

At one point in history of F1, the cars actually accelerated faster from 100 km/h to 200 km/h, than 0-100 mark. It was incredibly difficult to not spin the wheels from 0-100 and subsequently loose time

What I really love about Neil is that _consistently_ his lead-up communication is so good that, once he reaches his main point, it seems like an obvious thing I just never thought about before. "Well, _of course,_ maximum acceleration is 1G; beyond that, you lose traction because the wheels are spinning faster that gravity is pulling you down. DUH!"

The McMurtry Spéirling does 0-60 in 1.4 seconds thanks to a system of fans that push the car into the road.

Three cars that are sub 2 second Rimac Nevera - 1.85 seconds (0-60mph) Lucid Air Sapphire - 1.89 seconds (0-60mph) Pininfarina Battista - 1.9 seconds (0-62mph)

Would love to see Neil and the boys interview a F1 driver or engineer 😊

Some production cars can achieve sub 3s 0-60 (or over 1G acceleration), because they utilize similar tricks that the top fuel dragsters do - they temporarily increase the stickiness of the tires. The road surface is never completely flat - it is rough with small imperfections, acting a bit like a gear rack. And the tire is deformed and pushed down by the weight transfer of the car and some clever suspension, so that it acts a bit like that pinion gear at the gear rack. So the friction coefficient is a bit greater than 1. All of this was also mentioned in the video. However those cars are pushing the usability limit and it cannot get much quicker than that. We know that dragsters can achieve much more than 1G acceleration, but no one actually wants to be driving a dragster on the street.

Check out Gordon Murray's T.33 and T.50 based on the Brabham BT46B F1 car in 1978 which has a fan on the car's rear. This fan extracts air from underneath the car, producing heaps of downforce while it's at a standstill, and of course adding to the downforce as the car accellerates. The original car in 1978 was disqualified after only one race and if I recall it was an entire 6 seconds faster per lap than its competitors.

Even with tires spinning it's achievable. There are people that do "hard tire" drag racing on non prepped surfaces that still see above 1g and sub 3 second 0-60 times even without sticky tires digging into the surface. Weight tranfer and suspension setup are huge factors with most of those guys being able to accelerate like that without much traction.

I think we need a follow up video to explain the accel and decel times that seem to beat the rule. Rimac and Tesla for example on Matt Watson's channel CarWow are pulling greater than 1G. We are dying here in the comment section for a Tyson explanation. (Oh, and one more thing...I was hoping you were going to mention the fan cars that suck the car to the ground to gain huge traction while not increasing the mass).

Gary, you nailed the NHRA model... those 11,000 HP Top Fuel dragsters (with the T-Rex fron t wheels) pull up to 5 G's on launch, due to the super sticky slick tires and the burnout warming the aforementioned tires up to increase traction to the point of insane.

Just a couple of minutes into this and looking at comments too and I noticed something that it doesn't appear many people have much knowledge about. Instant center and anti squat, it's what allows dragsters to accelerate like they do, pro stock drag cars to accelerate like they do, and semi trucks to accelerate like they do (also comes into play on everyday vehicles just not as much effect) instant center is the point the rear axle (in a rwd vehicle) is lifting on the front of the vehicle ( it's the rotation about the center of the rear axle and the point it is being lifted at) and anti squat is a part of the geometry related to how the rear suspension reacts, if it has anti squat built into the geometry it means that instead of the rear of the vehicle "squatting" when it accelerates under power it actually stands up and pushes the rear tires into the ground harder. Add in adjustments to instant center and you can increase the amount of weight that is actually applied down into the ground on the rear tires which increases the contact patch of the rear tires which increases the amount of force needed to break the traction between the tires and the road surface... some of that may be included in the "Engineering the world's fastest cars" video I'm going to watch right after this

Actually... Rimac Nevera - 1.85 seconds (0-60mph) Lucid Air Sapphire - 1.89 seconds (0-60mph) Pininfarina Battista - 1.9 seconds (0-62mph) Tesla Model S Plaid - 2.3 seconds (0-60mph)

Automotive literature typically runs with a “roll out”. This is why the general public believes 3 second 0-60 is commonplace these days.

I’m not an expert but I’d say the mentioned limit of 0-60 in 3 seconds accounts for a constant amount of torque (i.e. throttle). Modern cars, especially electric cars, have launch systems that allow an increased torque output as speed on the way to 60 increases, allowing the other forces other than friction to go into effect and increase the rate at which a car can accelerate.

Terminal velocity is a fascinating concept in physics, describing the maximum speed an object can reach when falling through a fluid, such as air. It occurs when the force of gravity is balanced by the drag force, causing the object to fall at a constant speed. This equilibrium creates a unique dynamic where heavier objects can have different terminal velocities compared to lighter ones. But what factors exactly determine how quickly an object reaches its terminal velocity, and how can we manipulate these factors in practical applications like skydiving or engineering?

Great video!! Many car manufacturers use “rollout” to achieve a quicker 0-60/62 time for their spec sheet. They don’t start timing until the car is already in motion. The channel, “Engineering Explained,” has a good video demonstrating this as well as factors limiting a cars quickness. With equations 😊

Top fuel NHRA drag racing is the perfect balance of acceleration and traction (friction), the vehicles are designed for the maximum amount of downward force on the rear wheels that get heated up and become sticky in the pre-race burnout

I was suprised when Neal didn't include all wheel drive into the discussion, especially when snow plowing was mentioned. Having four drive tires vs 2 increases the coefficient of friction substantially which with current technology does allow several current production vehicles to easily surpass the 3 second 0-60 "barrier". Tesla plaid and Porsche 911 turbo are 2 examples

4m 20s No, Neil, they do NOT scale EXACTLY together! When speaking about the surfaces, both road and tire, the limit to force the flexible tire into the road surface is limited. there is a point that more weight does not benefit increase Increasing the surface mating area, the contact patch increases the ability to accelerate. the material of the tire will sheer away at a given, calculable point. this can be written in force per millimeter, centimeter, square inch, etc... The weight can be shifted, by design, without increasing the vehicle's weight. then again, you are not taking into account that the speed at which a tire rotates, adds to the amount of material of the tire that interlocks with the road surface. Tires actually provide their maximum forward acceleration, cornering and braking with a certain amount of slip (in some cases @7%). BTW, Neil, Skidding out is NOT the proper term for the loss of traction in acceleration, but in deceleration (stopping, negative acceleration). The contact patch cannot generate enough friction to slow the vehicle as much as the brakes and energy (vehicle mass*forward motion) require. I just described a skid. Skidding out is the loss of trajectory due to a skid. A burnout, as your buddy said, is correct, That doctorate does not mean that you know it all and your inability to even research the proper terminology would have caused you to never have received your doctorate, as you think you are speaking about one thing, while actually speaking about another.

You need to look into the McMurtry Speedster & The T50. Both have fans in the underbody that increase downforce significantly. Mind bending to watch these tech’s effect on a car.

The keywords are "tires digging into the road". The same arguments were proposed by physicists in the 60's, that dragsters will not get below about 9 seconds in the 1/4 mile, because that's about 1G of acceleration. But that's because they took a too simplistic view of friction and reduced the concept of friction to a single number; a coefficient. "Friction" is actually the interference between the microscopic structures of two surfaces in contact with each other. To break friction, the surfaces must shear off their microscopic structures. Similarly, tire traction is due to the soft rubber flowing into the crevices in the pavement, providing grip (adhesion). Take this to the extreme, end you end up with the gears and rack teeth embedded in the ground that Dr. Tyson mentioned, and the limit of acceleration would be the strength of the teeth. This is why the dragsters use huge tires; to put more rubber against the pavement for more strength (cohesion). Also, the tire treads need to be soft, but not necessarily "sticky", as that means it will take energy to peel the backside of the tread off the pavement.

What I wouldn't do to be in a class that Neil DeGrasse Tyson taught. Thank you for arming your viewers with interesting and practical knowledge. I didn't know that physics could actually be fun.

Let's just say that at sea level the acceleration of gravity is 32.174 ft/sec^2. That means in order to accelerate at greater than the rate of acceleration of gravity you have to increase the speed of the car (in a straight line) at a rate greater than 32.174 ft/sec per second, which is 21.94 MPH per second. So accelerating a car from 0 MPH to 60 MPH at the acceleration rate of gravity would take 2.73 seconds. There are PLENTY of vehicles on the road that can accelerate from 0-60 MPH in less than 2.73 seconds. I used to own a Kawasaki ZX-11 that would do 0-60 in 2.7 seconds, and that was stock off the showroom floor, on stock tires.

Sorry, but you can play with control arm angles and shock rebound settings to throw the tires into the ground when you hit it (lots more normal force). You can find video of slicks deforming and squatting down, while the back raises up. Then you need to make sure the suspension unloads slowly enough or you'll do a wheely then spin. You might like the science behind it. Lots of geometry. Kevin Wilson does a lot of KZbin explainers on suspension.

@5:51 🤔The statement "The fastest you can accelerate forward is 1g" is in fact incorrect. A simple thought experiment is all that is needed to intuitively realize this. If we examine the tribology of the contact surfaces, i.e., where rubber meets road, we realise that the limiting factor to road "grip" is the ablation of our tire compounds. Therefore, if we were to replace our road and tire with a rack and pinion system, we can be confident that the limiting factor to acceleration becomes inertia, engine (or motor) power, and drag. A real life counterargument to the assertion @5:51 is the McMurtry Speirling, an all-battery electric race car. The McMurtry Speirling can sprint from 0-60mph in 1.4 seconds and cover the quarter mile in 7.97 seconds. The quarter mile is about 400m. From kinematic physics, (distance) = (1/2)*(acceleration)*(time^2). We can rearrange the equation to get (acceleration) = (2)*(distance)/(time^2) = (2*400m)/(7.97^2 s^2) = 12.6m/s^2. Gravity on earth is generally approximated as 9.8m/s^2, so the McMurtry is pulling 12.6/9.8 = 1.3g.😳 Yes, the McMurtry is a fan-car (it uses a powerful fan to create a suction force of almost 2 metric tonnes). This suction force increases the apparent weight of the car. Friction force is just apparent weight x coefficient of friction. The higher the friction force, the higher the potential acceleration, if the motors are up to the task, which they clearly are for the McMurtry Speirling. It gets even crazier though, because the McMurtry actually has a 150mph speed governor. Back to our ballistics equation, (velocity) = (acceleration)*(time), which we can rearrange to get (acceleration) = (velocity)/(time). 60mph is 26.8m/s, so (acceleration) = (26.8m/s)/(1.4s) = 19.1m/s^2. Again, on earth, gravity is generally approximated as 9.8m/s^2, so the McMurtry is capable of (19.1m/s^2)/(9.8m/s^2) ~2g!!!!!!!!🤯😂

You guys need to attend a National Hot Rod Assoc NHRA race sometime and watch the nitro-fueled drag races hit 300+ mph in a 1,000ft!! Then, the next problem is stopping the thing.....Come to Sonoma Raceway in July for the NHRA races and I'll meet ya there...

These 3 men have never seen the McMurty. They figured out how to create downforce from 0. And the Lucid Air Sapphire can turn it's motors on and off 1,000 times per second. It just beat the Tesla Plaid by 3 car lengths in the 1/4 mile.

I love you guys! 🙌 There’s plenty of mass produced cars that can do 0-60mph in less than 3 secs from stand still (no roll out) and with good but mainstream roadworthy tires on normal asphalt/concrete roads at let’s say normal temps at around 20 degr. C

There's no such thing as too much horsepower, just not enough traction - Carol Shelby

Another way of saying what professor Tyson is saying here is the old rule that a car can never accelerate faster than it can decelerate. That is no longer the case. Using various means manufacturers have found ways to accelerate faster than 1G and to decelerate faster than 1G. "According to calculations based on MotorTrend's data, it turns out that in the case of Plaid, the acceleration was 1.199g on average, while braking was at 1.156g on average."

But the mcmurtry spéirling did 0-60 in 2.09 seconds. But it did use fans to literally suck it to the ground. So he is still correct.

Great video Neil! What about new technology though? This video looks mostly at weight increase to horsepower. Introducing, the McMurtry Speirling! An all electric, carbon fiber car that uses massive vacuum suction power, even from a dead stop to add down force. Able to maintain as much down force sitting still as moving forward, with minimal extra weight needed to achieve the traction needed for the power its able to produce to the wheels. Truly next generation in automotive technology in my opinion.

How about Top Fuel Dragsters and Funny Cars that accelerate to 330 mph in 3.7 seconds?

So how does a standard Tesla S Plaid standard out of the box do 0-60 in 1.99s? I know in regular conditions it's more like 2.3s but that is still faster than freefall which is 2.7s. I thought it had to do with the traction control measuring the ground 1000 times a second to keep the car in Static coefficient of friction which is higher than the kinetic coefficient of friction.

Great video, but the title and thumbnail are misleading.

This is the first time I felt smarter than an astrophysicist.

Neil, How can you hold yourself up as an expert in ANYTHING when you get something as basic as this so wrong. A coefficient of friction between the tires and the road greater than gravity, along with positive downforce as the vehicle picks up speed will ensure faster-than-gravitational acceleration (given enough hp). The quickest vehicles are currently accelerating at roughly 1.5 g; improvements in tires and aerodynamics will continue to push the upper bounds of acceleration. How am I wrong?

I was actually interested in Gary's anecdotes. Too bad Neil is always too in love with the sound of his voice.

Dr. Tyson is one of the greatest, but I have to say he is not totally right here. Cars are able to overcome loosing friction to some extent by not applying 100% of the car's capability at launch, and only applies a fraction and increases it's output over time till friction is close to optimal. This is called "launch control". The porsche 911 turbo S uses semi-road tires and with launch control is does a 2.6 0-60. Thr compound in those tires aren't as soft as they may seem. It's possible to drive up to 12'000 miles on those tires. If a car's engine could rev up to 7000 rpm, launch control would limit it to around 3000 to 4500 rpm depending on the car.

The fastest on record was a ThrustSSC driven by Andy Green, a twin turbofan jet-powered car which reached 763 mph.still interested how it was still able to remain on the ground without going airborne. Velocity and speed working together?

three things. Make the tires wider; make the care 4 wheel drive; add more tires. So what would a 12-wheel drive with 18 inch wide tires do 0 to 60.

I've heard this argument before, and it's very flawed. When a Top Fuel Dragster can go from 0 to 100 MPH in .8 tenths of a second and will accelerate to almost 340 MPH in 3.6 seconds to cover 1000 feet. That's way, way, way more than 1G!

Mr. Neil deKnowItAll: Tesla Plaids, McLaren 720S's, Ferrari SF90's, and other high performance sports cars are able to run well into the 9's 1/4 mile time while ON THE STREET using STREET TIRES. That's well over 1 G acceleration (about 1.5 G's in some cases). Not necessary to use that "sticky, gooey" compound you talk about (it's called VHT by the way). That helps to get the absolute best performance. But definitely not required to hit over 1G in a well engineered car. You're also forgetting about lateral acceleration. There are many cars that can pull well over 1 G of lateral acceleration. And again, that's on the street using street tires.

Oh…I love these explainers!!! Short, sweet, & to the point. 💯👌🏻👍🏻

I’m confused. I just watched a video of Tom Scott going 0-60 in like 1.4 seconds.

Top fuel dragster: 0 to 100 in .8 sec.

The fastest production car can 0-60 in 1.9 seconds, sooooo clearly there's some wizardry at play

What about four wheel drive, Neil? I am pretty sure some versions of the Porsche 911 do 0-60 in like 2.6’’

Explainers are my favorite Star Talk videos. But I have an issue with this video and that is that power is not related to acceleration (and yes, I'm a fuss budget about this). Maybe Dr. Tyson should do an explainer on that. Demonstration: I have a rear-wheel drive motorcycle that is accelerating at a constant 1G. It has a mass of 1,000 KG. The drive tire is 1 meter in radius. There is no wheel spin. How much power is being delivered to the drive tire? How much torque is being delivered to the drive tire? Spoiler alert: You will find that you cannot calculate the power without introducing either the instantaneous speed of the vehicle or the instantaneous tire RPM, and that value of power is valid only for that particular speed/tire RPM. You will find that to achieve a constant acceleration the torque remains constant, the power varies directly with the speed/tire RPM.

There are performance tires out there now that have a higher than 1.0 coefficient of friction, so they can actually break the sub-3.0 second acceleration barrier (usually around 2.5 s)! I think they don't need any specially prepped tracks, just regular roads. The tires are obviously softer than normal passenger car rubber. With specially prepped tracks, they will probably do 1.9 second accelerations, which is 1.44 g! Higher than the acceleration of gravity!

The main thing keeping cars from going faster isn't engine power or traction issues, it's the tires themselves. it's hard to make a tire that can rotate are the speed of sound and not rip itself apart while undergoing the forces in play

Static friction. You know, friction has been a very sticky subject in physics and engineering for a very long time.

Why is the thumbnail "terminal velocity", when it's all about acceleration from 0? Could also have mentioned, that the best practical way to improve on this is 4-wheel-drive: All of the mass of the car weights on accelerating-force producing wheels instead of just part of it weighing on the driven axle (unless the front wheels lift off due to dynamic forces). This probably was much more of a reason of Audi's success in 80's rally racing than any other off-road advantages.

@8:55 "You're not gonna get a car going 0-60 in 2 seconds unless theres something digging into the road" There are a few cars that have achieved this

Nice to see even Neil is human and gets things wrong sometimes! The 1 G limit he mentions is just a nonsense unless you drive off a cliff. Yes your acceleration, braking and cornering is ultimately limited by the grip of your tyres but there are many road cars these days that can generate well over 1G acceleration (either accelerating, braking or cornering) and there are quite a few road cars now that do well under 3 seconds 0-60, Bugatti Chrion (2.3), Ariel Atom, Tesla S etc and even under 2 seconds! Lucid Air Sapphire(1.9) , Rimac Nivera (1.85). Modern grippy road tyres mean even my own car an do 1.3G (lateral, as I don't have the power to accelerate that fast!), and many modern supercars can do around 1.5G and hyper cars like the McLaren P1 are closer to 2G. A Bugatti Chiron can brake at 2.5G but 1.7G of that comes from the tyres an an extra 0.8G deceleration comes from a big air brake that pops up into the air flow. The current limit for road cars seems to be around 1.8 secs 0-60 (although the McMurtry can do it in 1.4 as it sucks itself to the road with a fan) and interestingly Elon Musk wants to beat the tyre limit by adding rocket thrusters to the new Tesla supercar! And as for racing and drag cars they can do way more Gs with slick tyres and sticky compounds that chemically bond the tyres to the tarmac to increase the friction. Modern F1 car generate anywhere up up to 6G lateral and braking (due to downforce and tyres) and Top Fuel dragsters do 0-300 in around 4seconds which is around 5G acceleration which must to be seen to be believed!

Ferrari SF90 Stradale - 0 to 60 in 2.4 seconds 1g would take 2.74s (~3s) So the Ferrari is doing better than 1g

The ultimate top speed is somewhere just under the speed of sound because the shock wave would lift the wheels off of the ground.

Amazing videos as always!!

The tires, traction, air pressure and wind speed is always the issue. The all wheel drive Bugatti Chiron super sport managed 300 mph, but the tires had to be reinforced, and the speed was impacted by air pressure and wind speed and direction. Does 0-60 in less than 3 seconds which isn’t a stretch nowadays (in supercars anyway). My Audi RS3 managed it in 3.8 but that was a perfect windless day. Slightly wider rear wheels compared to the front wheels and electronic computer controlled all wheel drive to control traction helps. Basically looks for deviations in RPM between all 4 wheels and speeds up/slows down each to maintain traction and that software is improving all the time. Am only talking cars people can buy and go to the store with - not drag stuff with rockets and things. They’re not cars. Musk’s roadster is a car but was “slightly” modified to manage escape velocity. Fun fact: at top speed, the Chiron’s tires would only last for 13 miles, but it would run out of gas with 3 miles to spare anyway.

Misleading title, but interesting none the less

Neal is the man. I'm an avid follower but this is the first time I have to disagree. Yes Earth's gravity is a major factor in the calculation but it is not limited to 1G. Retina detachment is a common injury in Top Fuel drag racing from the 5Gs of acceleration they are generating. That is not the jet cars. Those actually accelerate slower. Some production road cars now break 1G. The Tesla Plaid pulled 1.3G according to Motor Trend, and 1.16G of deceleration during the braking test. According to popular Mechanics, anything that hits 0-60 in less than 2.73 is exceeding 1G. Motorcycle tires actually deform to absorb little bumps and fill the tiny cracks in the pavement for traction. They can slightly exceed 1G in cornering. That's why you're not supposed to use tires older than 5 years because they harden and begin to not be able to fill in the cracks. I assume many soft car tires do the same. Also in BeamNG Drive (which is known for super accurate physics) you can change the gravity to Moon, Jupiter or the Sun. Moon gravity makes it impossible to drive fast. Horrible traction and way too bouncy. So, yes Earth's gravity enables us to accelerate as fast as humans have so far achieved. If it was a little higher we could build a car that could accelerate even faster. Sun gravity just instantly pancakes most cars so there's definitely an upper limit to how much gravity will help your car accelerate. There also a couple of real cars that use fans to suck the car to the ground and generate up to 2,000lbs of downforce from a standing start without adding mass. Cool topic though, thanks.

Neil didn’t like him talking through the heated tires😂

12:10 lmao that imitation was on point!

Neil deGrasse Tyson, an unmodified stock Tesla Model S goes 0 to 60 in 1.9 seconds on regular roads ... O g lol | Explain That! ;)

November 11, 2022, Brittany Force went from zero to 338.94 MPH in 3.641 seconds. In a wheel driven car, not a rocket.

Model S Tesla is 0-60 in 1.9 seconds

Things I learned bombing hills on a Skateboard and dealing with wheel wobble.

So many comments jumped the gun on this video and didn’t finish watching it lol

The traction coefficient between the tire and the road depends on road construction. But a more grippy road will mean shorter tire life.

2:44 in. Hello, NHRA!? Love you guys!

A channel worth subscribing to twice

Learnt that concept fast when I bought a Tata SuperAce Mini Truck and couldn't drive uphill after some slight drizzle. Zero grip on the asphalt! I had to put sacks of sand on the back wheels for it to have traction because it is super light. But when it carried its max 1 tonne load it drives like a dream LOL!

Can we talk about Quark planets and grey holes please

One of the great new motorsports is generally referred to as "Drag and Drive". Pretty much exclusively amateur events (no real prize money, although many are professional car builders), which are, in general, one week long, drag races at 4 or 5 different tracks. The format they shoot for is gather at track A, register, car inspection and test on day 1. On day 2 Race for time only at track A, then DRIVE that same car to track B under it's own power (no time limit or any sort of race between tracks) following a predetermined route with check points.On day 3 Race for time only again at track B, pack up and DRIVE the same car to track C, wash and repeat. The path of travel after approximately one week ends up back at track A with the best aggregate time of the race portion who also made all of the check points declared the winner. There are multiple class and therefore multiple winners with the Grand Prize going to the quickest aggregate TOTAL, or average fastest at all the tracks, time. They, very loosely shoot for 1320 miles total for the drive part, so as to correspond to the 1320 feet of the drag race. The current record holder is TOTALLY UNBELIEVABLE to old school drag racers. Not, because of it's track speed, but because of it's ability to drive hundreds of miles on the streets and highways, pull into the track and do those dedicated race car like track times! www.motortrend.com/events/tom-bailey-wins-hot-rod-drag-week-2022/

Somebody please share the title of the video where Neil discussed Rails, at the end of this video

Tesla is adding a compressed air-jet assist on their new sports car. How do you include that in your analysis?

Hmm, Tesla Model S Plaid goes 0-60 in under 2 seconds! Contradicts Neil’s point at 9:05. No wonder they say that car has “alien” and “new” physics lol

Star Talk is great. Laughing and learning. Thanks guys. 🙏

I can't wait to hear about rails! Fantastic episode!

I liked the discussion very much, but I think there are still a few misconceptions. Dr. Tyson seems to imply that the coefficient of friction between rubber and pavement has to be less than or equal to 1.0. There is no physics reason this has to be true. It just depends on the type of rubber and the pavement properties. There are exotic rubber compositions that can have frictional coefficients >1. One of his guests seemed to miss the point that the acceleration of a wheel-driven car is limited by the friction of the tires on pavement. Putting a Merlin engine in your care doesn't let you accelerate faster than that limit, as long as you are transmitting the power through the tires and not through a propeller.

You can tell Neil is not a car guy. It's pretty common these days for the high end cars to go faster than 1G to 60 (say 2.4 to 2.5s) without rollout: true 0-60 on street tires on regular unprepped asphalt or concrete. The rubber in any tire will deform and fill the nooks and crannies of the road surface to give them a slight bite, almost like the gear example. It's just how tires work. Want a funny KZbin short at a place where they run 2, 3, or more G's? Get Neil laughing as he loses both shoes trying to walk across a prepped dragstrip. 🙂

"The fastest you can accelerate forward is one G" That's not always true. Without doing a Top Fuel-style burnout, because the car is all wheel drive and not really capable of doing so, the Rimac Nevera can accelerate at 1.5G, and hits 60mph in 1.85s.

Not sure it's fair to call this an oversight, but you guys might find it interesting. In motorsports that require a takeoff at the beginning of the event (such as drag racing), where maximizing acceleration is key to a good time, pro drivers are known to not go full throttle, because of that burnout principle where too much spin doesn't let you grip the tarmac. They actually use just enough throttle to grip the tarmac without being too much, and they'll add more throttle as they gain speed and have less room for grip loss, due to how the RPM of the wheels and the speed of the car interact mathematically. Pretty cool.

The combination of science and comedy is amazing.

Cleaning my house and listening to this interesting video.

Tires don't follow classic "friction coefficient" physics. You need to understand "traction coefficient", and "grip", which explain how tires can produce coefficients greater than 1, even without traction compounds or heat, and while operating at significant percentages of slip. Tires are wickedly complex devices.

The modern NHRA Top Fuel dragster accelerates harder and pulls more G's than any [unclassified] fighter jet launch. At 5 G's, there's no wheeled vehicle on earth that even comes close.

5:02 Missed win at 5 minute mark... Neil: How does the car look in a skirt? [quick cut to Chuck]: Better than me!!

It isn't glue on the tires for friction the rear differential gears try and "climb" the other they use this force to direct more pressure to the rear tires, search ladder bars and or 4 link suspension

Mcmurty spierling set a world record for a road car 0-60mph of 1.3 seconds recently. that car has electric motors and a giant electric fan out of the back. It kinda looks like the 1989 batmobile haha

McMurtry Speiring Does 0-60 mph in 1.40 seconds guys. Explain that

NO! The Tesla model S Plaid record on the track in the 1/4 mile is 1.987 seconds. Model S is a four wheel drive.

You should probably look into how drag race wheels work

The cover image not blurring the wheels is as incorrect as the title of the video.

Modern cars with good traction control can do it without problems! When the tires loose grip the engine decreases power to almost 0 then back to 100% then back to 0 and back to 100% again multiple times per second! That allows for greater acceleration than 1G and faster then 3 seconds 0-60 times! The reason that the new electric cars can do it even faster than 2 seconds 0-60 times are because electric motors can go from full power to 0 power to full power again, THOUSANDS of times per SECOND! That makes them get extremely fast because the don’t spin the wheels! I think you should read up on that and make a video explaining it! It’s really interesting technology! Love your videos! Thanks! / a normal, smart mechanic from Sweden!

If we're going to talk about downforce then I'm gonna need a spoiler alert! 🌬🚗🚨

Facts is facts. Thank you for no BS explanation