I went to a talk by an SOM architect a few years ago, while Tapei 101 was under construction.
He said the principal limiting factor for the height of a super-tall structure is economics.
In fact buildings over sixty stories or so don't make much sense in any real-estate market -- not even Manhattan or Hong Kong -- if viewed from the perspective of real estate as a commodity. Where supertalls make economic sense is if they can be turned into a prestige address when the building becomes a landmark.
With respect to wire rope, there is already synthetic rope with dramatically better tensile strength, and it's displacing wire rope in many applications. Synthetics have a lot less hardness than steel though, and are subject to abrasion. I don't know if a carbon fiber rope would be harder than a steel rope or not, but I know from experience that CFRP panels are not nearly as hard as steel plate.
I too saw Taipei 101 under construction... incredible to think it's in a serious earthquake zone.
there is already synthetic rope with dramatically better tensile strength, and it's displacing wire rope in many applications
The article did mention the use of a dual layer anti-abrasian coating for durability.
Honestly though, why increase height and density still further? There are stupendous issues here with efficiency with regards to food, water, and HVAC - if nothing else. My personal view is that cities of the present are essentially anachronisms spawned from 20th century post-industrialism intertia: artifacts of outmoded labour markets, planning laws and now-quaint geospatial efficiencies.
As the cost of living in cities rises due to the shortage of land, the requirement for importing food and water, and the artificiality of maintaining a reasonable healthy lifestyle in high density urban environment, my bet is that, broadly speaking, emerging labour markets (our type of industry, for example) based on new technologies for communications and a reformed education system will cause a mass migration of professionals away from cities, back to a more sustainable, decentralized model. Sort of like the green banker-belt outside of London, but on a far larger scale.
In short, I believe that while the city will not disappear, its face will change .. and certainly not primarily through ever-taller buildings.
Honestly though, why increase height and density still further? There are stupendous issues here with efficiency with regards to food, water, and HVAC - if nothing else.
Can you back up your impression that there are stupendous efficiency issues with numbers?
In the USA multiple studies have been done on the question. They find that the per capita carbon footprint of people living in major metropolitan areas is lower than those living in smaller cities and the country. And NYC, that concrete jungle that epitomizes a disconnect from anything natural, is actually per capita the one of the 10 most ecologically friendly cities in the nation!
Can you back up your impression that there are stupendous efficiency issues with numbers?
I would have thought that the cost of hauling food and water up 60 floors was self-evident? While I could go invest time finding numbers, to be honest I find it a bit rich that you ask me to provide sources while making equally unreferenced, sweeping and IMHO dicier claims in response.
For example, claiming the carbon footprint of city dwellers is low might be possible if it doesn't consider the cost of hauling the products they routinely use and throw away at rates far higher than other people on the planet... but that doesn't make it a realistic or truthful stance on the matter.
I am not surprised that NYC is low on obvious evils when considering this form of skin-deep environmental statistic, because it produces very little of... well, anything. As the center of finance, NY derives a great amount of wealth from achieving effectively zero of utility to the rest of the world.
For something more concrete, let's try measuring garbage. (I'm not going to get in to the interesting question of Wall St.'s facilitatory role in greater evils.) https://en.wikipedia.org/wiki/Environmental_issues_in_New_Yo...In September 2012, Travel+Leisure named New York City the #1 "America's Dirtiest City," from the results of a readership survey rating 35 "Favorite Cities" in the United States. It continues: In 2006 Mayor Michael Bloomberg signed legislation establishing a new solid waste management plan, which will use barges and trains to export 90% of the city’s 12,000 daily tons of residential trash. I can tell you that country people don't generate that much trash, and they can often dispose of it in a decentralized fashion (eg. via compost). Even Mexico City only produces 10,000 tons per day (random stat online), and its population is far higher and they probably actually make some tangible goods. But I'm not going to go build a well-referenced numerology of truth here. I hope you might be motivated to research further yourself.
The bottom line is that nature loves decentralization, and 'taxes' centralization. Cities are unnatural conglomerations that abhor nature. While we can sustain them, it's not the smartest thing to do in a finite world. Society is just beginning to learn from and invest in this with concessions to green architecture, urban design, public transportation, public communications infrastructure projects (Australia, China, France, New Zealand...), decentralized energy generation, etc.
Up 60 floors perhaps, but getting it there required only bringing it a few miles from the nearest depot (having been brought there en-masse) rather than a giant star (or worse) network, replicating the same effort 1000 times to transport said food and commodities and to provide infrastructure to every one of the many parties in the decentralised model you propose as more efficient. :/
Point of obvious fact for you. When I provide a citation, that's not an unreferenced claim. And, unlike you, I'm not cherry picking my references.
What do I mean by cherry picking? Let's take your Wikipedia link, one sentence before the travel and leisure survey. New York City accounts for only 1% of United States greenhouse gas emissions while housing 2.7% of its population.
This is all consistent with what I said. NYC has a ton of people. Having a ton of people, it is inevitably an environmental eyesore. However, per person, it is environmentally better than the alternative.
Let's look at your garbage claim. NYC produces 12,000 tons per day of garbage. NYC has about 8.3 million people. That's 2.89 pounds of garbage per person. From http://www.cleanair.org/Waste/wasteFacts.html we see that the average American produces 4.5 pounds of garbage per day, of which 66.8% is sent to landfill. That's 3.01 pounds. Again, per capita, NYC beats the rest of the USA. Of course this is slightly unfair. Again, as you note, NYC has mostly outsourced its manufacturing. Manufacturing generates lots of garbage. I don't see an easy way to quantify that. However I do note that NYC has a high density of very rich people whose consumption can be expected to be above average.
I've lived in the country. Based on my experience, people who live in the country create tons of garbage, it is just not centralized.
It is true that Mexico city does better. However Mexico city is also poorer. Poor people, out of necessity, cannot consume much.
Next let's move on to your points about raising water. First of all, as https://en.wikipedia.org/wiki/Skyscraper#Environmental_impac... makes clear, it is true that it takes energy to put stuff high in the sky. But there are tradeoffs and it is not at all clear whether a skyscraper is or is not environmentally efficient.
But that's irrelevant. The population density of NYC doesn't require high skyscrapers. I've lived there. It is really dependent upon having small apartments, packed closely together. Most of the city is made up of buildings that are 5 stories high. (Because at 6 stories you need to install elevators.)
As for your general hate of cities, I submit that the facts don't support it. It is true that cities are unnatural, expensive things. However, per capita, they tend be more efficient. But fundamentally there is no way to support an unlimited number of people in a finite world.
I think GDP was shown to grow almost quadratically with density. It wasn't so much about efficiences, as omnipresent services. If you can walk past 10 hotdog vendors on the way to work, you'll probably buy one.
Good for health? No. Good for the environment? No. Good for corporate profits, ease of taxation, and established measures of economic trajectory including GDP? Yes. This is the story of the city, and its inhabitant is you.
Manhattan has some of the lowest obesity rates in the country due to inhabitants reliance on walking/public transit over driving. There are few studies that show a 2 year life expectancy vs rural areas in the UK, but it's not a totally clear cut win for rural areas overall.
"Good for the environment? No."
Yes, actually - it's a lot more efficient to deliver services to people in densely populated areas than when they're spread thinly across the country side.
No disagreement on corporate profits. Cities are also great as birthplaces of movements, musical genres, schools of art, and political theories. Think the east village during punk, detroit in the 50s for rock, the salons of paris around the French Revolution, etc etc.
There are definitely great reasons to live in rural areas, but being a city dweller is far from inherently worse.
Health: Correlation is not causation. Those people also have cash, access to the best care, preventative care, etc.
Environment: What services are you talking about? Remember that to squeeze people together in the first place you have to import and maintain costly networks for moving food, water and energy. So dealing with decentralization from an efficiency standpoint should take this tradeoff in to account. As for the emissions references, I suppose they don't take in to account the ridiculous amount of pollution that goes on overseas or in other areas for products shipped in to cities (or the overheads of shipping itself).
I agree that historically there's great social and intellectual wealth in cities, but I personally believe that's now being eclipsed by non-geographic movements, many of which are largely fostered through the internet.
You seem to assume that you don't need to create and maintain costly networks for moving food, water and energy for people to live in rural areas. Not many people in rural areas farm their own food and sort out their own local water and energy supply.
Cities benefit because you can bring in resources using more efficient means in larger quantities.
The availability of water varies regionally, but in many areas it is not a big deal to drill a well and have clean water (and septic is usually just a matter of meeting building codes).
Energy and food are still a big deal, but the mix today is that shipping fuel has less impact on food prices than real estate value (that is, the food at rural stores isn't particularly expensive and they usually aren't that far away). They may be less economical than city stores, but they seem tenable.
I sort of think the trick is to figure out a set of policies that lead to healthy medium-high density areas, as it is most 'great cities' seem to be at least partly accidental.
> but in many areas it is not a big deal to drill a well and have clean water
Yet that is not how more than a miniscule fraction of houses in less densely built areas gets their water.
> Energy and food are still a big deal, but the mix today is that shipping fuel has less impact on food prices than real estate value (that is, the food at rural stores isn't particularly expensive and they usually aren't that far away). They may be less economical than city stores, but they seem tenable.
The real estate cost is irrelevant to the discussion of the efficiency of urban vs. rural energy and food delivery.
I was responding to you calling the distribution networks costly. If rural distribution ends up costing less, the efficiency isn't something you are going to get people to give much consideration.
This is why I then start talking about making more good cities, because that should presumably remove some of the costs that are more or less associated with lack of supply.
In theory, cities are better. It's cheaper to build a road network for 10 million people than 1000 road networks for 10,000 people. You can ship stuff in with container ships, rather than trucks.
But this might cause people to be more wasteful. Everything is cheap and accessible, so they consume more stuff.
It seems like you have a lot of misconceptions about cities and there health and environmental impacts, which have been proven multiple times to be lower in per capita then suburban and rural communities, often by great amounts. I'd like to understand why you think the decentralized model is more sustainable, It requires cars and roads to live outside the M25. Other comments have dealt with these numbers already.
Anyway, to my point. I see no reason why new technology and interconnectedness is going to lead to the decline of the western city. My Experience suggests its more likely to lead to a greater desire among young adults to move to the urban cores (as they always habe), for Sex/Marriage, Culture and Nightlife as they see there own friends partake, so to speak. At the end of the day, extremely few people would find the internet an acceptable replacement to living amongst ones peers
my bet is that, broadly speaking, emerging labour markets (our type of industry, for example) based on new technologies for communications and a reformed education system will cause a mass migration of professionals away from cities, back to a more sustainable, decentralized model.
You never heard of the economy of scale that comes with urban density? How would lower density makes the environment more "sustainable"?
In short, being closer to nature breeds efficiency.
For some basic examples: with more privacy, less pollution and lower rise building, people have a viable option to open a window when they're hot instead of turning on the air conditioner. Eating food from your own garden. Being more conscious of which food is in season, thus consuming more of it and less of the other stuff, saving on transport and artificial production overheads. Realistic capacity for grid-independent energy generation, wastewater disposal, rainwater capture, etc. There are plenty more.
(Edit: Seeing as people are apparently voting this down, I am honestly curious what they disagree with?)
Do you have some numbers? All the ones I know point to rural populations having significantly larger pollution footprints than urban populations, despite those advantages.
I don't think it's realistic to lump all rural populations together. For example, the unabomber's woodsman hut style existence probably had effectively zero pollution footprint. Whereas, the also American example of a large scale industrial farmer with a four bedroom house, two cars and a family, large scale farming equipment, and expectations of 24x7x365 electricity, water, sewerage, cell phone signals, non-local products and in-school education for his children is going to be worse than an urbanite.
If you are ever lucky enough to get the chance visit some more traditional cultures, you can see for yourself just how slight an impact they make on their environment, with houses, food, and clothes alike built from nature. It's amazing.
So, my position isn't realistic because it doesn't take into account the possibility that large parts of the population may choose to go back to a pre-industrial life?
No, I was pointing out the methodological problem with your suggested use of statistics, and that of course we have a spectrum of options when moving away from cities. My own feeling is that most of them are going to lead to less impact on nature, but perhaps you are right and in the short term many people will demand the same level of convenient consumption. Time will tell. Eventually, however, it seems clear to me that practicality will triumph convenience, since it's widely acknowledged that the first world presently consumes on a level that is ridiculously unsustainable and we will simply run out of the capacity to continue.
The biggest reason that cities are expensive to live in isn't so much a lack of land, it's a lack of properly zoned land. Even in limited areas like Manhattan, we have imposed extra artificial limitations on ourselves in the form of zoning laws. Remove those laws, and there will be much more housing built, and it will be cheaper to live in cities. Forced low income housing is another restriction, by only giving developers reasonable exceptions to draconian laws like minimum parking requirements if they set aside a certain portion of the units to low income housing, the government again restricts density. Better to remove ridiculous zoning laws in general, and housing will become more affordable for everyone.
My personal view is that cities of the present are essentially serving the same purposes they have served since the 19th century: meeting places for like-minded participants in labour markets, social and cultural gatherings, and sex.
As the cost of living in cities rises due to the shortage of land and the requirement for importing food and water, those seeking life partners can increase not only their number of prospective mates, but the feasibility of finding one who makes a lot of money. Not to mention the availability and acceptability of almost any persuasion, hobby, or kink. Those souls most interested in health will have no problem finding a vegan delicacy at any mealtime, no worry of being stuck with some "salad" at McDonald's as the only option being any points A and B, and they can always hop a train to commune with nature.
Broadly speaking, the desire of people to live near thousands of their peers after graduation will cause young professionals to keep moving to cities, eschewing a life more connected with nature for one with a greater diversity of local work opportunities, events, and beautiful bodies. Just like London.
Sex is a reasonable point to bring up. I guess you argue that cities are little more than vast, non-stop, multi-generational orgies. But London? http://www.allaboutfrogs.org/stories/well.html
There are a wide variety of coatings out there that could address this -- especially for an application requiring some flexibility like this, there are a wide variety of polyurethanes that have super high abrasion resistance compared to steel.
It would probably also be practical to simply modify the bearing surfaces as well.
How tall does a building have to get before all the other "utility" stuff becomes a limiting factor for any reasonable floor-space/building footprint? I imagine the space you need to dedicate on each floor to water/sewage, electrical, ventilation, etc goes up approximately linearly with the addition of floors. You also need to add more elevators as you add more floors, just to service the additional people each floor implies. Add too many floors and eventually some of the floors become little more than shafts running to other floors.
I don't really know anything about architecture so maybe my intuition is off. Maybe these concerns are never realized with the number of floors that are practical for other reasons?
The Burj received some pretty unflattering coverage a year or two ago for their "poop trucks", which were necessary for moving however many tons of feces 30,000+ people produce per day. However in many cases the building "cheats", i.e. the floor area shrinks rapidly the higher you go up and so the strain is better distributed throughout the system. I say cheat only because it's much more challenging to manage a uniform (or close to it) floor area from base to top such as the old WTC. The GE Building at 30 Rock is a good example of a building that used the building code (NYC setbacks, a good topic in itself if you're interested) to its advantage in planning the elevators and ventilation. It was mentioned in another comment above I think but in reality the economics are a much more controlling factor than hard engineering, and most of the engineering problems are about doing X for $YYY rather than XYZ for glory and innovation.
The Burj is a joke. It also seems to be mostly empty, because it priced itself out of the real estate market after the receession. It is so 'prestigious', no one can afford to use it. There are miles of empty lots starting just a few hundred yards away. If the Burj toppled over to the east, the top of it would land on empty ground. It is a temple to the vanity of the rulers of Dubai and their property developer lackeys. It is also an embarrassment, because Sheikh Khalifa of Abu Dhabi (the one with all the oil) had to bail them out to get it completed after the property bust of 2008 - that's why it's called Burj Khalifa, not Burj Dubai, as originally planned. And not to cap it all, the observation deck is only half way up!
I know this happens, with places pricing themselves out of the market, but it surprises me. Wouldn't they want to lower the cost of owning/renting a unit until the can actually get some buyers? It would still be a loss, but wouldn't it be much less loss, and isn't that better?
The problem has more to do with Dubai than with the building. Many buildings in Dubai employ similar schemes because the sewerage system wasn't scaled as the city grew.
This is like a lot of things in Dubai: roads, public transport and the airport which is currently being more than doubled.
You're quite right, but it's still worth noting that most supertalls are emphatically not residential towers. Office towers are much easier to manage when there's a workday pattern. I wonder if the rampant debt and consequent vacancies around Dubai has lightened the loads so to speak on their sewage costs...
Roughly 1/4 of the area is taken up with elevators, stairwells, and so on. So here's a back of the envelope calculation:
Elevator to office ratio: 1 : 3.
Proportion of floor area that is usable: 3 / (1 + 3) = 3/4.
To join the mile-high club, you need a building that's about 4 times higher. I will make the very crude assumption that, for a building that is 4 times higher, you will need 4 times as many elevators.
Elevator to office ratio: 4 : 3
Proportion of floor area that is usable: 3 / (4 + 3) = 3/7
Usable floor area compared to floor area of the old World Trade Center, occupying the same site:
4 * (3 / 7) ÷ (3 / 4) = 16 / 7; or about 2.3
So it's doable, but it's ridiculously inefficient. Where you draw the line is an interesting question. 100 stories is already pushing the limits, but you can alleviate this problem by tapering the building, like the Burj Khalifa. This is remarkably similar to how the pyramid builders solved their problems.
But what the pyramid builders really needed was the arch. And what modern engineers really need is an efficient vertical transport system. The obvious thing to do is have more elevators per shaft. Maybe something like a vertical cable car would work. Or even ditch the cables and make each elevator independently mobile within a network of interconnected shafts, like a vertical train system.
On the same note, in the last century brick buildings were limited in height by the thickness of the walls. If you went much beyond 20 stories, the ground floor walls filled the entire floor, making a sort of pedestal. So further height got zero further floor space.
Steel buildings got around this. Hanging each floor from a steel skeleton means the walls don't get thicker at all.
As you calculate, elevators are the new brick. The number needed to serve higher floors increase to the point the ground floor is nothing but elevators. So further height is pointless.
Its exacerbated by the need to fill/empty the building in bursts - people want to work regular hours, and everybody works the same hours. So you need enough elevators to essentially evacuate the building in under an hour.
Ways to work around this? Well, a pyramid structure would help I imagine. Elevators to server higher levels could be distributed evenly about the ground level, more in the center and fewer around the lower edges. That also increases windows-per-volume.
And of course if people lived and worked in the building and rarely left it, then the need to 'evacuate' from the ground floor goes away.
I imagine an arcology where people live, work and entertain in alternating levels. Fire and services can be located internally in strategic volumes. Air can be drafted up through the building using thermal gradients instead of fans.
Need to write a storey involving this kind of structure sometime I guess.
One high-throughput system is the http://en.wikipedia.org/wiki/Paternoster. Unfortunately, it looks extremely dangerous, and in fact has caused a large enough number of accidents that it's banned in most modern countries.
One idea I keep returning to is a "laned" system for elevators/lifts. Two shafts for going up, and two for going down. One of the two in each direction is the "passing lane"-- and you fit dozens of elevator "cars" in the whole system. For very high altitudes it may even make sense to have a third, high-speed lane.
Obviously this would require a completely different mechanism as you can no longer have cables attaching each car to the roof. In fact I have no clue how it could work! This is what I keep pondering...
You might be able to do it with linear motors. The problem there would be the reliance on the safety brakes in the event of power outages (not really a problem with counterweight elevators).
Mount what amounts to an elevator system on the linear motor, but it never goes up and down. So you suspend a standard otis elevator from the linear motor.
Power fails, linear starts to fall, lands on top of the traditional otis with its emergency brakes holding the whole works up. There's no reason the cable between the otis and the linear has to be 200 feet for the linear to build up speed... make it, perhaps, 3 inches and a nice spring arrangement.
I bet it would still be pretty scary to be in one of those during a power failure. So put hybrid batteries on the linear motor so it can just keep on running during a power fail, perhaps programmed to do nothing but a normal controlled descent to the bottom doors. if ($powerfail == 'Y') { ignore_all_floor_selection_buttons_higher_than_this_floor; }
I remember hearing that elevators took up a quarter of the floor space of the old World Trade Center - only because they used express and local elevators, it would have otherwise been half the floor space. So it would seem a "vertical train" system could be quite valuable for saving real estate.
Is it really that impractical to put the motor in the car? The elevator anyway needs rails on the side, if for nothing else to provide something for the emergency brakes.
Use regenerative braking on the way down so you don't need a counter weight - although that does mean you need a much large motor, you might save on energy, but power requirements would still be high.
Assuming that the weights of the lift car and the passenger load
remain about the same, moving the motor to the car saves the weight
of the cable, but adds the motor, power contacts, and whatever
traction device (cog?) moves the car.
Adding regenerative braking adds some form of energy storage -
batteries, flywheel, compressed air, or whatever. A flywheel might
be lighter than batteries, but torque I/O might affect passenger comfort.
It would be interesting to see how CF holds up over time. ISTR that
Kevlar rope is very strong, but turned out to have unexpected issues
with repeated jerky load/unload cycles. Presumably the CF elevator
cable would have adequate testing before commercial use.
There are already many buildings that segregate elevator systems into multiple stacked towers such as the Petronas Towers in Malaysia [1]. But in Petronas' case, it can become too complex that even the staff don't always get it right.
I can't comment on the first part (seems weird to me?) but they briefly mention "staged" elevators towards the end of the article (although it does not answer the first question.)
I wonder how many technologies out there exist, which would allow us to go far beyond our current state of the world, but we simply don't know about them. In a such an interconnected world, it sure feels that innovations are not very well combined to move us forward. Good article, btw.
This reminds me of a book back from the nineties called "Faster" by James Gleick. There was a chapter on lifts being the limit to building height, although I seem to recall it was more down to shaft space rather than cable strength.
I have been wondering why elevators aren't just vertical trains. No limit to distance, and several cars could use same tracks. Currently elevator shafts can reserve huge part of floor space. Down going cars could run motors in regenerative mode. So there's no need for heavy counterweights or heavy ropes. Another effeciency trick is trying to get people going to same destination into same car, reducing number of required stops. Might add some latency, but makes overall throughput better.
There are a number of suggestions to remove the cables altogether and have the car power itself, but would it not be easier to have the cables removed and still power it through the building?
Lots of discussion here about ratios of usable space in tall structures. Why don't we solve that by putting the elevators on the outside of the building?
It's always a novelty before it becomes mainstream. Have the elevators run in tracks of some sort, rather than in a shaft. Elevator won't block the view until it goes by.
Why do tall elevators use cables at all? Why not a system with a motor driven gear wheel on the car engaged with toothed rails on the sides of the shaft. You would not have counterweights but you could recover energy used in lifting on the next descent, and store it in supercapacitors for use on the next lift, which would achieve the same ends.
edit: I take it back, my memory is failing me. Some intermediate-modulus high-strength PAN based carbon fibers have strengths exceeding most synthetic polymers. Here is a comparison I put together a few years back for some research on fibers.
This is quite surprising as many synthetic polymers (zylon, spectra/dyneema, kevlar) are much stronger than carbon fiber. There is even a competition to make the strongest rope for potential space elevators:
It seems to be missing the real issue that you generally don't want lifts that go all the way to the top in one run because it uses up to much real estate.
You have to have multi-stage lifts else the whole building becomes full of lifts rather than offices etc
Much more exciting for projects like loon I would have thought.
Because when you stack lifts on top of each other in different parts of the shaft you can have multiple lifts running at once, hence multiple time the efficiency per m2. (High latency though)
Lifts are also limited by speeds, if they go too fast they make some people queasy. This is also an issue to contend with since express elevator are limited in the 'express' bit.
Edit: to be a bit clearer if you split up a shaft into 4 sections with fours lifts you can have four lifts full of people being moved, hence your bandwidth is 4 times as much. Taken to extreme you have one for every floor http://en.wikipedia.org/wiki/Paternoster
Lifts on the ground floor have to service the entire tower, where a lift that started half way up the tower would only have to serve half as much traffic as the ground floor lift, so you could have like a dozen lifts that go from ground->50%, and 6 lifts that go from 50% to top.
I love when scientific interest articles pop up on the front page like this.
It's really amazing to me that one of the things that holds skyscraper maximum height back is the practical concern of lift height. That's simply not the first thing I would think of if someone asked me the question.
But while that's cool, I don't think we necessarily should be building taller skyscrapers. They're not very practical. If they were, we'd have quasi-Coruscant cities where all the buildings were as tall as the Empire State Building or Willis Tower.
Instead, what tends to actually happen is the buildings become landmarks that attract a lot of attention but comparatively little real estate. Furthermore, when cities expand they generally need to build upwards quickly and forsake extravagance for practicality. If it takes 10 years to build a monolithic structure higher than the skyline, that's a project that's burning money for a long time until it's profitable.
The ropes provide energy efficiency. On one end is the lift car, but on the other and going in the opposite direction is a counterweight of similar mass. The lift motor only needs to move the difference in mass.
If you put the motor in the car without ropes then it has to be powerful enough to lift the whole car and all occupants. And if you want any hope of energy efficiency you'd need regenerative braking for when going down. This would make the lift car a lot heavier and the electrical system a lot more complicated.
Yes, but in either case, energy is lost in accelerating and decelerating mass. If your cable is a mile long, accelerating and decelerating it costs quite some energy, too. Long cable also have problems with swaying and elasticity.
Also, a main problem with high rise buildings is loss of floor space at lower heights (the water, electricity, waste, and person traffic of floors 2 to N all have to pass though floor 1)
Ropeless elevators can have a huge advantage there, as they allow one to hang multiple elevators in a single shaft that both service the full range of floors. Yes, that requires sophisticated software to prevent lift cars from having to pass through each other too often (some designs allow cabines to do that by making it possible for the cars to move horizontally, too), but it is an active research area.
"ropeless elevator" is not on Wikipedia yet; the best (but tangential and possibly slightly commercial) I could find Googling it is http://www.barkermohandas.com/images/Integrated%20Vertical%2..., which is about a system with wires that allows one to move cars horizontally by sliding them from one car frame to another using linear motors.
Not everything is a software problem, I think you are hugely underestimating how much more power is required for an elevator to self propel vertically upwards compared to a counterweight system. I'm not an expert but I'd have to guess its at least 10x if not potentially much more
He said the principal limiting factor for the height of a super-tall structure is economics.
In fact buildings over sixty stories or so don't make much sense in any real-estate market -- not even Manhattan or Hong Kong -- if viewed from the perspective of real estate as a commodity. Where supertalls make economic sense is if they can be turned into a prestige address when the building becomes a landmark.
With respect to wire rope, there is already synthetic rope with dramatically better tensile strength, and it's displacing wire rope in many applications. Synthetics have a lot less hardness than steel though, and are subject to abrasion. I don't know if a carbon fiber rope would be harder than a steel rope or not, but I know from experience that CFRP panels are not nearly as hard as steel plate.