Why does a Tesla car use an AC motor instead of a DC one?

You're asking about the technical tradeoffs surrounding the selection of a traction motor for an electric vehicle application. Describing the full design tradespace is far beyond what can reasonably be summarized here, but I'll outline the prominent design tradeoffs for such an application.

Because the amount of energy that can be stored chemically (i.e. in a battery) is quite limited, nearly all electric vehicles are designed with efficiency in mind. Most transit application traction motors for automotive applications range between 60kW and 300kW peak power. Ohms law indicates that power losses in cabling, motor windings, and battery interconnects is P=I²R. Thus reducing current in half reduces resistive losses by 4x. As a result most automotive applications run at a nominal DC link voltage between 288 and 360V_nom (there are other reasons for this selection of voltage, too, but let's focus on losses). Supply voltage is relevant in this discussion, as certain motors, like Brush DC, have practical upper limits on supply voltage due to commutator arcing.

Ignoring more exotic motor technologies like switched/variable reluctance, there are three primary categories of electric motors used in automotive applications:

Brush DC motor: mechanically commutated, only a simple DC 'chopper' is required to control torque. While Brush DC motors can have permanent magnets, the size of the magnets for traction applications makes them cost-prohibitive. As a result, most DC traction motors are series- or shunt-wound. In such a configuration, there are windings on both stator and rotor.

Brushless DC motor (BLDC): electronically commutated by inverter, permanent magnets on rotor, windings on stator.

Induction motor: electronically commutated by inverter, induction rotor, windings on stator.

Following are some brash generalizations regarding tradeoffs between the three motor technologies. There are plenty of point examples that will defy these parameters; my goal is only to share what I would consider nominal values for this type of application.

- Efficiency:
Brush DC: Motor:~80%, DC controller: ~94% (passive flyback), NET=75%
BLDC: ~93%, inverter: ~97% (synchronous flyback or hysteretic control), NET=90%
Induction: ~91%: inverter: 97% (synchronous flyback or hysteretic control), NET=88%

- Wear/Service:
Brush DC: Brushes subject to wear; require periodic replacement. Bearings.
BLDC: Bearings (lifetime)
Induction: Bearings (lifetime)

- Specific cost (cost per kW), including inverter
Brush DC: Low - motor and controller are generally inexpensive
BLDC: High - high power permanent magnets are very expensive
Induction: Moderate - inverters add cost, but motor is cheap

- Heat rejection
Brush DC: Windings on rotor make heat removal from both rotor and commutator challenging with high power motors.
BLDC: Windings on stator make heat rejection straightforward. Magnets on rotor have low-moderate eddy current-induced heating
Induction: Windings on stator make stator heat rejection straightforward. Induced currents in rotor can require oil cooling in high power applications (in and out via shaft, not splashed).

- Torque/speed behavior
Brush DC: Theoretically infinite zero speed torque, torque drops with increasing speed. Brush DC automotive applications generally require 3-4 gear ratios to span the full automotive range of grade and top speed. I drove a 24kW DC motor-powered EV for a number of years that could light the tires up from a standstill (but struggled to get to 65 MPH).
BLDC: Constant torque up to base speed, constant power up to max speed. Automotive applications are viable with a single ratio gearbox.
Induction: Constant torque up to base speed, constant power up to max speed. Automotive applications are viable with a single ratio gearbox. Can take hundreds of ms for torque to build after application of current

- Miscellaneous:
Brush DC: At high voltages, commutator arcing can be problematic. Brush DC motors are canonically used in golf cart and forklift (24V or 48V) applications, though newer models are induction due to improved efficiency. Regnerative braking is tricky and requires a more complex speed controller.
BLDC: Magnet cost and assembly challenges (the magnets are VERY powerful) make BLDC motors viable for lower power applications (like the two Prius motor/generators). Regnerative braking comes essentially for free.
Induction: The motor is relatively cheap to make, and power electronics for automotive applications have come down in price significantly over the past 20 years. Regnerative braking comes essentially for free.

Again, this is only a very top-level summary of some of the primary design drivers for motor selection. I've intentionally omitted specific power and specific torque, as those tend to vary much more with the actual implementation.

...and now why Tesla uses induction motors

The other answers are excellent and get at the technical reasons. Having followed Tesla and the EV market in general for many years, I'd like to actually answer your question as why Tesla uses induction motors.

Background

Elon Musk (cofounder of Tesla) comes from Silicon Valley (SV) thinking, where "move fast and break things" is the mantra. When he cashed out of PayPal for several hundred million, he decided to tackle (space exploration and) electric vehicles. In SV-land, time/speed to get things done is everything, so he went looking around to find something he could use as a starting point to get a jump start.

JB Straubel was a like minded engineer (both space and EV) who reached out to Musk shortly after Musk made his interest in space and EV public.

During their first lunch meeting, Straubel mentioned a company called AC Propulsion that had developed a prototype electric sports car using a kit car frame. Already in its second-generation, it had recently switched to using lithium-ion batteries, had a range of 250 miles, offered lots of torque, could go 0-60 in under 4 seconds, but, most germane to this discussion, used -- you guessed it -- AC Propulsion (induction motor).

Musk visited AC Propulsion and came away very impressed. He tried for a few months to convince AC Propulsion to commercialize the electric vehicle, but they had no interest in doing so at that time.

Tom Gage, the president of AC Propulsion, suggested that Musk join forces with another suitor consisting of Martin Eberhard, Marc Tarpenning, and Ian Wright. They agreed to merge their efforts, with Musk becoming chairman and overall head of product design, Eberhard becoming CEO, and Straubel becoming CTO of the new company which they named "Tesla Motors."

The Answer

So there you have it, Tesla uses induction mostly because the first viable prototype that Musk saw used it. Inertia (no pun intended... ok, a little) explains the rest ("If it ain't broke...").

Now as to why AC Propulsion used it in their Tzero prototype, see the other answers... ;-)

If you want the full story go here or here.

It's hard to say what the engineers' exact reasons were without being on the design team, but here are a few thoughts:

1. Both motors require similar drives. Brushed DC motors can run directly off a battery but the type of motor you are looking at in an electric vehicle is a brushless DC motor. The drives for an induction motor and a brushless DC motor are very similar. The control of an induction motor is probably more complex in general.

2. DC brushless motors have magnets in the rotor. This is more costly than an induction rotor with copper. Additionally, the magnet market is very volatile. On the other hand, an induction motor will have a lot more heat produced in the rotor due to I²R losses and core losses.

3. Starting torque on brushless motor is generally higher than on induction motors.

4. Peak efficiency of brushless is generally higher than induction motors but I believe I read somewhere that Tesla gets a higher average efficiency with their induction motor than they would with a brushless. Unfortunately I can't recall where I read that, though.

5. A lot of people are researching switched reluctance machines now. The last few motor conferences I've been to have been all about switched reluctance. They don't require magnets and the efficiency on these types of motors looks promising. Everybody wants to get away from magnets in motors.

So, as I said, I doubt anybody could answer your question except for the engineers at Tesla. But my best guess is that it probably has something to do with my point 4) but I don't know that for sure. I'm sure the volatility of magnet prices has something to do with it too.