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Note: ICEs in this article refers to internal combustion engines. In other contexts ICE can denote organizations such as Immigrations and Customs Enforcement.

Internal combustion engines convert chemical energy stored in fuels into mechanical work by combusting fuel with

The modern ICE developed in the late 19th century with the four-stroke Otto cycle and the diesel

Operation varies by type. Spark-ignition engines mix air and fuel and ignite with a spark; compression-ignition

Core components include the cylinder block, pistons, crankshaft, valvetrain, fuel system, ignition, lubrication, and cooling. Emissions

Efficiency and emissions depend on design and operating conditions. Typical automotive thermal efficiencies fall around 25–40%.

Although ICEs remain central to many applications, trends toward electrification and sustainable fuels influence the future.

air
inside
cylinders.
The
expanding
gases
push
pistons,
turning
a
crankshaft
to
produce
motion.
ICEs
include
reciprocating
piston
engines
and
rotary
designs,
and
power
most
cars,
trucks,
ships,
and
generators.
engine.
Through
the
20th
century,
improvements
in
materials,
ignition,
and
fuel
delivery
boosted
power,
efficiency,
and
durability,
enabling
widespread
use
in
transportation
and
industry.
engines
rely
on
high
compression
to
ignite
injected
fuel.
Two-stroke
and
four-stroke
cycles
differ
in
the
number
of
piston
events
per
power
cycle.
Modern
designs
use
direct
injection,
turbocharging,
and
variable
valve
timing
to
improve
efficiency.
controls—catalytic
converters,
exhaust
gas
recirculation,
and
sensors—address
environmental
concerns.
Techniques
such
as
turbocharging,
direct
injection,
variable
valve
timing,
and
hybridization
improve
economy,
while
cleaner
fuels
and
advanced
catalysts
reduce
pollutants.
They
are
likely
to
persist
in
heavy-duty
and
high-energy-demand
roles,
even
as
lighter
vehicles
transition
to
alternative
propulsion.