A scanning tunnelling microscope sees atoms. Why does a tiny gap change so much?
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Answer: Exponential current
Exponential current ✓ — Correct. STM works because tunnelling current depends exponentially on the tip-sample distance, so an angstrom-scale height change can strongly change current. Some teaching texts estimate a 1 angstrom gap change can shift current by about an order of magnitude. That turns quantum leakage into a topographic ruler.
Surface heat damage — Heating the surface would usually be a nuisance, not the measurement principle. STM uses a small voltage and current feedback, and it needs conducting or semiconducting samples. The nice twist is that the microscope maps absence: a vacuum gap with no classical wire still carries a measurable quantum current.
Lens magnification — A normal lens is not what gives STM atomic sensitivity. The tip is brought extremely close to a conducting surface, and the electronics keep the tunnelling current near a target value. Unlike optical microscopy, the resolution comes from the steep distance dependence of electron tunnelling.
More Physics in Daily Life questions
- In a warm office that already reads 26 C, which change can make people feel cooler without lowering the thermostat?
- Why might 26 C feel acceptable in a breezy naturally ventilated summer building but too warm in a sealed winter office?
- On a warm humid day, why can the same 27 C room feel much worse once you start sweating?
- Why can moving air make a 27 C room feel cooler without changing the thermometer?
- Which hidden factor can make a desk beside a cold window feel chilly even when the thermostat across the room still reads 22 C?
- In the same 22 C room, why might someone who just climbed stairs feel warm while someone sitting in a T-shirt feels chilly?
