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Atomic Absorption Spectroscopy: Interference01:25

Atomic Absorption Spectroscopy: Interference

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Interference leads to systematic error in atomic absorption (AA) measurements by enhancing or diminishing the analytical signal or the background. These interferences can be grouped into three main categories: spectral interference, chemical interference, and physical interference.
Spectral interference occurs when signals from other elements or molecules overlap with the analyte signal, falsely elevating or masking the analyte's absorbance. This interference can be corrected using Zeeman,...
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Control Systems01:10

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Control systems are everywhere in contemporary society, influencing diverse applications from aerospace to automated manufacturing. These systems can be found naturally within biological processes, such as blood sugar regulation and heart rate adjustment in response to stress, as well as in man-made systems like elevators and automated vehicles. A control system is essentially a network of subsystems and processes that collaboratively convert specific inputs into desired outputs.
At the heart...
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Measuring Acceleration Due to Gravity01:12

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Consider a coffee mug hanging on a hook in a pantry. If the mug gets knocked, it oscillates back and forth like a pendulum until the oscillations die out.
A simple pendulum can be described as a point mass and a string. Meanwhile, a physical pendulum is any object whose oscillations are similar to a simple pendulum, but cannot be modeled as a point mass on a string because its mass is distributed over a larger area. The behavior of a physical pendulum can be modeled using the principles of...
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Atomic Force Microscopy01:08

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Atomic force microscopy (AFM) is a type of scanning probe microscopy that can analyze topographic details of various specimens like ceramics, glass, polymers, and biological samples. AFM offers over 1000 times more resolution than the optical imaging system. Images generated from AFM are three-dimensional surface profiles, offering an advantage over the flat, two-dimensional images from other imaging techniques.
The AFM Probe
The probe is regarded as the heart of any AFM setup and comprises the...
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Relative Motion Analysis using Rotating Axes - Acceleration01:22

Relative Motion Analysis using Rotating Axes - Acceleration

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Consider a component AB undergoing a linear motion. Along with a linear motion, point B also rotates around point A. To comprehend this complex movement, position vectors for both points A and B are established using a stationary reference frame. The absolute velocity of point B is determined by adding the absolute velocity of point A, the relative velocity of point B in the rotating frame, and the effects caused by the angular velocity within the rotating frame.
Time differentiation is...
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Inertial Frames of Reference01:03

Inertial Frames of Reference

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Newton’s first law is usually considered to be a statement about reference frames. It provides a method for identifying a special type of reference frame: the inertial reference frame. In principle, we can make the net force on a body zero. If its velocity relative to a given frame is constant, then that frame is said to be inertial. So, by definition, an inertial reference frame is a reference frame where Newton's first law holds valid. Newton's first law applies to objects with...
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Related Experiment Video

Updated: Jul 10, 2025

Picometer-Precision Atomic Position Tracking through Electron Microscopy
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Enhancing the sensitivity of atom-interferometric inertial sensors using robust control.

Jack C Saywell1, Max S Carey1, Philip S Light1

  • 1Q-CTRL, Sydney, NSW, Australia.

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|November 22, 2023
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Summary

Robust light pulses enhance atom-interferometric accelerometers, improving precision by 10x. This quantum sensing advancement overcomes real-world noise for better navigation and Earth observation.

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Area of Science:

  • Quantum sensing
  • Atomic interferometry
  • Inertial navigation

Background:

  • Atom-interferometric quantum sensors offer revolutionary potential for navigation, civil engineering, and Earth observation.
  • Real-world operation faces challenges from external interference, platform noise, and size/weight/power constraints.

Purpose of the Study:

  • To demonstrate robust control techniques using tailored light pulses to mitigate error sources in atom-interferometric accelerometers.
  • To improve the performance and precision of quantum sensors in noisy, real-world environments.

Main Methods:

  • Experimentally applied laser-intensity noise (up to 20%) to mimic unpredictable lateral platform motion.
  • Utilized tailored light pulses designed with robust control techniques.
  • Measured local gravity and applied accelerations to validate sensor performance.

Main Results:

  • Robust control pulses maintained performant sensing, while conventional pulses failed under simulated platform motion.
  • Interferometer scale factor was preserved, and measurement precision improved by 10× in the presence of laser-intensity noise.
  • Applied accelerations were measured up to 21× more precisely at the highest noise level.

Conclusions:

  • Tailored light pulses using robust control techniques effectively mitigate significant error sources in atom-interferometric accelerometers.
  • This approach enhances measurement precision and preserves sensor performance in noisy environments.
  • Provides a viable pathway for improved atom-interferometric inertial sensing in practical, real-world applications.