Quantum Physics: A Beginner's GuideAs Alastair Rae points out in his introduction, "quantum physics is not rocket science". It may have gained a reputation as the theory that no one really understands, but its practical applications are all around us in everyday life. If it were not for quantum physics, computers would not function, metals would not conduct electricity, and the power stations that heat our homes would not produce energy. Assuming no prior scientific or mathematical knowledge, this clear and concise introduction provides a stepbystep guide to quantum theory, right from the very basic principles to the most cuttingedge developments, such as superfast computers and unbreakable codes, which could soon become reality. Finally, Rae turns to the philosophical questions posed by quantum physics and asks: if Einstein was wrong and God really does play dice, what are the consequences of this for the way we view ourselves and our relation to the world? Written by one of the most respected authors in the field, this authoritative and readable guide will be suitable for anyone wishing to gain a clearer understanding of one of the key scientific discoveries of our time. 
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Review: Quantum Physics: A Beginner's Guide
User Review  Sophie  GoodreadsIt seems cool for those who are interest on learning quantum physics!:) Read full review
Review: Quantum Physics: A Beginner's Guide
User Review  GoodreadsIt seems cool for those who are interest on learning quantum physics!:) Read full review
Contents
Mathematics  4 
nine  9 
A first look at quantum objects  16 
Copyright  
10 other sections not shown
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applied associated band barrier calculated carbon Chapter classical physics conﬁned consider contains Cooper pairs corresponding crystal current ﬂow deﬁned direction discussed distance Earth effect elec electric current emitted energy gap energy levels equal example ﬁlled ﬁnd ﬁrst ﬁssion frequency fundamental heat radiation hydrogen atom illustrated in Figure insulators interaction kinetic energy known light waves magnetic ﬁelds mass Mathematical Box 2.5 matter waves means measure metal molecules momentum motion moving ntype negatively charged neutrons nuclear nucleus number of electrons oscillator pn junction particular phenomena photoelectric effect photon Planck’s constant polarization positively charged potential energy predict principle probability of ﬁnding properties of atoms quantity quantized quantum computer quantum physics quantum tunnelling quarks qubits result Schrodinger equation semiconductor signiﬁcant similar space speed spin standing waves superconductivity superposition temperature theory thermal tion total energy transistor travelling waves trons tunnelling understand velocity vibration voltage wave function wave properties waveparticle duality wavelength whole number