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【内容】
本书的作者为保罗·哈克特(Paul Hockett)教授,他于2008年在诺丁汉大学获得了博士学位,2009年加入了加拿大国家研究委员会,保罗的研究兴趣非常广泛,横跨了AMO(原子、分子、光学)的许多领域,包括量子、计算物理学(与物理化学),他特别关注光与物质相互作用的基础理论、光谱学和复杂系统的应用。本书的首要主题正如作者在前言中所述,是光电子量子计量学的发展。这个一般概念可以看作光电子光谱学的发展分支,通过具有高信息含量的实验来利用光致电离干涉仪的相位灵敏度。
【目录】
Map
A noteonthe online materials
A note on the references
Preface
Acknowledgments
Part Ⅲ Developments,methodologies and measurements
8 Developing quantum metrology with photoelectrons
8.1 Historicaldevelopment:completephotoionizati,otiexperiments
8.1.1 Atomic photoionization
8.1.2 Molecular photoionization
8.1.3 Further reading
8.2 Experimental and analysis methodologies
8.2.1 Determination of βL,M(k,t) from photoelectron images
8.2.2 Matrix element retrieval
References
9 State-resolved frequency-domain measurements
9.1 Rotationally-resolved photoelectron imaging
9.2 Bootstrapping complexity:from atomicto molecular scattering
9.3 Photoelectronangularinter ferograms and determination ofthe dipollmatrix elements
9.4 Uniqueness:mapping the X2 hyperspaceandverification
9.5 Pump-probepolarizationgeo metry dependence and tomographicimaging References
10 Time-domainmeasurements within tra-pulsedynamics
10.1 Photoelectron imagingmeasurements frompotassium
10.2 Photoelectron imagesimulationan dparameter reconstruction
10.3 Photoelectron angular interferograms and determination of the dipole matrix elements
10.4 Mapping X2:fit statistics and sensitivity
10.5 Comparison with tomographic data
References
11 Time-domain measements with rotational wavepackets:bootstrapping protocol
11.1 Test case:butadiene model
11.2 Nitrogen aligned-frame photoelectron imaging
11.3 Bootstrapping protocol
11.3.1 Formalism
11.3.2 Stage 1:rotational wavepacket reconstruction
11.3.3 Stage 2:photoionization matrix element reconstruction
11.4 Photoionization matrix elements
11.5 Molecular frame reconstructions
11.6 Bootstrap protocol summary and outlook
References
Part Ⅳ Generalisations and future directions
12 Advances
12.1 Information content revisited
12.2 Multiplexing and control
12.2.1 Exploring the intra-pulse dynamics
12.2.2 Coherent control for metrology:polarization multiplexing and information content
1 2.2.3 Extensions
1 2.2.4 Maximum information measurements and multiplexing
12.3 Generalised bootstrapping
12.3.1 Theoretical limitations
12.3.2 Additional approximations
12.3.3 Experimental considerations
12.3.4 Computational methods
References
13 Future directions and outlook
13.1 Bootstrapping to quantitative quantum dynamics
13.2 Further directions for quantum metrologies based on photoelectron interferograms
13.3 Summary and outlook
References
编辑手记
A noteonthe online materials
A note on the references
Preface
Acknowledgments
Part Ⅲ Developments,methodologies and measurements
8 Developing quantum metrology with photoelectrons
8.1 Historicaldevelopment:completephotoionizati,otiexperiments
8.1.1 Atomic photoionization
8.1.2 Molecular photoionization
8.1.3 Further reading
8.2 Experimental and analysis methodologies
8.2.1 Determination of βL,M(k,t) from photoelectron images
8.2.2 Matrix element retrieval
References
9 State-resolved frequency-domain measurements
9.1 Rotationally-resolved photoelectron imaging
9.2 Bootstrapping complexity:from atomicto molecular scattering
9.3 Photoelectronangularinter ferograms and determination ofthe dipollmatrix elements
9.4 Uniqueness:mapping the X2 hyperspaceandverification
9.5 Pump-probepolarizationgeo metry dependence and tomographicimaging References
10 Time-domainmeasurements within tra-pulsedynamics
10.1 Photoelectron imagingmeasurements frompotassium
10.2 Photoelectron imagesimulationan dparameter reconstruction
10.3 Photoelectron angular interferograms and determination of the dipole matrix elements
10.4 Mapping X2:fit statistics and sensitivity
10.5 Comparison with tomographic data
References
11 Time-domain measements with rotational wavepackets:bootstrapping protocol
11.1 Test case:butadiene model
11.2 Nitrogen aligned-frame photoelectron imaging
11.3 Bootstrapping protocol
11.3.1 Formalism
11.3.2 Stage 1:rotational wavepacket reconstruction
11.3.3 Stage 2:photoionization matrix element reconstruction
11.4 Photoionization matrix elements
11.5 Molecular frame reconstructions
11.6 Bootstrap protocol summary and outlook
References
Part Ⅳ Generalisations and future directions
12 Advances
12.1 Information content revisited
12.2 Multiplexing and control
12.2.1 Exploring the intra-pulse dynamics
12.2.2 Coherent control for metrology:polarization multiplexing and information content
1 2.2.3 Extensions
1 2.2.4 Maximum information measurements and multiplexing
12.3 Generalised bootstrapping
12.3.1 Theoretical limitations
12.3.2 Additional approximations
12.3.3 Experimental considerations
12.3.4 Computational methods
References
13 Future directions and outlook
13.1 Bootstrapping to quantitative quantum dynamics
13.2 Further directions for quantum metrologies based on photoelectron interferograms
13.3 Summary and outlook
References
编辑手记
