000			04597nlm1a2200565 4500
001			666311
005			20231030042033.0
035			_a(RuTPU)RU\TPU\network\37515
035			_aRU\TPU\network\30932
090			_a666311
100			_a20211216a2020 k y0engy50 ba
101	0		_aeng
135			_adrcn ---uucaa
181		0	_ai
182		0	_ab
200	1		_aInfluence of ablation on energy deposition in polymer material under irradiation of intense pulsed ion beam _fZhang Shijian, Yu Xiao, Zhong Haowen [et al.]
203			_aText _celectronic
300			_aTitle screen
320			_a[References: 20 tit.]
330			_aShort-pulse length and high-power density, intense pulsed ion beam (IPIB) has been widely studied in material processing during past decades. Ablation effect plays a great role in the interaction between IPIB and material and may affect the energy deposition of IPIB, thus further influencing the beam application and diagnostics. Therefore, the investigation of ablation effect on energy deposition of IPIB in the irradiated material is of great significance for its applications and diagnostic techniques. In this work, experiments on the IPIB irradiation are carried out on the BIPPAB-450 accelerator at Beihang University. Its maximum accelerating voltage is 450 kV, peak current density is 150 A/cm2, energy density is 1.5–1.8 J/cm2 and pulse duration (FWHM) is 80 ns. Polymer materials which have low thermal conductivity, low decomposition temperature and thus yield to ablation under low beam density, such as polycarbonate (PC), polyvinyl chloride (PVC) and polymethyl methacrylate (PMMA), are chosen in the present research. The 304 stainless steel is used for calorimetric beam diagnostics and comparative analysis. Energy deposition in polymer material and 304 stainless steel are obtained by high infrared imaging diagnostics. It is revealed that the distributions of energy deposition in these two kinds of materials differ from each other obviously.
330			_aThe highest energy density deposited in the 304 stainless steel appears in the center of the irradiated area where focused is the beam with a higher energy density. However, the central energy density in polymer material turns out to be lower than the surrounding area, indicating that a large portion of the ion beam is prevented from reaching the target. Meanwhile, the simulation based on the finite element method is carried out for the thermal filed distribution and evolution under the IPIB irradiation. The simulation result indicates that the strong ablation can be generated on the target surface since the highest temperature caused by IPIB irradiation is much higher than its decomposition temperature. According to the results of experiments and simulation, the polymer material can start to be ablated at the initial stage of IPIB irradiation which will consume partial energy and the products of ablation may act as shielding to block the energy deposition in the same pulse.
461			_tActa Physica Sinica
463			_tVol. 69, iss. 11 _v[115202, 6 p.] _d2020
610	1		_aэлектронный ресурс
610	1		_aтруды учёных ТПУ
610	1		_antense pulsed ion beam
610	1		_aablation
610	1		_aenergy deposition
610	1		_ashielding
610	1		_aионные пучки
610	1		_aабляция
610	1		_aэнерговыделение
610	1		_aэкранирование
610	1		_aполимерные материалы
610	1		_aоблучение
701		0	_aZhang Shijian
701		0	_aYu Xiao
701		0	_aZhong Haowen
701		0	_aLiang Guoying Y.
701		0	_aXu Mofei
701		0	_aZhang Nan
701		0	_aRen Jianhui
701		0	_aKuang Shicheng
701		0	_aYan Sha
701		1	_aRemnev (Remnyov) _bG. E. _cphysicist _cProfessor of Tomsk Polytechnic University, Doctor of technical sciences _f1948- _gGennady Efimovich _2stltpush _3(RuTPU)RU\TPU\pers\31500
701		0	_aLe Xiaoyun
712	0	2	_aНациональный исследовательский Томский политехнический университет _bИнженерная школа новых производственных технологий _bНаучно-производственная лаборатория "Импульсно-пучковых, электроразрядных и плазменных технологий" _h7882 _2stltpush _3(RuTPU)RU\TPU\col\23502
801		2	_aRU _b63413507 _c20211216 _gRCR
856	4		_uhttps://doi.org/10.7498/aps.69.20200212
942			_cCF